ALL

NEW ORLEANS – The immunotherapy drug blinatumomab improves survival as a first-line treatment in certain younger adult patients with B-lineage acute lymphoblastic leukemia, investigators have found. The extremely expensive drug is currently Food and Drug Administration approved for B-lineage ALL in relapsed/refractory cases.

“We feel that this represents a new standard of care for these patients and should be incorporated into their standard therapy,” said lead author and hematologist Mark R. Litzow, MD, of Mayo Clinic in Rochester, Minn., in a news briefing at the annual meeting of the American Society of Hematology.

B-lineage ALL, also known as B-cell ALL, represents 75% of cases of the blood cancer in adults according to the Leukemia & Lymphoma Society. It occurs when there’s an overgrowth of immature white blood cells known as B-cell lymphoblasts. “These are the blast cells that don’t function well and cause these patients to develop infections and bleeding,” Dr. Litzow said.

Treatments include chemotherapy and stem-cell transplants. Blinatumomab, a bispecific T-cell engager molecule, is FDA approved for patients with relapsed/refractory B-lineage ALL and those with morphologic complete remission who still have measurable residual disease (MRD).

As the new study notes, some patients who undergo chemotherapy and reach remission have poor survival outcomes even when there’s no sign of MRD. “Even though we can’t find leukemia in the patients’ bone marrow, it’s still hiding there,” Dr. Litzow said.

The new phase 3, randomized trial aims to determine if adding blinatumomab (Blincyto) to first-line chemotherapy improves outcomes. The drug “brings a normal T cell, part of the immune system, in proximity to a leukemia plasma cell and kills it.”

For the study, researchers from 2013 to 2019 recruited 488 patients aged 30-70 years with newly diagnosed BCR::ABL1 negative B-lineage ALL (median age = 51). The subjects underwent chemotherapy, and then were “randomized to receive an additional four cycles of consolidation chemo or two cycles of blin [blinatumomab] for 28 days each cycle followed by three cycles of consolidation chemo, another 4-week cycle of blinatumomab (third cycle of blinatumomab) followed by an additional cycle of chemo and then a fourth cycle of blinatumomab (step 3),” the researchers reported. “Following completion of consolidation chemo +/– blin, patients were given 2.5 years of POMP [prednisone, vincristine, 6-mercaptopurine, and methotrexate] maintenance therapy timed from the start of the intensification cycle (step 4).”

There were 112 patients in each group. Among MRD-negative patients, 56 patients died – 17 in the blinatumomab arm and 39 in the control arm at the third interim efficacy analysis. At a mean follow-up of 43 months, median overall survival for patients in the blinatumomab arm was not reached vs. 71.4 months in the control group (hazard ratio, 0.42, 95% confidence interval, 0.24-0.75; P = .003).

“The patients that got blinatumomab plus chemotherapy had an improved survival over those that got the standard chemotherapy,” Dr. Litzow said.

Dr. Litzow didn’t discuss the drug’s expense in his presentation. According to a 2019 report, when a daily vial of blinatumomab cost $3,464-$3,815, a treatment course of five month-long cycles could run to $535,000. According to drugs.com, the cost now is $4,740 per vial – more than $660,000 for five cycles.

In an interview, Cleveland Clinic hematologist/oncologist Anjali Advani, MD, said the study is “groundbreaking and one of the most exciting studies to come along in the acute lymphoblastic leukemia field.”

The trial “is one of the first studies to show improvement in outcome in a randomized manner with the addition of a novel agent,” she added. “This will change our standard of care for these patients.”

The National Cancer Institute funded the trial and drug manufacturer Amgen provided the medication and support through a cooperative research and development agreement.

Dr. Litzow discloses relationships with Actinium, Jazz, Syndax, Novartis, Astellas, Amgen, Abbvie, Pluristem and Biosight. Other authors have various disclosures with multiple drugmakers. Dr. Advani discloses relationships with Amgen, Jazz, Nkarta, Taiho, Beam, GMI, Kura, Pfizer, OBI, Incyte, Kite, ImmunoGen, GlycoMimetics, SGN, MacroGenics, and Servier.

NEW ORLEANS – The immunotherapy drug blinatumomab improves survival as a first-line treatment in certain younger adult patients with B-lineage acute lymphoblastic leukemia, investigators have found. The extremely expensive drug is currently Food and Drug Administration approved for B-lineage ALL in relapsed/refractory cases.

“We feel that this represents a new standard of care for these patients and should be incorporated into their standard therapy,” said lead author and hematologist Mark R. Litzow, MD, of Mayo Clinic in Rochester, Minn., in a news briefing at the annual meeting of the American Society of Hematology.

B-lineage ALL, also known as B-cell ALL, represents 75% of cases of the blood cancer in adults according to the Leukemia & Lymphoma Society. It occurs when there’s an overgrowth of immature white blood cells known as B-cell lymphoblasts. “These are the blast cells that don’t function well and cause these patients to develop infections and bleeding,” Dr. Litzow said.

Treatments include chemotherapy and stem-cell transplants. Blinatumomab, a bispecific T-cell engager molecule, is FDA approved for patients with relapsed/refractory B-lineage ALL and those with morphologic complete remission who still have measurable residual disease (MRD).

As the new study notes, some patients who undergo chemotherapy and reach remission have poor survival outcomes even when there’s no sign of MRD. “Even though we can’t find leukemia in the patients’ bone marrow, it’s still hiding there,” Dr. Litzow said.

The new phase 3, randomized trial aims to determine if adding blinatumomab (Blincyto) to first-line chemotherapy improves outcomes. The drug “brings a normal T cell, part of the immune system, in proximity to a leukemia plasma cell and kills it.”

For the study, researchers from 2013 to 2019 recruited 488 patients aged 30-70 years with newly diagnosed BCR::ABL1 negative B-lineage ALL (median age = 51). The subjects underwent chemotherapy, and then were “randomized to receive an additional four cycles of consolidation chemo or two cycles of blin [blinatumomab] for 28 days each cycle followed by three cycles of consolidation chemo, another 4-week cycle of blinatumomab (third cycle of blinatumomab) followed by an additional cycle of chemo and then a fourth cycle of blinatumomab (step 3),” the researchers reported. “Following completion of consolidation chemo +/– blin, patients were given 2.5 years of POMP [prednisone, vincristine, 6-mercaptopurine, and methotrexate] maintenance therapy timed from the start of the intensification cycle (step 4).”

There were 112 patients in each group. Among MRD-negative patients, 56 patients died – 17 in the blinatumomab arm and 39 in the control arm at the third interim efficacy analysis. At a mean follow-up of 43 months, median overall survival for patients in the blinatumomab arm was not reached vs. 71.4 months in the control group (hazard ratio, 0.42, 95% confidence interval, 0.24-0.75; P = .003).

“The patients that got blinatumomab plus chemotherapy had an improved survival over those that got the standard chemotherapy,” Dr. Litzow said.

Dr. Litzow didn’t discuss the drug’s expense in his presentation. According to a 2019 report, when a daily vial of blinatumomab cost $3,464-$3,815, a treatment course of five month-long cycles could run to $535,000. According to drugs.com, the cost now is $4,740 per vial – more than $660,000 for five cycles.

In an interview, Cleveland Clinic hematologist/oncologist Anjali Advani, MD, said the study is “groundbreaking and one of the most exciting studies to come along in the acute lymphoblastic leukemia field.”

The trial “is one of the first studies to show improvement in outcome in a randomized manner with the addition of a novel agent,” she added. “This will change our standard of care for these patients.”

The National Cancer Institute funded the trial and drug manufacturer Amgen provided the medication and support through a cooperative research and development agreement.

Dr. Litzow discloses relationships with Actinium, Jazz, Syndax, Novartis, Astellas, Amgen, Abbvie, Pluristem and Biosight. Other authors have various disclosures with multiple drugmakers. Dr. Advani discloses relationships with Amgen, Jazz, Nkarta, Taiho, Beam, GMI, Kura, Pfizer, OBI, Incyte, Kite, ImmunoGen, GlycoMimetics, SGN, MacroGenics, and Servier.

NEW ORLEANS – The immunotherapy drug blinatumomab improves survival as a first-line treatment in certain younger adult patients with B-lineage acute lymphoblastic leukemia, investigators have found. The extremely expensive drug is currently Food and Drug Administration approved for B-lineage ALL in relapsed/refractory cases.

“We feel that this represents a new standard of care for these patients and should be incorporated into their standard therapy,” said lead author and hematologist Mark R. Litzow, MD, of Mayo Clinic in Rochester, Minn., in a news briefing at the annual meeting of the American Society of Hematology.

B-lineage ALL, also known as B-cell ALL, represents 75% of cases of the blood cancer in adults according to the Leukemia & Lymphoma Society. It occurs when there’s an overgrowth of immature white blood cells known as B-cell lymphoblasts. “These are the blast cells that don’t function well and cause these patients to develop infections and bleeding,” Dr. Litzow said.

Treatments include chemotherapy and stem-cell transplants. Blinatumomab, a bispecific T-cell engager molecule, is FDA approved for patients with relapsed/refractory B-lineage ALL and those with morphologic complete remission who still have measurable residual disease (MRD).

As the new study notes, some patients who undergo chemotherapy and reach remission have poor survival outcomes even when there’s no sign of MRD. “Even though we can’t find leukemia in the patients’ bone marrow, it’s still hiding there,” Dr. Litzow said.

The new phase 3, randomized trial aims to determine if adding blinatumomab (Blincyto) to first-line chemotherapy improves outcomes. The drug “brings a normal T cell, part of the immune system, in proximity to a leukemia plasma cell and kills it.”

For the study, researchers from 2013 to 2019 recruited 488 patients aged 30-70 years with newly diagnosed BCR::ABL1 negative B-lineage ALL (median age = 51). The subjects underwent chemotherapy, and then were “randomized to receive an additional four cycles of consolidation chemo or two cycles of blin [blinatumomab] for 28 days each cycle followed by three cycles of consolidation chemo, another 4-week cycle of blinatumomab (third cycle of blinatumomab) followed by an additional cycle of chemo and then a fourth cycle of blinatumomab (step 3),” the researchers reported. “Following completion of consolidation chemo +/– blin, patients were given 2.5 years of POMP [prednisone, vincristine, 6-mercaptopurine, and methotrexate] maintenance therapy timed from the start of the intensification cycle (step 4).”

There were 112 patients in each group. Among MRD-negative patients, 56 patients died – 17 in the blinatumomab arm and 39 in the control arm at the third interim efficacy analysis. At a mean follow-up of 43 months, median overall survival for patients in the blinatumomab arm was not reached vs. 71.4 months in the control group (hazard ratio, 0.42, 95% confidence interval, 0.24-0.75; P = .003).

“The patients that got blinatumomab plus chemotherapy had an improved survival over those that got the standard chemotherapy,” Dr. Litzow said.

Dr. Litzow didn’t discuss the drug’s expense in his presentation. According to a 2019 report, when a daily vial of blinatumomab cost $3,464-$3,815, a treatment course of five month-long cycles could run to $535,000. According to drugs.com, the cost now is $4,740 per vial – more than $660,000 for five cycles.

In an interview, Cleveland Clinic hematologist/oncologist Anjali Advani, MD, said the study is “groundbreaking and one of the most exciting studies to come along in the acute lymphoblastic leukemia field.”

The trial “is one of the first studies to show improvement in outcome in a randomized manner with the addition of a novel agent,” she added. “This will change our standard of care for these patients.”

The National Cancer Institute funded the trial and drug manufacturer Amgen provided the medication and support through a cooperative research and development agreement.

Dr. Litzow discloses relationships with Actinium, Jazz, Syndax, Novartis, Astellas, Amgen, Abbvie, Pluristem and Biosight. Other authors have various disclosures with multiple drugmakers. Dr. Advani discloses relationships with Amgen, Jazz, Nkarta, Taiho, Beam, GMI, Kura, Pfizer, OBI, Incyte, Kite, ImmunoGen, GlycoMimetics, SGN, MacroGenics, and Servier.

NEW ORLEANS – A study aimed at improving outcomes and reducing toxicity of treatment for children and young adults with acute lymphoblastic leukemia (ALL) or lymphoblastic lymphoma found that, contrary to long-held assumptions, high-dose methotrexate does not reduce the risk for central nervous system relapse.

The same study also addressed two other issues related to standard care for these patients: 1) the dosage of dexamethasone used during the first treatment phase (results of which had already been reported some years ago) and 2) the impact of omitting monthly pulses of dexamethasone and vincristine after initial treatment.

“The trial did not give us the answers we were looking for, but that’s why we do randomized trials, and at least we have one clear answer, which is that high-dose methotrexate does not seem to have benefit in reducing the risk of CNS relapse,” reported study investigator Ajay Vora, MSc, from Great Ormond Street Hospital, London.

Among 1,570 patients randomly assigned in one group of the UKALL2011 trial, 5-year rates of CNS relapse were identical at 5.6% for patients treated with either high-dose methotrexate or standard interim maintenance with oral mercaptopurine and oral and intrathecal methotrexate.

There was a hint, however, that high-dose methotrexate could have a beneficial effect by reducing relapses in bone marrow for some subgroups of patients with B-lineage disease after dexamethasone induction, Dr. Vora commented.

He was speaking at a press briefing at the annual meeting of the American Society of Hematology, prior to the presentation of the data by Amy A. Kirkwood, MSc, from the University College London Cancer Institute.

Reacting to the results, Cynthia E. Dunbar, MD, chief of the Translational Stem Cell Biology Branch at the National Heart, Lung, and Blood Institute in Bethesda, Md., emphasized that “in patients treated with the UKALL regimen, high doses of methotrexate did not reduce the rate of CNS relapse, contrary to our long-standing beliefs.”

“Going forward, patients can be spared the risk of high-dose methotrexate without increasing their risk of recurrence in the central nervous system,” she said.

“As researchers in hematology, we look at it as our duty to question the standard approaches that we use to treat patients, even those that we thought of as tried-and-true,” said briefing moderator Mikkael Sekeres, MD, of the Sylvester Comprehensive Cancer Center at the University of Miami. This is one of the abstracts that “challenge some of those standards and in fact reveal that in many cases, giving less therapy and being less restrictive is actually better for patients or at least no worse.”
 

Complex design

The UKALL2011 trial had a byzantine design, with the overarching goal of finding out which treatment and maintenance strategy best finds the sweet spot between efficacy and toxicity in children and young adults (up to age 25) with ALL and lymphoblastic lymphoma.

One question that was already answered, as investigators reported at the 2017 ASH annual meeting, came from the first randomization in the study, designed to see whether a shorter course of dexamethasone – 14 days versus the standard 28 days – could reduce induction toxicity. It did not.

Now, at ASH 2022, the investigators reported outcomes from the second phase of the trial, which included two randomizations: one comparing high-dose methotrexate with standard interim maintenance to reduce CNS relapse risk, and one to see whether forgoing pulses of vincristine/dexamethasone could reduce maintenance morbidity.

Patients were stratified by National Cancer Institute minimal residual disease (MRD) risk categories, cytogenetics, and end-of-induction MRD to receive one of three treatment regimens. Patients with MRD high risk, defined as MRD greater than 0.5% at the end of consolidation, were not eligible for second-phase randomization and instead received off-protocol therapies.The second randomization was factorial, stratified by NCI and MRD risk groups, resulting in four arms: high-dose methotrexate with or without pulses and standard interim maintenance with our without pulses.

Standard interim maintenance in this trial was 2 months of oral mercaptopurine/methotrexate monthly pulses and single intrathecal methotrexate in two of the regimens, as well as five doses of escalating intravenous methotrexate plus vincristine and two doses of pegylated asparaginase in the third.

High-dose methotrexate was given at a dose of 5 g/m² for four doses 2 weeks apart, low dose 6-mercaptopurine, plus two doses of pegylated asparaginase in one regimen only.
 

Equivocal conclusions

As noted above, CNS relapse, the primary endpoint for the interim maintenance randomization, did not differ between the groups, with identical 5-year relapse rates. Similarly, 5-year event-free survival (EFS) rates were 90.3% in the high-dose group and 89.5% in the standard group, a difference that was not statistically significant (P = .68).

There was, however, an interaction between the first (short- vs. standard-course dexamethasone) and the interim maintenance randomizations, indicating significantly inferior EFS outcomes for patients who had received the short dose of dexamethasone followed by high-dose methotrexate, especially among patients who did not receive pulses (P = .006).

An analysis of patients treated with standard dexamethasone showed that those who received high-dose methotrexate had a lower risk for bone marrow relapse, with a hazard ratio of 0.62 (P = .029), and trends, albeit nonsignificant, toward better EFS and overall survival.

In addition, the overall results suggested that steroid pulses could be safely omitted without leading to an increase in bone marrow relapses: the 5-year rates of bone marrow relapse were 10.2% with pulses and 12.2% without, although omitting pulses was associated with a slight but significant decrease in EFS overall (P = .01). The effect was attenuated among patients who had received standard-course dexamethasone and high-dose methotrexate. Leaving out the pulses also reduced rates of grade 3 or 4 adverse events, including febrile neutropenia, Ms. Kirkwood noted in her presentation.

The investigators plan to analyze quality-of-life outcomes related to dexamethasone-vincristine pulses to see whether doing so could tip the balance in favor of leaving them out of therapy, and they will continue to follow patients to see whether their findings hold.

UKALL2011 was funded by Children with Cancer UK, Blood Cancer UK, and Cancer Research UK. Ms. Kirkwood disclosed consulting for and receiving honoraria from Kite. Dr. Vora reported no relevant financial relationships.

A version of this article first appeared on Medscape.com.

NEW ORLEANS – A study aimed at improving outcomes and reducing toxicity of treatment for children and young adults with acute lymphoblastic leukemia (ALL) or lymphoblastic lymphoma found that, contrary to long-held assumptions, high-dose methotrexate does not reduce the risk for central nervous system relapse.

The same study also addressed two other issues related to standard care for these patients: 1) the dosage of dexamethasone used during the first treatment phase (results of which had already been reported some years ago) and 2) the impact of omitting monthly pulses of dexamethasone and vincristine after initial treatment.

“The trial did not give us the answers we were looking for, but that’s why we do randomized trials, and at least we have one clear answer, which is that high-dose methotrexate does not seem to have benefit in reducing the risk of CNS relapse,” reported study investigator Ajay Vora, MSc, from Great Ormond Street Hospital, London.

Among 1,570 patients randomly assigned in one group of the UKALL2011 trial, 5-year rates of CNS relapse were identical at 5.6% for patients treated with either high-dose methotrexate or standard interim maintenance with oral mercaptopurine and oral and intrathecal methotrexate.

There was a hint, however, that high-dose methotrexate could have a beneficial effect by reducing relapses in bone marrow for some subgroups of patients with B-lineage disease after dexamethasone induction, Dr. Vora commented.

He was speaking at a press briefing at the annual meeting of the American Society of Hematology, prior to the presentation of the data by Amy A. Kirkwood, MSc, from the University College London Cancer Institute.

Reacting to the results, Cynthia E. Dunbar, MD, chief of the Translational Stem Cell Biology Branch at the National Heart, Lung, and Blood Institute in Bethesda, Md., emphasized that “in patients treated with the UKALL regimen, high doses of methotrexate did not reduce the rate of CNS relapse, contrary to our long-standing beliefs.”

“Going forward, patients can be spared the risk of high-dose methotrexate without increasing their risk of recurrence in the central nervous system,” she said.

“As researchers in hematology, we look at it as our duty to question the standard approaches that we use to treat patients, even those that we thought of as tried-and-true,” said briefing moderator Mikkael Sekeres, MD, of the Sylvester Comprehensive Cancer Center at the University of Miami. This is one of the abstracts that “challenge some of those standards and in fact reveal that in many cases, giving less therapy and being less restrictive is actually better for patients or at least no worse.”
 

Complex design

The UKALL2011 trial had a byzantine design, with the overarching goal of finding out which treatment and maintenance strategy best finds the sweet spot between efficacy and toxicity in children and young adults (up to age 25) with ALL and lymphoblastic lymphoma.

One question that was already answered, as investigators reported at the 2017 ASH annual meeting, came from the first randomization in the study, designed to see whether a shorter course of dexamethasone – 14 days versus the standard 28 days – could reduce induction toxicity. It did not.

Now, at ASH 2022, the investigators reported outcomes from the second phase of the trial, which included two randomizations: one comparing high-dose methotrexate with standard interim maintenance to reduce CNS relapse risk, and one to see whether forgoing pulses of vincristine/dexamethasone could reduce maintenance morbidity.

Patients were stratified by National Cancer Institute minimal residual disease (MRD) risk categories, cytogenetics, and end-of-induction MRD to receive one of three treatment regimens. Patients with MRD high risk, defined as MRD greater than 0.5% at the end of consolidation, were not eligible for second-phase randomization and instead received off-protocol therapies.The second randomization was factorial, stratified by NCI and MRD risk groups, resulting in four arms: high-dose methotrexate with or without pulses and standard interim maintenance with our without pulses.

Standard interim maintenance in this trial was 2 months of oral mercaptopurine/methotrexate monthly pulses and single intrathecal methotrexate in two of the regimens, as well as five doses of escalating intravenous methotrexate plus vincristine and two doses of pegylated asparaginase in the third.

High-dose methotrexate was given at a dose of 5 g/m² for four doses 2 weeks apart, low dose 6-mercaptopurine, plus two doses of pegylated asparaginase in one regimen only.
 

Equivocal conclusions

As noted above, CNS relapse, the primary endpoint for the interim maintenance randomization, did not differ between the groups, with identical 5-year relapse rates. Similarly, 5-year event-free survival (EFS) rates were 90.3% in the high-dose group and 89.5% in the standard group, a difference that was not statistically significant (P = .68).

There was, however, an interaction between the first (short- vs. standard-course dexamethasone) and the interim maintenance randomizations, indicating significantly inferior EFS outcomes for patients who had received the short dose of dexamethasone followed by high-dose methotrexate, especially among patients who did not receive pulses (P = .006).

An analysis of patients treated with standard dexamethasone showed that those who received high-dose methotrexate had a lower risk for bone marrow relapse, with a hazard ratio of 0.62 (P = .029), and trends, albeit nonsignificant, toward better EFS and overall survival.

In addition, the overall results suggested that steroid pulses could be safely omitted without leading to an increase in bone marrow relapses: the 5-year rates of bone marrow relapse were 10.2% with pulses and 12.2% without, although omitting pulses was associated with a slight but significant decrease in EFS overall (P = .01). The effect was attenuated among patients who had received standard-course dexamethasone and high-dose methotrexate. Leaving out the pulses also reduced rates of grade 3 or 4 adverse events, including febrile neutropenia, Ms. Kirkwood noted in her presentation.

The investigators plan to analyze quality-of-life outcomes related to dexamethasone-vincristine pulses to see whether doing so could tip the balance in favor of leaving them out of therapy, and they will continue to follow patients to see whether their findings hold.

UKALL2011 was funded by Children with Cancer UK, Blood Cancer UK, and Cancer Research UK. Ms. Kirkwood disclosed consulting for and receiving honoraria from Kite. Dr. Vora reported no relevant financial relationships.

A version of this article first appeared on Medscape.com.

NEW ORLEANS – A study aimed at improving outcomes and reducing toxicity of treatment for children and young adults with acute lymphoblastic leukemia (ALL) or lymphoblastic lymphoma found that, contrary to long-held assumptions, high-dose methotrexate does not reduce the risk for central nervous system relapse.

The same study also addressed two other issues related to standard care for these patients: 1) the dosage of dexamethasone used during the first treatment phase (results of which had already been reported some years ago) and 2) the impact of omitting monthly pulses of dexamethasone and vincristine after initial treatment.

“The trial did not give us the answers we were looking for, but that’s why we do randomized trials, and at least we have one clear answer, which is that high-dose methotrexate does not seem to have benefit in reducing the risk of CNS relapse,” reported study investigator Ajay Vora, MSc, from Great Ormond Street Hospital, London.

Among 1,570 patients randomly assigned in one group of the UKALL2011 trial, 5-year rates of CNS relapse were identical at 5.6% for patients treated with either high-dose methotrexate or standard interim maintenance with oral mercaptopurine and oral and intrathecal methotrexate.

There was a hint, however, that high-dose methotrexate could have a beneficial effect by reducing relapses in bone marrow for some subgroups of patients with B-lineage disease after dexamethasone induction, Dr. Vora commented.

He was speaking at a press briefing at the annual meeting of the American Society of Hematology, prior to the presentation of the data by Amy A. Kirkwood, MSc, from the University College London Cancer Institute.

Reacting to the results, Cynthia E. Dunbar, MD, chief of the Translational Stem Cell Biology Branch at the National Heart, Lung, and Blood Institute in Bethesda, Md., emphasized that “in patients treated with the UKALL regimen, high doses of methotrexate did not reduce the rate of CNS relapse, contrary to our long-standing beliefs.”

“Going forward, patients can be spared the risk of high-dose methotrexate without increasing their risk of recurrence in the central nervous system,” she said.

“As researchers in hematology, we look at it as our duty to question the standard approaches that we use to treat patients, even those that we thought of as tried-and-true,” said briefing moderator Mikkael Sekeres, MD, of the Sylvester Comprehensive Cancer Center at the University of Miami. This is one of the abstracts that “challenge some of those standards and in fact reveal that in many cases, giving less therapy and being less restrictive is actually better for patients or at least no worse.”
 

Complex design

The UKALL2011 trial had a byzantine design, with the overarching goal of finding out which treatment and maintenance strategy best finds the sweet spot between efficacy and toxicity in children and young adults (up to age 25) with ALL and lymphoblastic lymphoma.

One question that was already answered, as investigators reported at the 2017 ASH annual meeting, came from the first randomization in the study, designed to see whether a shorter course of dexamethasone – 14 days versus the standard 28 days – could reduce induction toxicity. It did not.

Now, at ASH 2022, the investigators reported outcomes from the second phase of the trial, which included two randomizations: one comparing high-dose methotrexate with standard interim maintenance to reduce CNS relapse risk, and one to see whether forgoing pulses of vincristine/dexamethasone could reduce maintenance morbidity.

Patients were stratified by National Cancer Institute minimal residual disease (MRD) risk categories, cytogenetics, and end-of-induction MRD to receive one of three treatment regimens. Patients with MRD high risk, defined as MRD greater than 0.5% at the end of consolidation, were not eligible for second-phase randomization and instead received off-protocol therapies.The second randomization was factorial, stratified by NCI and MRD risk groups, resulting in four arms: high-dose methotrexate with or without pulses and standard interim maintenance with our without pulses.

Standard interim maintenance in this trial was 2 months of oral mercaptopurine/methotrexate monthly pulses and single intrathecal methotrexate in two of the regimens, as well as five doses of escalating intravenous methotrexate plus vincristine and two doses of pegylated asparaginase in the third.

High-dose methotrexate was given at a dose of 5 g/m² for four doses 2 weeks apart, low dose 6-mercaptopurine, plus two doses of pegylated asparaginase in one regimen only.
 

Equivocal conclusions

As noted above, CNS relapse, the primary endpoint for the interim maintenance randomization, did not differ between the groups, with identical 5-year relapse rates. Similarly, 5-year event-free survival (EFS) rates were 90.3% in the high-dose group and 89.5% in the standard group, a difference that was not statistically significant (P = .68).

There was, however, an interaction between the first (short- vs. standard-course dexamethasone) and the interim maintenance randomizations, indicating significantly inferior EFS outcomes for patients who had received the short dose of dexamethasone followed by high-dose methotrexate, especially among patients who did not receive pulses (P = .006).

An analysis of patients treated with standard dexamethasone showed that those who received high-dose methotrexate had a lower risk for bone marrow relapse, with a hazard ratio of 0.62 (P = .029), and trends, albeit nonsignificant, toward better EFS and overall survival.

In addition, the overall results suggested that steroid pulses could be safely omitted without leading to an increase in bone marrow relapses: the 5-year rates of bone marrow relapse were 10.2% with pulses and 12.2% without, although omitting pulses was associated with a slight but significant decrease in EFS overall (P = .01). The effect was attenuated among patients who had received standard-course dexamethasone and high-dose methotrexate. Leaving out the pulses also reduced rates of grade 3 or 4 adverse events, including febrile neutropenia, Ms. Kirkwood noted in her presentation.

The investigators plan to analyze quality-of-life outcomes related to dexamethasone-vincristine pulses to see whether doing so could tip the balance in favor of leaving them out of therapy, and they will continue to follow patients to see whether their findings hold.

UKALL2011 was funded by Children with Cancer UK, Blood Cancer UK, and Cancer Research UK. Ms. Kirkwood disclosed consulting for and receiving honoraria from Kite. Dr. Vora reported no relevant financial relationships.

A version of this article first appeared on Medscape.com.

In addition to the latest news in clinical care and drug development, some eyebrow-raising findings that challenge long-held, untested assumptions are promised from the annual meeting of the American Society of Hematology.

The conference starts in New Orleans on Saturday, Dec. 10, , but a sample of what is to come was given last week in a preview media briefing, moderated by Mikkael A. Sekeres, MD, from the University of Miami. Dr. Sekeres, who recently authored a book on the FDA and how it regulates drug approvals, also serves as chair of the ASH Committee on Communications.
 

“Feeding Our Patients Gruel”

Dr. Sekeres expressed particular excitement about a multicenter randomized trial done in Italy. It showed that patients who have neutropenia after a stem cell transplant need not be required to eat a bland diet (Abstract 169).

“We for years have been essentially feeding our patients gruel in the hospital, and these are folks who have to be hospitalized for a stem cell transplant or in my case – I’m a leukemia specialist – for acute leukemia, for 4-6 weeks. The neutropenic diet consists of the blandest food you can imagine, with nothing to really spice it up.”

He noted that a neutropenic diet is so unpalatable that family members often sneak food into patient rooms, and “for years we’ve never seen adverse outcomes in any of those folks who instead of having mashed potatoes and oatmeal ate a corned beef sandwich for dinner.”

Now, the results from this trial “actually give us license to finally allow patients to eat whatever they want,” Dr. Sekeres said.
 

Practice-changing data

ASH experts pointed to two more presentations that are expected to change clinical practice. These include the finding that high-dose methotrexate does not reduce the risk for central nervous system relapse in children with acute lymphoblastic leukemia and lymphoblastic lymphoma (Abstract 214).

Another new study that seems to defy conventional wisdom showed that in adults with relapsed or refractory acute myeloid leukemia, intensive chemotherapy in an effort to achieve remission before a stem cell transplant did not result in better outcomes, compared with sequential conditioning and immediate transplant (Abstract 4).
 

Premature aging in HL survivors

ASH President Jane N. Winter, MD, from Northwestern University, Chicago, who also spoke at the briefing, highlighted a study that followed adult survivors of pediatric Hodgkin lymphoma. This study, from St. Jude Children’s Research Hospital in Memphis and the Wilmot Cancer Institute at the University of Rochester (N.Y), found that these adult survivors are at significantly elevated risk for epigenetic age acceleration accompanied by neurocognitive deficits when compared with controls (Abstract 902).

“This is an area that is very near and dear to my heart,” she said. “Much of my career has focused on reducing the therapy to reduce the long-term consequences of treatments. Pediatricians have been very much wedded to very intensive therapies and tend to incorporate radiation more commonly in their treatment strategies for children than we do in adults.”

Dr. Winter noted that, although clinicians focus primarily on the link between mediastinal radiation and long-term adverse events such as breast cancer, “now we’re shedding a light on the neurocognitive deficits, which I think are underappreciated. Being able to screen for this impact of our treatment, and perhaps then develop strategies to deal with it or prevent it, will have very wide-ranging impact.”
 

Inherited thrombophilia and miscarriage

Cynthia E. Dunbar, MD, chief of the translational stem cell biology branch at the National Heart, Lung, and Blood Institute in Bethesda, Md., who also spoke at the briefing, said that one of the abstracts most important to her practice is a study concerning pregnancy. It showed that low-molecular-weight heparin did not prevent miscarriage in pregnant women with confirmed inherited thrombophilia who had two or more prior pregnancy losses, compared with standard surveillance (Abstract LBA-5).

“This is not my field at all; on the other hand, as a hematologist and a woman, that’s what my emails in the middle of the night and my panicked phone calls are often about. Once somebody has one miscarriage, especially if they feel like they’re already over 30 and the clock is ticking, there’s a huge emphasis and a huge amount of pressure on obstetricians to basically work up for everything, kind of a shotgun [approach],” she said.

Those workups may reveal genetic mutations that are associated with mild elevations in risk for clotting. As a result, some pregnant women are put on anticoagulation therapy, which can cause complications for both pregnancy and delivery. These study findings don’t solve the problem of spontaneous pregnancy loss, but they at least rule out inherited thrombophilia as a preventable cause of miscarriages, Dr. Dunbar said.

Another potentially practice-changing abstract is a study showing that, in younger adults with mantle cell lymphoma, the addition of the Bruton’s tyrosine kinase inhibitor ibrutinib (Imbruvica) to induction therapy and as maintenance with or without autologous stem cell transplant had strong efficacy and acceptable toxicity (Abstract 1).

“The results show that the ibrutinib-containing regimen without transplant is at least as good as the current standard of care with transplant.” Dr. Winter said. “Additional follow-up will be required to show definitively that an autotransplant is unnecessary if ibrutinib is included in this treatment regimen.”

A version of this article first appeared on Medscape.com.

In addition to the latest news in clinical care and drug development, some eyebrow-raising findings that challenge long-held, untested assumptions are promised from the annual meeting of the American Society of Hematology.

The conference starts in New Orleans on Saturday, Dec. 10, , but a sample of what is to come was given last week in a preview media briefing, moderated by Mikkael A. Sekeres, MD, from the University of Miami. Dr. Sekeres, who recently authored a book on the FDA and how it regulates drug approvals, also serves as chair of the ASH Committee on Communications.
 

“Feeding Our Patients Gruel”

Dr. Sekeres expressed particular excitement about a multicenter randomized trial done in Italy. It showed that patients who have neutropenia after a stem cell transplant need not be required to eat a bland diet (Abstract 169).

“We for years have been essentially feeding our patients gruel in the hospital, and these are folks who have to be hospitalized for a stem cell transplant or in my case – I’m a leukemia specialist – for acute leukemia, for 4-6 weeks. The neutropenic diet consists of the blandest food you can imagine, with nothing to really spice it up.”

He noted that a neutropenic diet is so unpalatable that family members often sneak food into patient rooms, and “for years we’ve never seen adverse outcomes in any of those folks who instead of having mashed potatoes and oatmeal ate a corned beef sandwich for dinner.”

Now, the results from this trial “actually give us license to finally allow patients to eat whatever they want,” Dr. Sekeres said.
 

Practice-changing data

ASH experts pointed to two more presentations that are expected to change clinical practice. These include the finding that high-dose methotrexate does not reduce the risk for central nervous system relapse in children with acute lymphoblastic leukemia and lymphoblastic lymphoma (Abstract 214).

Another new study that seems to defy conventional wisdom showed that in adults with relapsed or refractory acute myeloid leukemia, intensive chemotherapy in an effort to achieve remission before a stem cell transplant did not result in better outcomes, compared with sequential conditioning and immediate transplant (Abstract 4).
 

Premature aging in HL survivors

ASH President Jane N. Winter, MD, from Northwestern University, Chicago, who also spoke at the briefing, highlighted a study that followed adult survivors of pediatric Hodgkin lymphoma. This study, from St. Jude Children’s Research Hospital in Memphis and the Wilmot Cancer Institute at the University of Rochester (N.Y), found that these adult survivors are at significantly elevated risk for epigenetic age acceleration accompanied by neurocognitive deficits when compared with controls (Abstract 902).

“This is an area that is very near and dear to my heart,” she said. “Much of my career has focused on reducing the therapy to reduce the long-term consequences of treatments. Pediatricians have been very much wedded to very intensive therapies and tend to incorporate radiation more commonly in their treatment strategies for children than we do in adults.”

Dr. Winter noted that, although clinicians focus primarily on the link between mediastinal radiation and long-term adverse events such as breast cancer, “now we’re shedding a light on the neurocognitive deficits, which I think are underappreciated. Being able to screen for this impact of our treatment, and perhaps then develop strategies to deal with it or prevent it, will have very wide-ranging impact.”
 

Inherited thrombophilia and miscarriage

Cynthia E. Dunbar, MD, chief of the translational stem cell biology branch at the National Heart, Lung, and Blood Institute in Bethesda, Md., who also spoke at the briefing, said that one of the abstracts most important to her practice is a study concerning pregnancy. It showed that low-molecular-weight heparin did not prevent miscarriage in pregnant women with confirmed inherited thrombophilia who had two or more prior pregnancy losses, compared with standard surveillance (Abstract LBA-5).

“This is not my field at all; on the other hand, as a hematologist and a woman, that’s what my emails in the middle of the night and my panicked phone calls are often about. Once somebody has one miscarriage, especially if they feel like they’re already over 30 and the clock is ticking, there’s a huge emphasis and a huge amount of pressure on obstetricians to basically work up for everything, kind of a shotgun [approach],” she said.

Those workups may reveal genetic mutations that are associated with mild elevations in risk for clotting. As a result, some pregnant women are put on anticoagulation therapy, which can cause complications for both pregnancy and delivery. These study findings don’t solve the problem of spontaneous pregnancy loss, but they at least rule out inherited thrombophilia as a preventable cause of miscarriages, Dr. Dunbar said.

Another potentially practice-changing abstract is a study showing that, in younger adults with mantle cell lymphoma, the addition of the Bruton’s tyrosine kinase inhibitor ibrutinib (Imbruvica) to induction therapy and as maintenance with or without autologous stem cell transplant had strong efficacy and acceptable toxicity (Abstract 1).

“The results show that the ibrutinib-containing regimen without transplant is at least as good as the current standard of care with transplant.” Dr. Winter said. “Additional follow-up will be required to show definitively that an autotransplant is unnecessary if ibrutinib is included in this treatment regimen.”

A version of this article first appeared on Medscape.com.

In addition to the latest news in clinical care and drug development, some eyebrow-raising findings that challenge long-held, untested assumptions are promised from the annual meeting of the American Society of Hematology.

The conference starts in New Orleans on Saturday, Dec. 10, , but a sample of what is to come was given last week in a preview media briefing, moderated by Mikkael A. Sekeres, MD, from the University of Miami. Dr. Sekeres, who recently authored a book on the FDA and how it regulates drug approvals, also serves as chair of the ASH Committee on Communications.
 

“Feeding Our Patients Gruel”

Dr. Sekeres expressed particular excitement about a multicenter randomized trial done in Italy. It showed that patients who have neutropenia after a stem cell transplant need not be required to eat a bland diet (Abstract 169).

“We for years have been essentially feeding our patients gruel in the hospital, and these are folks who have to be hospitalized for a stem cell transplant or in my case – I’m a leukemia specialist – for acute leukemia, for 4-6 weeks. The neutropenic diet consists of the blandest food you can imagine, with nothing to really spice it up.”

He noted that a neutropenic diet is so unpalatable that family members often sneak food into patient rooms, and “for years we’ve never seen adverse outcomes in any of those folks who instead of having mashed potatoes and oatmeal ate a corned beef sandwich for dinner.”

Now, the results from this trial “actually give us license to finally allow patients to eat whatever they want,” Dr. Sekeres said.
 

Practice-changing data

ASH experts pointed to two more presentations that are expected to change clinical practice. These include the finding that high-dose methotrexate does not reduce the risk for central nervous system relapse in children with acute lymphoblastic leukemia and lymphoblastic lymphoma (Abstract 214).

Another new study that seems to defy conventional wisdom showed that in adults with relapsed or refractory acute myeloid leukemia, intensive chemotherapy in an effort to achieve remission before a stem cell transplant did not result in better outcomes, compared with sequential conditioning and immediate transplant (Abstract 4).
 

Premature aging in HL survivors

ASH President Jane N. Winter, MD, from Northwestern University, Chicago, who also spoke at the briefing, highlighted a study that followed adult survivors of pediatric Hodgkin lymphoma. This study, from St. Jude Children’s Research Hospital in Memphis and the Wilmot Cancer Institute at the University of Rochester (N.Y), found that these adult survivors are at significantly elevated risk for epigenetic age acceleration accompanied by neurocognitive deficits when compared with controls (Abstract 902).

“This is an area that is very near and dear to my heart,” she said. “Much of my career has focused on reducing the therapy to reduce the long-term consequences of treatments. Pediatricians have been very much wedded to very intensive therapies and tend to incorporate radiation more commonly in their treatment strategies for children than we do in adults.”

Dr. Winter noted that, although clinicians focus primarily on the link between mediastinal radiation and long-term adverse events such as breast cancer, “now we’re shedding a light on the neurocognitive deficits, which I think are underappreciated. Being able to screen for this impact of our treatment, and perhaps then develop strategies to deal with it or prevent it, will have very wide-ranging impact.”
 

Inherited thrombophilia and miscarriage

Cynthia E. Dunbar, MD, chief of the translational stem cell biology branch at the National Heart, Lung, and Blood Institute in Bethesda, Md., who also spoke at the briefing, said that one of the abstracts most important to her practice is a study concerning pregnancy. It showed that low-molecular-weight heparin did not prevent miscarriage in pregnant women with confirmed inherited thrombophilia who had two or more prior pregnancy losses, compared with standard surveillance (Abstract LBA-5).

“This is not my field at all; on the other hand, as a hematologist and a woman, that’s what my emails in the middle of the night and my panicked phone calls are often about. Once somebody has one miscarriage, especially if they feel like they’re already over 30 and the clock is ticking, there’s a huge emphasis and a huge amount of pressure on obstetricians to basically work up for everything, kind of a shotgun [approach],” she said.

Those workups may reveal genetic mutations that are associated with mild elevations in risk for clotting. As a result, some pregnant women are put on anticoagulation therapy, which can cause complications for both pregnancy and delivery. These study findings don’t solve the problem of spontaneous pregnancy loss, but they at least rule out inherited thrombophilia as a preventable cause of miscarriages, Dr. Dunbar said.

Another potentially practice-changing abstract is a study showing that, in younger adults with mantle cell lymphoma, the addition of the Bruton’s tyrosine kinase inhibitor ibrutinib (Imbruvica) to induction therapy and as maintenance with or without autologous stem cell transplant had strong efficacy and acceptable toxicity (Abstract 1).

“The results show that the ibrutinib-containing regimen without transplant is at least as good as the current standard of care with transplant.” Dr. Winter said. “Additional follow-up will be required to show definitively that an autotransplant is unnecessary if ibrutinib is included in this treatment regimen.”

A version of this article first appeared on Medscape.com.

A novel approach in which two products were co-administered achieved a 99% complete response rate in children with relapsed or treatment-resistant B-cell acute lymphoblastic leukemia (B-ALL).

In this trial, the largest study to date of a CAR T-cell therapy for such patients, the researchers co-administered two CAR T-cell therapies, one targeting CD19 and the other targeting CD22.

The results showed that 192 of 194 patients (99%) achieved a complete remission.

The combined overall 12-month event-free survival was 73.5%.

The study was published online in the Journal of Clinical Oncology.

These results are better than what has been reported for CAR T cells that are already on the market. These products, which target CD19, have achieved complete remission in 85.5% of cases and a 12-month event-free survival of 52.4% in children with B-ALL.

“We do believe [this approach] will become standard of care,” said study author Ching-Hon Pui, MD, of the departments of oncology, pathology, and global pediatric medicine, St. Jude Children’s Research Hospital, Memphis.

He noted that this work builds on the huge success that has already been achieved in this field with CAR T-cell products directed at CD19. The first of these products to reach the market was tisagenlecleucel-T (Novartis).

“To put this study in context, the first child who received CAR T-cell therapy for B-ALL after multiple relapses has recently celebrated her 10-year cancer-free survival milestone, and we hope that our finding will result in many more such milestones,” he said.

These new results are very impressive, said Stephen P. Hunger, MD, an expert commenting for the American Society of Clinical Oncology, which highlighted the research in a press release. “They were also able to treat almost 200 patients in a relatively short time.”

Hunger pointed out that dual administration and targeting is not a new idea and is one of the strategies that is currently under investigation. But it is too early to consider this to be the standard of care, he said. “We want to see it replicated in other centers and to see longer follow-up,” said Dr. Hunger, who is Distinguished Chair in Pediatrics and director of the center for childhood cancer research at Children’s Hospital of Philadelphia. “We can establish this as a first step down the road, and we will see if others will achieve similar results.”
 

Strategy of dual targeting

Despite the success CAR T-cell therapy in childhood leukemia, the currently available products have limitations, Dr. Pui and colleagues note.

About half of patients treated with CD19 CAR T cells experience relapse within 1 year, owing either to loss of CAR T-cell persistence or to loss of CD19 antigen because of splice variants, acquired genetic mutations, or lineage switch.

With further treatment with CAR T cells directed against CD22, 70%-80% of patients who failed CD19 CAR T will achieve into complete remission. However, most will experience relapse.

Recent efforts in the field have turned to exploring the safety and feasibility of CAR T cells that target both CD19 and CD22. The results were not superior to those of the CD19 CAR T-cell therapy given alone, although sequential treatment has yielded promising response rates, the authors note.

They hypothesized that co-administration of CD19- and CD22-targeted CAR T cells would improve efficacy, as it could forestall the development of drug resistance.
 

Achieved 99% remission

Dr. Pui and colleagues conducted a phase 2 trial that included 225 evaluable patients aged 20 years or younger who were being treated at five urban hospitals in and near Shanghai, China. Of this group, 194 had refractory disease or hematologic relapse, and 31 patients had isolated extramedullary relapse.

A safety run-in stage to determine the recommended dose was initially conducted. An interim analysis of the first 30 patients who were treated (27 at the recommended dose) showed that the approach was safe and effective. Additional patients were then enrolled.

The 192 patients (of 194) who achieved complete remission attained negative minimal residual disease status.

At a median follow-up of 11 months, 43 patients experienced relapse (24 with CD191/CD221 relapse, 16 with CD19– /CD221, one with CD19– /CD22– , and two unknown), for a cumulative risk of 22.2%.
 

Transplant and relapse options

In an interview, Dr. Pui noted that various treatment options were available for the children who experienced relapse. “For patients who were in good clinical condition, we will treat them with molecular therapeutics, allogeneic CAR T cells from donor, or even repeated humanized CD19 and/or CD22 CAR T cells with or without CD20 CAR T cells in an attempt to induce a remission for allogeneic transplantation,” he said.

The site-specific 12-month event-free survival rate in the trial was 69.2% for patients who did not receive a transplant, 95% for those children who had an isolated relapse to the testicles, and 68.6% for those who had an isolated central nervous system relapse.

After censoring 78 patients for consolidative transplantation, the 12-month overall survival was 87.7%.

Consolidative transplantation was performed in 24 of the 37 patients with KMT2A-rearranged or ZNF384-rearranged ALL and in 54 patients because of parental request. The reason for this was that patients with these two genetic subtypes of leukemia (KMT2A-rearranged and ZNF384-rearranged), under the pressure of phenotype-specific treatment (such as CAR T cells or blinatumomab) are at risk of lineage switch and development of secondary acute myeloid leukemia, explained Dr. Pui. “That is an even more resistant form of leukemia, and up to 5%-10% of the patients have been reported to develop this complication.

“We performed consolidation transplantation in these patients to avoid the risk of lineage switch but would accept the parental request not to perform allogeneic transplant after they were clearly informed of the risk,” he told this news organization.

He also suggested that this approach of co-administration of two types of CAR T cells would be especially suitable for “patients with extramedullary involvement, because most of them will be spared of local irradiation so that they can preserve their neurocognitive function and fertility and avoid radiation-induced second cancer, such as brain tumor,” he said.
 

Lower toxicity

With regard to toxicity, the majority of patients (n = 98, 88%) developed cytokine release syndrome, which was grade ≥3 in 64 (28.4%) patients and fatal in one. Neurotoxicity occurred in 47 (20.9%) patients, was of grade ≥3 in 9 (4.0%) patients, and was fatal in 2 patients who received 12 x 106 and 5.6 x 106 CAR T cells/kg.

In addition, grade 3 or 4 seizure developed in 14.2% of the patients; it was more common in those who had presented with isolated or combined CNS leukemia. Grade 3 or 4 hypotension occurred in 40.9% of the patients. About three-quarters of the patients were treated with tocilizumab (n = 67, 74.2%), and 79 (35.1%) were treated with corticosteroids.

“In general, CD19 and CD22 CAR T cells were less toxic than CD19 CAR T cells, the historical controls, in our experience,” said Dr. Pui. “There were three fatal complications, a rate not excessive considering a large number of patients were treated.”
 

Future studies needed

The researchers note that in this trial, the CD22 CAR T cells did not expand as robustly or persist as long as did the CD19 CAR T cells, and they hope that future studies will elucidate whether enhancing CD22 CAR T-cell persistence and activity would further improve outcomes.

The study was supported in part by the National Natural Science Foundation of China, the Shanghai Collaborative Innovation Center for Translational Medicine, the Research Programs of Shanghai Science, the Technology Commission Foundation, the U.S. National Cancer Institute, the VIVA China Children’s Cancer Foundation, and the American Lebanese Syrian Associated Charities.

A version of this article first appeared on Medscape.com.

A novel approach in which two products were co-administered achieved a 99% complete response rate in children with relapsed or treatment-resistant B-cell acute lymphoblastic leukemia (B-ALL).

In this trial, the largest study to date of a CAR T-cell therapy for such patients, the researchers co-administered two CAR T-cell therapies, one targeting CD19 and the other targeting CD22.

The results showed that 192 of 194 patients (99%) achieved a complete remission.

The combined overall 12-month event-free survival was 73.5%.

The study was published online in the Journal of Clinical Oncology.

These results are better than what has been reported for CAR T cells that are already on the market. These products, which target CD19, have achieved complete remission in 85.5% of cases and a 12-month event-free survival of 52.4% in children with B-ALL.

“We do believe [this approach] will become standard of care,” said study author Ching-Hon Pui, MD, of the departments of oncology, pathology, and global pediatric medicine, St. Jude Children’s Research Hospital, Memphis.

He noted that this work builds on the huge success that has already been achieved in this field with CAR T-cell products directed at CD19. The first of these products to reach the market was tisagenlecleucel-T (Novartis).

“To put this study in context, the first child who received CAR T-cell therapy for B-ALL after multiple relapses has recently celebrated her 10-year cancer-free survival milestone, and we hope that our finding will result in many more such milestones,” he said.

These new results are very impressive, said Stephen P. Hunger, MD, an expert commenting for the American Society of Clinical Oncology, which highlighted the research in a press release. “They were also able to treat almost 200 patients in a relatively short time.”

Hunger pointed out that dual administration and targeting is not a new idea and is one of the strategies that is currently under investigation. But it is too early to consider this to be the standard of care, he said. “We want to see it replicated in other centers and to see longer follow-up,” said Dr. Hunger, who is Distinguished Chair in Pediatrics and director of the center for childhood cancer research at Children’s Hospital of Philadelphia. “We can establish this as a first step down the road, and we will see if others will achieve similar results.”
 

Strategy of dual targeting

Despite the success CAR T-cell therapy in childhood leukemia, the currently available products have limitations, Dr. Pui and colleagues note.

About half of patients treated with CD19 CAR T cells experience relapse within 1 year, owing either to loss of CAR T-cell persistence or to loss of CD19 antigen because of splice variants, acquired genetic mutations, or lineage switch.

With further treatment with CAR T cells directed against CD22, 70%-80% of patients who failed CD19 CAR T will achieve into complete remission. However, most will experience relapse.

Recent efforts in the field have turned to exploring the safety and feasibility of CAR T cells that target both CD19 and CD22. The results were not superior to those of the CD19 CAR T-cell therapy given alone, although sequential treatment has yielded promising response rates, the authors note.

They hypothesized that co-administration of CD19- and CD22-targeted CAR T cells would improve efficacy, as it could forestall the development of drug resistance.
 

Achieved 99% remission

Dr. Pui and colleagues conducted a phase 2 trial that included 225 evaluable patients aged 20 years or younger who were being treated at five urban hospitals in and near Shanghai, China. Of this group, 194 had refractory disease or hematologic relapse, and 31 patients had isolated extramedullary relapse.

A safety run-in stage to determine the recommended dose was initially conducted. An interim analysis of the first 30 patients who were treated (27 at the recommended dose) showed that the approach was safe and effective. Additional patients were then enrolled.

The 192 patients (of 194) who achieved complete remission attained negative minimal residual disease status.

At a median follow-up of 11 months, 43 patients experienced relapse (24 with CD191/CD221 relapse, 16 with CD19– /CD221, one with CD19– /CD22– , and two unknown), for a cumulative risk of 22.2%.
 

Transplant and relapse options

In an interview, Dr. Pui noted that various treatment options were available for the children who experienced relapse. “For patients who were in good clinical condition, we will treat them with molecular therapeutics, allogeneic CAR T cells from donor, or even repeated humanized CD19 and/or CD22 CAR T cells with or without CD20 CAR T cells in an attempt to induce a remission for allogeneic transplantation,” he said.

The site-specific 12-month event-free survival rate in the trial was 69.2% for patients who did not receive a transplant, 95% for those children who had an isolated relapse to the testicles, and 68.6% for those who had an isolated central nervous system relapse.

After censoring 78 patients for consolidative transplantation, the 12-month overall survival was 87.7%.

Consolidative transplantation was performed in 24 of the 37 patients with KMT2A-rearranged or ZNF384-rearranged ALL and in 54 patients because of parental request. The reason for this was that patients with these two genetic subtypes of leukemia (KMT2A-rearranged and ZNF384-rearranged), under the pressure of phenotype-specific treatment (such as CAR T cells or blinatumomab) are at risk of lineage switch and development of secondary acute myeloid leukemia, explained Dr. Pui. “That is an even more resistant form of leukemia, and up to 5%-10% of the patients have been reported to develop this complication.

“We performed consolidation transplantation in these patients to avoid the risk of lineage switch but would accept the parental request not to perform allogeneic transplant after they were clearly informed of the risk,” he told this news organization.

He also suggested that this approach of co-administration of two types of CAR T cells would be especially suitable for “patients with extramedullary involvement, because most of them will be spared of local irradiation so that they can preserve their neurocognitive function and fertility and avoid radiation-induced second cancer, such as brain tumor,” he said.
 

Lower toxicity

With regard to toxicity, the majority of patients (n = 98, 88%) developed cytokine release syndrome, which was grade ≥3 in 64 (28.4%) patients and fatal in one. Neurotoxicity occurred in 47 (20.9%) patients, was of grade ≥3 in 9 (4.0%) patients, and was fatal in 2 patients who received 12 x 106 and 5.6 x 106 CAR T cells/kg.

In addition, grade 3 or 4 seizure developed in 14.2% of the patients; it was more common in those who had presented with isolated or combined CNS leukemia. Grade 3 or 4 hypotension occurred in 40.9% of the patients. About three-quarters of the patients were treated with tocilizumab (n = 67, 74.2%), and 79 (35.1%) were treated with corticosteroids.

“In general, CD19 and CD22 CAR T cells were less toxic than CD19 CAR T cells, the historical controls, in our experience,” said Dr. Pui. “There were three fatal complications, a rate not excessive considering a large number of patients were treated.”
 

Future studies needed

The researchers note that in this trial, the CD22 CAR T cells did not expand as robustly or persist as long as did the CD19 CAR T cells, and they hope that future studies will elucidate whether enhancing CD22 CAR T-cell persistence and activity would further improve outcomes.

The study was supported in part by the National Natural Science Foundation of China, the Shanghai Collaborative Innovation Center for Translational Medicine, the Research Programs of Shanghai Science, the Technology Commission Foundation, the U.S. National Cancer Institute, the VIVA China Children’s Cancer Foundation, and the American Lebanese Syrian Associated Charities.

A version of this article first appeared on Medscape.com.

A novel approach in which two products were co-administered achieved a 99% complete response rate in children with relapsed or treatment-resistant B-cell acute lymphoblastic leukemia (B-ALL).

In this trial, the largest study to date of a CAR T-cell therapy for such patients, the researchers co-administered two CAR T-cell therapies, one targeting CD19 and the other targeting CD22.

The results showed that 192 of 194 patients (99%) achieved a complete remission.

The combined overall 12-month event-free survival was 73.5%.

The study was published online in the Journal of Clinical Oncology.

These results are better than what has been reported for CAR T cells that are already on the market. These products, which target CD19, have achieved complete remission in 85.5% of cases and a 12-month event-free survival of 52.4% in children with B-ALL.

“We do believe [this approach] will become standard of care,” said study author Ching-Hon Pui, MD, of the departments of oncology, pathology, and global pediatric medicine, St. Jude Children’s Research Hospital, Memphis.

He noted that this work builds on the huge success that has already been achieved in this field with CAR T-cell products directed at CD19. The first of these products to reach the market was tisagenlecleucel-T (Novartis).

“To put this study in context, the first child who received CAR T-cell therapy for B-ALL after multiple relapses has recently celebrated her 10-year cancer-free survival milestone, and we hope that our finding will result in many more such milestones,” he said.

These new results are very impressive, said Stephen P. Hunger, MD, an expert commenting for the American Society of Clinical Oncology, which highlighted the research in a press release. “They were also able to treat almost 200 patients in a relatively short time.”

Hunger pointed out that dual administration and targeting is not a new idea and is one of the strategies that is currently under investigation. But it is too early to consider this to be the standard of care, he said. “We want to see it replicated in other centers and to see longer follow-up,” said Dr. Hunger, who is Distinguished Chair in Pediatrics and director of the center for childhood cancer research at Children’s Hospital of Philadelphia. “We can establish this as a first step down the road, and we will see if others will achieve similar results.”
 

Strategy of dual targeting

Despite the success CAR T-cell therapy in childhood leukemia, the currently available products have limitations, Dr. Pui and colleagues note.

About half of patients treated with CD19 CAR T cells experience relapse within 1 year, owing either to loss of CAR T-cell persistence or to loss of CD19 antigen because of splice variants, acquired genetic mutations, or lineage switch.

With further treatment with CAR T cells directed against CD22, 70%-80% of patients who failed CD19 CAR T will achieve into complete remission. However, most will experience relapse.

Recent efforts in the field have turned to exploring the safety and feasibility of CAR T cells that target both CD19 and CD22. The results were not superior to those of the CD19 CAR T-cell therapy given alone, although sequential treatment has yielded promising response rates, the authors note.

They hypothesized that co-administration of CD19- and CD22-targeted CAR T cells would improve efficacy, as it could forestall the development of drug resistance.
 

Achieved 99% remission

Dr. Pui and colleagues conducted a phase 2 trial that included 225 evaluable patients aged 20 years or younger who were being treated at five urban hospitals in and near Shanghai, China. Of this group, 194 had refractory disease or hematologic relapse, and 31 patients had isolated extramedullary relapse.

A safety run-in stage to determine the recommended dose was initially conducted. An interim analysis of the first 30 patients who were treated (27 at the recommended dose) showed that the approach was safe and effective. Additional patients were then enrolled.

The 192 patients (of 194) who achieved complete remission attained negative minimal residual disease status.

At a median follow-up of 11 months, 43 patients experienced relapse (24 with CD191/CD221 relapse, 16 with CD19– /CD221, one with CD19– /CD22– , and two unknown), for a cumulative risk of 22.2%.
 

Transplant and relapse options

In an interview, Dr. Pui noted that various treatment options were available for the children who experienced relapse. “For patients who were in good clinical condition, we will treat them with molecular therapeutics, allogeneic CAR T cells from donor, or even repeated humanized CD19 and/or CD22 CAR T cells with or without CD20 CAR T cells in an attempt to induce a remission for allogeneic transplantation,” he said.

The site-specific 12-month event-free survival rate in the trial was 69.2% for patients who did not receive a transplant, 95% for those children who had an isolated relapse to the testicles, and 68.6% for those who had an isolated central nervous system relapse.

After censoring 78 patients for consolidative transplantation, the 12-month overall survival was 87.7%.

Consolidative transplantation was performed in 24 of the 37 patients with KMT2A-rearranged or ZNF384-rearranged ALL and in 54 patients because of parental request. The reason for this was that patients with these two genetic subtypes of leukemia (KMT2A-rearranged and ZNF384-rearranged), under the pressure of phenotype-specific treatment (such as CAR T cells or blinatumomab) are at risk of lineage switch and development of secondary acute myeloid leukemia, explained Dr. Pui. “That is an even more resistant form of leukemia, and up to 5%-10% of the patients have been reported to develop this complication.

“We performed consolidation transplantation in these patients to avoid the risk of lineage switch but would accept the parental request not to perform allogeneic transplant after they were clearly informed of the risk,” he told this news organization.

He also suggested that this approach of co-administration of two types of CAR T cells would be especially suitable for “patients with extramedullary involvement, because most of them will be spared of local irradiation so that they can preserve their neurocognitive function and fertility and avoid radiation-induced second cancer, such as brain tumor,” he said.
 

Lower toxicity

With regard to toxicity, the majority of patients (n = 98, 88%) developed cytokine release syndrome, which was grade ≥3 in 64 (28.4%) patients and fatal in one. Neurotoxicity occurred in 47 (20.9%) patients, was of grade ≥3 in 9 (4.0%) patients, and was fatal in 2 patients who received 12 x 106 and 5.6 x 106 CAR T cells/kg.

In addition, grade 3 or 4 seizure developed in 14.2% of the patients; it was more common in those who had presented with isolated or combined CNS leukemia. Grade 3 or 4 hypotension occurred in 40.9% of the patients. About three-quarters of the patients were treated with tocilizumab (n = 67, 74.2%), and 79 (35.1%) were treated with corticosteroids.

“In general, CD19 and CD22 CAR T cells were less toxic than CD19 CAR T cells, the historical controls, in our experience,” said Dr. Pui. “There were three fatal complications, a rate not excessive considering a large number of patients were treated.”
 

Future studies needed

The researchers note that in this trial, the CD22 CAR T cells did not expand as robustly or persist as long as did the CD19 CAR T cells, and they hope that future studies will elucidate whether enhancing CD22 CAR T-cell persistence and activity would further improve outcomes.

The study was supported in part by the National Natural Science Foundation of China, the Shanghai Collaborative Innovation Center for Translational Medicine, the Research Programs of Shanghai Science, the Technology Commission Foundation, the U.S. National Cancer Institute, the VIVA China Children’s Cancer Foundation, and the American Lebanese Syrian Associated Charities.

A version of this article first appeared on Medscape.com.

While great strides have been made in children’s leukemia care during the past 50 years, statistics have remained grim. For acute myeloid leukemia (AML), the most common type, 5-year survival rates were just 69% for children younger than 15 between 2009 and 2015. Patients who do survive past adolescence face high risks of future complications.

Specialists say the challenges hindering more progress include a lack of clinical research, an emphasis on competition over cooperation, and sparse insight into how best to adjust adult leukemia treatments to children. Now, a large clinical trial launched by the Leukemia & Lymphoma Society (LLS) seeks to revolutionize pediatric AML care by testing multiple experimental treatments across the globe. Its goal goes beyond simply boosting survival.

“Our project aims to find better treatments, more targeted treatments, that will leave children with fewer long-term health problems as adults. We want them to not just survive but thrive,” Gwen Nichols, MD, chief medical officer of LLS, said in an interview. “What we’ve had was not working for anybody. So we have to try a different approach.”

The LLS Pediatric Acute Leukemia (PedAL) Master Trial launched in spring of 2022. Seventy-five study locations from Nova Scotia to Hawaii are now recruiting patients up to age 22 with known or suspected relapsed/refractory AML, mixed phenotype acute leukemia, or relapsed acute lymphoblastic leukemia (ALL).

The 5-year trial expects to recruit 960 participants in the United States and Canada. Clinics in Europe, Australia, and New Zealand also are taking part.

“Pediatric oncologists should know that PedAL, for the first time, is providing a cooperative, seamless way to interrogate [the genomics of] a child’s leukemia,” hematologist/oncologist Todd Cooper, DO, section chief of pediatric oncology at Seattle Children’s Cancer and Blood Disorders Center, said in an interview. “It is also providing a seamless and efficient way for children to be assigned to clinical trials that are going to be tailored towards a particular child’s leukemia. This is something that’s never been done.”

In North America, all trial participants with relapsed AML will undergo genetic sequencing for free as part of the screening process. Clinics “can’t always access genomic screening for their patients,” Dr. Nichols said. “We’re providing that even if they don’t participate in any other part of the trial, even if they go and get another available therapy or go on a different trial. We want them to know that this is available, and they will get the results. And if they’re looking for a trial when they get those results, we have trained oncology nurses who will help them navigate and find clinical trials.”

In PedAL itself, one subtrial is now in progress: An open-label phase 3 randomized multicenter analysis of whether the oral leukemia drug venetoclax combined with the intensive infused chemotherapy treatment FLA+GO (fludarabine, high-dose cytarabine, and gemtuzumab ozogamicin) will improve overall survival compared to FLA+GO alone. Ninety-eight subjects are expected to join the 5-year subtrial.

“We expect within the next year to open three or four different subtrials of targeted therapies for specific groups of patients,” E. Anders Kolb, MD, chief of oncology and hematology at Nemours Children’s Health in Delaware and cochair of the PedAL trial, said in an interview. “Over the course of the next few years, we’re going to learn a lot about the natural history of relapsed leukemia – we don’t have a ton of data on that – and then how targeted therapies may alter some of those outcomes.”

Discussions with multiple drugmakers are in progress regarding the potential subtrials, he said.

The PedAL strategy addresses the lack of new drugs for children with AML, Seattle Children’s Dr. Cooper said. One main reason for the gap is that childhood leukemia is much less common than the adult form, he said, so a lot of drug development is geared toward adults. As a result, he said, new drugs “are geared towards adults whose leukemia is not as aggressive. Whereas in children, the acute leukemias, especially AML, are quite aggressive and need therapies that are often more intense.”

In addition, he said, “we have only recently become aware of how AML is biologically much different than in adults.”

In AML, Delaware’s Dr. Kolb explained, “there are many different phenotypes – ways that these cells can look and behave. But we treat them with a single regimen. What I like to tell families is that we’ve got a few tools in our toolbox, but they all happen to be sledgehammers. The key to the challenge in AML is that it is a molecular disease, but we’re treating it with therapies that were developed 40-50 years ago.”

In PedAL, the goal is to figure out the best ways to target therapy for the specific types that patients have. On this front, the genomic screening in the trial is crucial because it will identify which patients express certain targets and allow them to be assigned to appropriate sub-trials, Dr. Coooper said.

What’s next? “LLS has planned for this to be ongoing for the next 5 to 7 years, so that we can get a number of studies up and running,” Dr. Nichols said. “After that, those studies will continue. We will hope that most of them can be self-funded by then.”

As for cost, she noted that the PedAL trial is part of the society’s Dare to Dream Project, formerly known as the Children’s Initiative, which focuses on pediatric blood cancers. The project, with a fundraising goal of $175 million, focuses on research, patient services and survivorship.

”We have a whole range of services, travel assistance, copay programs and educational resources that doctors may want to use as a valid source of information,” she said. ‘When I was in practice, patients were always asking me, ‘Do you have anything I can read or take home to give my son something about his disease?’ LLS has good-quality, patient-level information for patients. We welcome people contacting us or going to our website and taking advantage of that for free.”

Dr. Nichols and Dr. Kolb report no disclosures. Dr. Cooper reports academic funding from LLS.

While great strides have been made in children’s leukemia care during the past 50 years, statistics have remained grim. For acute myeloid leukemia (AML), the most common type, 5-year survival rates were just 69% for children younger than 15 between 2009 and 2015. Patients who do survive past adolescence face high risks of future complications.

Specialists say the challenges hindering more progress include a lack of clinical research, an emphasis on competition over cooperation, and sparse insight into how best to adjust adult leukemia treatments to children. Now, a large clinical trial launched by the Leukemia & Lymphoma Society (LLS) seeks to revolutionize pediatric AML care by testing multiple experimental treatments across the globe. Its goal goes beyond simply boosting survival.

“Our project aims to find better treatments, more targeted treatments, that will leave children with fewer long-term health problems as adults. We want them to not just survive but thrive,” Gwen Nichols, MD, chief medical officer of LLS, said in an interview. “What we’ve had was not working for anybody. So we have to try a different approach.”

The LLS Pediatric Acute Leukemia (PedAL) Master Trial launched in spring of 2022. Seventy-five study locations from Nova Scotia to Hawaii are now recruiting patients up to age 22 with known or suspected relapsed/refractory AML, mixed phenotype acute leukemia, or relapsed acute lymphoblastic leukemia (ALL).

The 5-year trial expects to recruit 960 participants in the United States and Canada. Clinics in Europe, Australia, and New Zealand also are taking part.

“Pediatric oncologists should know that PedAL, for the first time, is providing a cooperative, seamless way to interrogate [the genomics of] a child’s leukemia,” hematologist/oncologist Todd Cooper, DO, section chief of pediatric oncology at Seattle Children’s Cancer and Blood Disorders Center, said in an interview. “It is also providing a seamless and efficient way for children to be assigned to clinical trials that are going to be tailored towards a particular child’s leukemia. This is something that’s never been done.”

In North America, all trial participants with relapsed AML will undergo genetic sequencing for free as part of the screening process. Clinics “can’t always access genomic screening for their patients,” Dr. Nichols said. “We’re providing that even if they don’t participate in any other part of the trial, even if they go and get another available therapy or go on a different trial. We want them to know that this is available, and they will get the results. And if they’re looking for a trial when they get those results, we have trained oncology nurses who will help them navigate and find clinical trials.”

In PedAL itself, one subtrial is now in progress: An open-label phase 3 randomized multicenter analysis of whether the oral leukemia drug venetoclax combined with the intensive infused chemotherapy treatment FLA+GO (fludarabine, high-dose cytarabine, and gemtuzumab ozogamicin) will improve overall survival compared to FLA+GO alone. Ninety-eight subjects are expected to join the 5-year subtrial.

“We expect within the next year to open three or four different subtrials of targeted therapies for specific groups of patients,” E. Anders Kolb, MD, chief of oncology and hematology at Nemours Children’s Health in Delaware and cochair of the PedAL trial, said in an interview. “Over the course of the next few years, we’re going to learn a lot about the natural history of relapsed leukemia – we don’t have a ton of data on that – and then how targeted therapies may alter some of those outcomes.”

Discussions with multiple drugmakers are in progress regarding the potential subtrials, he said.

The PedAL strategy addresses the lack of new drugs for children with AML, Seattle Children’s Dr. Cooper said. One main reason for the gap is that childhood leukemia is much less common than the adult form, he said, so a lot of drug development is geared toward adults. As a result, he said, new drugs “are geared towards adults whose leukemia is not as aggressive. Whereas in children, the acute leukemias, especially AML, are quite aggressive and need therapies that are often more intense.”

In addition, he said, “we have only recently become aware of how AML is biologically much different than in adults.”

In AML, Delaware’s Dr. Kolb explained, “there are many different phenotypes – ways that these cells can look and behave. But we treat them with a single regimen. What I like to tell families is that we’ve got a few tools in our toolbox, but they all happen to be sledgehammers. The key to the challenge in AML is that it is a molecular disease, but we’re treating it with therapies that were developed 40-50 years ago.”

In PedAL, the goal is to figure out the best ways to target therapy for the specific types that patients have. On this front, the genomic screening in the trial is crucial because it will identify which patients express certain targets and allow them to be assigned to appropriate sub-trials, Dr. Coooper said.

What’s next? “LLS has planned for this to be ongoing for the next 5 to 7 years, so that we can get a number of studies up and running,” Dr. Nichols said. “After that, those studies will continue. We will hope that most of them can be self-funded by then.”

As for cost, she noted that the PedAL trial is part of the society’s Dare to Dream Project, formerly known as the Children’s Initiative, which focuses on pediatric blood cancers. The project, with a fundraising goal of $175 million, focuses on research, patient services and survivorship.

”We have a whole range of services, travel assistance, copay programs and educational resources that doctors may want to use as a valid source of information,” she said. ‘When I was in practice, patients were always asking me, ‘Do you have anything I can read or take home to give my son something about his disease?’ LLS has good-quality, patient-level information for patients. We welcome people contacting us or going to our website and taking advantage of that for free.”

Dr. Nichols and Dr. Kolb report no disclosures. Dr. Cooper reports academic funding from LLS.

While great strides have been made in children’s leukemia care during the past 50 years, statistics have remained grim. For acute myeloid leukemia (AML), the most common type, 5-year survival rates were just 69% for children younger than 15 between 2009 and 2015. Patients who do survive past adolescence face high risks of future complications.

Specialists say the challenges hindering more progress include a lack of clinical research, an emphasis on competition over cooperation, and sparse insight into how best to adjust adult leukemia treatments to children. Now, a large clinical trial launched by the Leukemia & Lymphoma Society (LLS) seeks to revolutionize pediatric AML care by testing multiple experimental treatments across the globe. Its goal goes beyond simply boosting survival.

“Our project aims to find better treatments, more targeted treatments, that will leave children with fewer long-term health problems as adults. We want them to not just survive but thrive,” Gwen Nichols, MD, chief medical officer of LLS, said in an interview. “What we’ve had was not working for anybody. So we have to try a different approach.”

The LLS Pediatric Acute Leukemia (PedAL) Master Trial launched in spring of 2022. Seventy-five study locations from Nova Scotia to Hawaii are now recruiting patients up to age 22 with known or suspected relapsed/refractory AML, mixed phenotype acute leukemia, or relapsed acute lymphoblastic leukemia (ALL).

The 5-year trial expects to recruit 960 participants in the United States and Canada. Clinics in Europe, Australia, and New Zealand also are taking part.

“Pediatric oncologists should know that PedAL, for the first time, is providing a cooperative, seamless way to interrogate [the genomics of] a child’s leukemia,” hematologist/oncologist Todd Cooper, DO, section chief of pediatric oncology at Seattle Children’s Cancer and Blood Disorders Center, said in an interview. “It is also providing a seamless and efficient way for children to be assigned to clinical trials that are going to be tailored towards a particular child’s leukemia. This is something that’s never been done.”

In North America, all trial participants with relapsed AML will undergo genetic sequencing for free as part of the screening process. Clinics “can’t always access genomic screening for their patients,” Dr. Nichols said. “We’re providing that even if they don’t participate in any other part of the trial, even if they go and get another available therapy or go on a different trial. We want them to know that this is available, and they will get the results. And if they’re looking for a trial when they get those results, we have trained oncology nurses who will help them navigate and find clinical trials.”

In PedAL itself, one subtrial is now in progress: An open-label phase 3 randomized multicenter analysis of whether the oral leukemia drug venetoclax combined with the intensive infused chemotherapy treatment FLA+GO (fludarabine, high-dose cytarabine, and gemtuzumab ozogamicin) will improve overall survival compared to FLA+GO alone. Ninety-eight subjects are expected to join the 5-year subtrial.

“We expect within the next year to open three or four different subtrials of targeted therapies for specific groups of patients,” E. Anders Kolb, MD, chief of oncology and hematology at Nemours Children’s Health in Delaware and cochair of the PedAL trial, said in an interview. “Over the course of the next few years, we’re going to learn a lot about the natural history of relapsed leukemia – we don’t have a ton of data on that – and then how targeted therapies may alter some of those outcomes.”

Discussions with multiple drugmakers are in progress regarding the potential subtrials, he said.

The PedAL strategy addresses the lack of new drugs for children with AML, Seattle Children’s Dr. Cooper said. One main reason for the gap is that childhood leukemia is much less common than the adult form, he said, so a lot of drug development is geared toward adults. As a result, he said, new drugs “are geared towards adults whose leukemia is not as aggressive. Whereas in children, the acute leukemias, especially AML, are quite aggressive and need therapies that are often more intense.”

In addition, he said, “we have only recently become aware of how AML is biologically much different than in adults.”

In AML, Delaware’s Dr. Kolb explained, “there are many different phenotypes – ways that these cells can look and behave. But we treat them with a single regimen. What I like to tell families is that we’ve got a few tools in our toolbox, but they all happen to be sledgehammers. The key to the challenge in AML is that it is a molecular disease, but we’re treating it with therapies that were developed 40-50 years ago.”

In PedAL, the goal is to figure out the best ways to target therapy for the specific types that patients have. On this front, the genomic screening in the trial is crucial because it will identify which patients express certain targets and allow them to be assigned to appropriate sub-trials, Dr. Coooper said.

What’s next? “LLS has planned for this to be ongoing for the next 5 to 7 years, so that we can get a number of studies up and running,” Dr. Nichols said. “After that, those studies will continue. We will hope that most of them can be self-funded by then.”

As for cost, she noted that the PedAL trial is part of the society’s Dare to Dream Project, formerly known as the Children’s Initiative, which focuses on pediatric blood cancers. The project, with a fundraising goal of $175 million, focuses on research, patient services and survivorship.

”We have a whole range of services, travel assistance, copay programs and educational resources that doctors may want to use as a valid source of information,” she said. ‘When I was in practice, patients were always asking me, ‘Do you have anything I can read or take home to give my son something about his disease?’ LLS has good-quality, patient-level information for patients. We welcome people contacting us or going to our website and taking advantage of that for free.”

Dr. Nichols and Dr. Kolb report no disclosures. Dr. Cooper reports academic funding from LLS.

Patients undergoing chimeric antigen receptor (CAR) T-cell therapy who develop potentially serious neurotoxicity from the therapy show elevated plasma levels of neurofilament light chain (NfL) prior to the treatment, suggesting a possibly important predictor of risk for the side effect.

“This is the first study to show NfL levels are elevated even before CAR T treatment is given,” first author Omar H. Butt, MD, PhD, of the Siteman Cancer Center at Barnes-Jewish Hospital and Washington University in St. Louis, said in an interview.

“While unlikely to be the sole driver of [the neurotoxicity], neural injury reflected by NfL may aid in identifying a high-risk subset of patients undergoing cellular therapy,” the authors concluded in the study, published in JAMA Oncology.

CAR T-cell therapy has gained favor for virtually revolutionizing the treatment of some leukemias and lymphomas, however, as many as 40%-60% of patients develop the neurotoxicity side effect, called immune effector cell–associated neurotoxicity syndrome (ICANS), which, though usually low grade, in more severe cases can cause substantial morbidity and even mortality.

Hence, “the early identification of patients at risk for ICANS is critical for preemptive management,” the authors noted.

NfL, an established marker of neuroaxonal injury in neurodegenerative diseases including multiple sclerosis and Alzheimer’s disease, has been shown in previous studies to be elevated following the development of ICANS and up to 5 days prior to its peak symptoms.

To further evaluate NfL elevations in relation to ICANS, Dr. Butt and colleagues identified 30 patients undergoing CD19 CART-cell therapy, including 77% for diffuse large B-cell lymphoma, at two U.S. centers: Washington University in St. Louis and Case Western Reserve University, Cleveland.

The patients had a median age of 64 and were 40% female.

Among them, four developed low-grade ICANS grade 1-2, and 7 developed ICANS grade 3 or higher.

Of those developing any-grade ICANS, baseline elevations of NfL prior to the CAR T-cell treatment, were significantly higher, compared with those who did not develop ICANs (mean 87.6 pg/mL vs. 29.4 pg/mL, P < .001), with no significant differences between the low-grade (1 and 2) and higher-grade (3 or higher) ICANS groups.

A receiver operating characteristic analysis showed baseline NfL levels significantly predicted the development of ICANS with high accuracy (area under the ROC curve, 0.96), as well as sensitivity (AUROC, 0.91) and specificity (AUROC, 0.95).

Notably, baseline NfL levels were associated with ICANS severity, but did not correlate with other factors including demographic, oncologic history, nononcologic neurologic history, or history of exposure to neurotoxic therapies.

However, Dr. Butt added, “it is important to note that our study was insufficiently powered to examine those relationships in earnest. Therefore, [a correlation between NfL and those factors] remains possible,” he said.

The elevated NfL levels observed prior to the development of ICANS remained high across the study’s seven time points, up to day 30 post infusion.
 

Interest in NfL levels on the rise

NfL assessment is currently only clinically validated in amyotrophic lateral sclerosis, where it is used to assess neuroaxonal health and integrity. However, testing is available as interest and evidence of NfL’s potential role in other settings grows.

Meanwhile, Dr. Butt and associates are themselves developing an assay to predict the development of ICANS, which will likely include NfL, if the role is validated in further studies.

“Future studies will explore validating NfL for ICANS and additional indications,” he said.

ICANS symptoms can range from headaches and confusion to seizures or strokes in more severe cases.

The current gold standard for treatment includes early intervention with high-dose steroids and careful monitoring, but there is reluctance to use such therapies because of concerns about their blunting the anticancer effects of the CAR T cells.

Importantly, if validated, elevations in NfL could signal the need for more precautionary measures with CAR T-cell therapy, Dr. Butt noted.

“Our data suggests patients with high NfL levels at baseline would benefit most from perhaps closer monitoring with frequent checks and possible early intervention at the first sign of symptoms, a period of time when it may be hard to distinguish ICANS from other causes of confusion, such as delirium,” he explained.
 

Limitations: Validation, preventive measures needed

Commenting on the study, Sattva S. Neelapu, MD, a professor and deputy chair of the department of lymphoma and myeloma at the University of Texas MD Anderson Cancer Center, Houston, agreed that the findings have potentially important implications.

“I think this is a very intriguing and novel finding that needs to be investigated further prospectively in a larger cohort and across different CAR T products in patients with lymphoma, leukemia, and myeloma,” Dr. Neelapu said in an interview.

The NfL elevations observed even before CAR T-cell therapy among those who went on to develop ICANS are notable, he added.

“This is the surprising finding in the study,” Dr. Neelapu said. “It raises the question whether neurologic injury is caused by prior therapies that these patients received or whether it is an age-related phenomenon, as we do see higher incidence and severity of ICANS in older patients or some other mechanisms.”

A key caveat, however, is that even if a risk is identified, options to prevent ICANS are currently limited, Dr. Neelapu noted.

“I think it is too early to implement this into clinical practice,” he said. In addition to needing further validation, “assessing NfL levels would be useful when there is an effective prophylactic or therapeutic strategy – both of which also need to be investigated.”

Dr. Butt and colleagues are developing a clinical assay for ICANS and reported a provisional patent pending on the use of plasma NfL as a predictive biomarker for ICANS. The study received support from the Washington University in St. Louis, the Paula and Rodger O. Riney Fund, the Daniel J. Brennan MD Fund, the Fred Simmons and Olga Mohan Fund; the National Cancer Institute, the National Multiple Sclerosis Society, and the National Institute of Neurological Disorders and Stroke. Dr. Neelapu reported conflicts of interest with numerous pharmaceutical companies.

Patients undergoing chimeric antigen receptor (CAR) T-cell therapy who develop potentially serious neurotoxicity from the therapy show elevated plasma levels of neurofilament light chain (NfL) prior to the treatment, suggesting a possibly important predictor of risk for the side effect.

“This is the first study to show NfL levels are elevated even before CAR T treatment is given,” first author Omar H. Butt, MD, PhD, of the Siteman Cancer Center at Barnes-Jewish Hospital and Washington University in St. Louis, said in an interview.

“While unlikely to be the sole driver of [the neurotoxicity], neural injury reflected by NfL may aid in identifying a high-risk subset of patients undergoing cellular therapy,” the authors concluded in the study, published in JAMA Oncology.

CAR T-cell therapy has gained favor for virtually revolutionizing the treatment of some leukemias and lymphomas, however, as many as 40%-60% of patients develop the neurotoxicity side effect, called immune effector cell–associated neurotoxicity syndrome (ICANS), which, though usually low grade, in more severe cases can cause substantial morbidity and even mortality.

Hence, “the early identification of patients at risk for ICANS is critical for preemptive management,” the authors noted.

NfL, an established marker of neuroaxonal injury in neurodegenerative diseases including multiple sclerosis and Alzheimer’s disease, has been shown in previous studies to be elevated following the development of ICANS and up to 5 days prior to its peak symptoms.

To further evaluate NfL elevations in relation to ICANS, Dr. Butt and colleagues identified 30 patients undergoing CD19 CART-cell therapy, including 77% for diffuse large B-cell lymphoma, at two U.S. centers: Washington University in St. Louis and Case Western Reserve University, Cleveland.

The patients had a median age of 64 and were 40% female.

Among them, four developed low-grade ICANS grade 1-2, and 7 developed ICANS grade 3 or higher.

Of those developing any-grade ICANS, baseline elevations of NfL prior to the CAR T-cell treatment, were significantly higher, compared with those who did not develop ICANs (mean 87.6 pg/mL vs. 29.4 pg/mL, P < .001), with no significant differences between the low-grade (1 and 2) and higher-grade (3 or higher) ICANS groups.

A receiver operating characteristic analysis showed baseline NfL levels significantly predicted the development of ICANS with high accuracy (area under the ROC curve, 0.96), as well as sensitivity (AUROC, 0.91) and specificity (AUROC, 0.95).

Notably, baseline NfL levels were associated with ICANS severity, but did not correlate with other factors including demographic, oncologic history, nononcologic neurologic history, or history of exposure to neurotoxic therapies.

However, Dr. Butt added, “it is important to note that our study was insufficiently powered to examine those relationships in earnest. Therefore, [a correlation between NfL and those factors] remains possible,” he said.

The elevated NfL levels observed prior to the development of ICANS remained high across the study’s seven time points, up to day 30 post infusion.
 

Interest in NfL levels on the rise

NfL assessment is currently only clinically validated in amyotrophic lateral sclerosis, where it is used to assess neuroaxonal health and integrity. However, testing is available as interest and evidence of NfL’s potential role in other settings grows.

Meanwhile, Dr. Butt and associates are themselves developing an assay to predict the development of ICANS, which will likely include NfL, if the role is validated in further studies.

“Future studies will explore validating NfL for ICANS and additional indications,” he said.

ICANS symptoms can range from headaches and confusion to seizures or strokes in more severe cases.

The current gold standard for treatment includes early intervention with high-dose steroids and careful monitoring, but there is reluctance to use such therapies because of concerns about their blunting the anticancer effects of the CAR T cells.

Importantly, if validated, elevations in NfL could signal the need for more precautionary measures with CAR T-cell therapy, Dr. Butt noted.

“Our data suggests patients with high NfL levels at baseline would benefit most from perhaps closer monitoring with frequent checks and possible early intervention at the first sign of symptoms, a period of time when it may be hard to distinguish ICANS from other causes of confusion, such as delirium,” he explained.
 

Limitations: Validation, preventive measures needed

Commenting on the study, Sattva S. Neelapu, MD, a professor and deputy chair of the department of lymphoma and myeloma at the University of Texas MD Anderson Cancer Center, Houston, agreed that the findings have potentially important implications.

“I think this is a very intriguing and novel finding that needs to be investigated further prospectively in a larger cohort and across different CAR T products in patients with lymphoma, leukemia, and myeloma,” Dr. Neelapu said in an interview.

The NfL elevations observed even before CAR T-cell therapy among those who went on to develop ICANS are notable, he added.

“This is the surprising finding in the study,” Dr. Neelapu said. “It raises the question whether neurologic injury is caused by prior therapies that these patients received or whether it is an age-related phenomenon, as we do see higher incidence and severity of ICANS in older patients or some other mechanisms.”

A key caveat, however, is that even if a risk is identified, options to prevent ICANS are currently limited, Dr. Neelapu noted.

“I think it is too early to implement this into clinical practice,” he said. In addition to needing further validation, “assessing NfL levels would be useful when there is an effective prophylactic or therapeutic strategy – both of which also need to be investigated.”

Dr. Butt and colleagues are developing a clinical assay for ICANS and reported a provisional patent pending on the use of plasma NfL as a predictive biomarker for ICANS. The study received support from the Washington University in St. Louis, the Paula and Rodger O. Riney Fund, the Daniel J. Brennan MD Fund, the Fred Simmons and Olga Mohan Fund; the National Cancer Institute, the National Multiple Sclerosis Society, and the National Institute of Neurological Disorders and Stroke. Dr. Neelapu reported conflicts of interest with numerous pharmaceutical companies.

Patients undergoing chimeric antigen receptor (CAR) T-cell therapy who develop potentially serious neurotoxicity from the therapy show elevated plasma levels of neurofilament light chain (NfL) prior to the treatment, suggesting a possibly important predictor of risk for the side effect.

“This is the first study to show NfL levels are elevated even before CAR T treatment is given,” first author Omar H. Butt, MD, PhD, of the Siteman Cancer Center at Barnes-Jewish Hospital and Washington University in St. Louis, said in an interview.

“While unlikely to be the sole driver of [the neurotoxicity], neural injury reflected by NfL may aid in identifying a high-risk subset of patients undergoing cellular therapy,” the authors concluded in the study, published in JAMA Oncology.

CAR T-cell therapy has gained favor for virtually revolutionizing the treatment of some leukemias and lymphomas, however, as many as 40%-60% of patients develop the neurotoxicity side effect, called immune effector cell–associated neurotoxicity syndrome (ICANS), which, though usually low grade, in more severe cases can cause substantial morbidity and even mortality.

Hence, “the early identification of patients at risk for ICANS is critical for preemptive management,” the authors noted.

NfL, an established marker of neuroaxonal injury in neurodegenerative diseases including multiple sclerosis and Alzheimer’s disease, has been shown in previous studies to be elevated following the development of ICANS and up to 5 days prior to its peak symptoms.

To further evaluate NfL elevations in relation to ICANS, Dr. Butt and colleagues identified 30 patients undergoing CD19 CART-cell therapy, including 77% for diffuse large B-cell lymphoma, at two U.S. centers: Washington University in St. Louis and Case Western Reserve University, Cleveland.

The patients had a median age of 64 and were 40% female.

Among them, four developed low-grade ICANS grade 1-2, and 7 developed ICANS grade 3 or higher.

Of those developing any-grade ICANS, baseline elevations of NfL prior to the CAR T-cell treatment, were significantly higher, compared with those who did not develop ICANs (mean 87.6 pg/mL vs. 29.4 pg/mL, P < .001), with no significant differences between the low-grade (1 and 2) and higher-grade (3 or higher) ICANS groups.

A receiver operating characteristic analysis showed baseline NfL levels significantly predicted the development of ICANS with high accuracy (area under the ROC curve, 0.96), as well as sensitivity (AUROC, 0.91) and specificity (AUROC, 0.95).

Notably, baseline NfL levels were associated with ICANS severity, but did not correlate with other factors including demographic, oncologic history, nononcologic neurologic history, or history of exposure to neurotoxic therapies.

However, Dr. Butt added, “it is important to note that our study was insufficiently powered to examine those relationships in earnest. Therefore, [a correlation between NfL and those factors] remains possible,” he said.

The elevated NfL levels observed prior to the development of ICANS remained high across the study’s seven time points, up to day 30 post infusion.
 

Interest in NfL levels on the rise

NfL assessment is currently only clinically validated in amyotrophic lateral sclerosis, where it is used to assess neuroaxonal health and integrity. However, testing is available as interest and evidence of NfL’s potential role in other settings grows.

Meanwhile, Dr. Butt and associates are themselves developing an assay to predict the development of ICANS, which will likely include NfL, if the role is validated in further studies.

“Future studies will explore validating NfL for ICANS and additional indications,” he said.

ICANS symptoms can range from headaches and confusion to seizures or strokes in more severe cases.

The current gold standard for treatment includes early intervention with high-dose steroids and careful monitoring, but there is reluctance to use such therapies because of concerns about their blunting the anticancer effects of the CAR T cells.

Importantly, if validated, elevations in NfL could signal the need for more precautionary measures with CAR T-cell therapy, Dr. Butt noted.

“Our data suggests patients with high NfL levels at baseline would benefit most from perhaps closer monitoring with frequent checks and possible early intervention at the first sign of symptoms, a period of time when it may be hard to distinguish ICANS from other causes of confusion, such as delirium,” he explained.
 

Limitations: Validation, preventive measures needed

Commenting on the study, Sattva S. Neelapu, MD, a professor and deputy chair of the department of lymphoma and myeloma at the University of Texas MD Anderson Cancer Center, Houston, agreed that the findings have potentially important implications.

“I think this is a very intriguing and novel finding that needs to be investigated further prospectively in a larger cohort and across different CAR T products in patients with lymphoma, leukemia, and myeloma,” Dr. Neelapu said in an interview.

The NfL elevations observed even before CAR T-cell therapy among those who went on to develop ICANS are notable, he added.

“This is the surprising finding in the study,” Dr. Neelapu said. “It raises the question whether neurologic injury is caused by prior therapies that these patients received or whether it is an age-related phenomenon, as we do see higher incidence and severity of ICANS in older patients or some other mechanisms.”

A key caveat, however, is that even if a risk is identified, options to prevent ICANS are currently limited, Dr. Neelapu noted.

“I think it is too early to implement this into clinical practice,” he said. In addition to needing further validation, “assessing NfL levels would be useful when there is an effective prophylactic or therapeutic strategy – both of which also need to be investigated.”

Dr. Butt and colleagues are developing a clinical assay for ICANS and reported a provisional patent pending on the use of plasma NfL as a predictive biomarker for ICANS. The study received support from the Washington University in St. Louis, the Paula and Rodger O. Riney Fund, the Daniel J. Brennan MD Fund, the Fred Simmons and Olga Mohan Fund; the National Cancer Institute, the National Multiple Sclerosis Society, and the National Institute of Neurological Disorders and Stroke. Dr. Neelapu reported conflicts of interest with numerous pharmaceutical companies.

Ibrutinib (Imbruvica) is now available for use in children aged 1-12 years who have chronic graft-versus-host disease (cGVHD), which can develop after stem cell transplantation for treatment of a blood cancer.

Specifically, the indication is for pediatric patients with cGVHD who have already been treated with one or more lines of systemic therapy. The manufacturers have also launched a new oral suspension formulation, in addition to capsules and tablets, which were already available.

Ibrutinib is already approved for use in adults with cGVHD.

The drug is also approved for use in several blood cancers, including chronic lymphocytic leukemia, mantle cell lymphoma, and Waldenström’s macroglobulinemia. All these approvals are for adult patients.

This is the first pediatric indication for the product and is “incredibly meaningful,” said Gauri Sunkersett, DO, associate medical director at AbbVie, which markets the drug together with Jansen. “As a pediatric oncologist, when my patients describe the physical pain they experience from simply hugging their parents, due to their cGVHD, the importance of researching alternative treatment options in this patient population is further validated.”

These children have already been through a lot, having been diagnosed with a leukemia or lymphoma and then undergoing chemotherapy and/or radiotherapy for a stem cell transplant. Just over half (52%-65%) of children who receive allogeneic transplants go on to develop cGVHD, in which the donor bone marrow or stem cells attack the recipient.

“Imagine going through a transplant and then being told you have a moderate to severe chronic disease that can sometimes also be life-threatening,” commented Paul A. Carpenter, MD, attending physician at Seattle Children’s Hospital. “If these children were between 1 and 12 and didn’t respond to steroid treatment, we didn’t have any rigorously studied treatment options – until now.”

The new indication was approved by the U.S. Food and Drug Administration on the basis of results from the iMAGINE trial, for which Dr. Carpenter was a principal investigator.

The phase 1/2 iMAGINE trial was an open-label, multicenter, single-arm trial conducted with 47 patients (mean age, 13 years; range, 1-19 years) with relapsed/refractory cGVHD who had received at least one prior systemic therapy. Ibrutinib was given at a dose of 420 mg orally once daily to patients aged 12 and older and at a dose of 240 mg/m2 orally once daily to patients who were younger than 12 years.

The overall response rate through week 25 was 60% (confidence interval, 95%, 44%-74%). The median duration of response was 5.3 months (95% CI, 2.8-8.8).

The safety profile was consistent with the established profile for ibrutinib. Observed adverse events in pediatric patients were consistent with those observed in adult patients with moderate to severe cGVHD, the companies noted.

The FDA noted that the most common (≥ 20%) adverse reactions, including laboratory abnormalities, were anemia, musculoskeletal pain, pyrexia, diarrhea, pneumonia, abdominal pain, stomatitis, thrombocytopenia, and headache.

Full prescribing information for ibrutinib is available here.

A version of this article first appeared on Medscape.com.

Ibrutinib (Imbruvica) is now available for use in children aged 1-12 years who have chronic graft-versus-host disease (cGVHD), which can develop after stem cell transplantation for treatment of a blood cancer.

Specifically, the indication is for pediatric patients with cGVHD who have already been treated with one or more lines of systemic therapy. The manufacturers have also launched a new oral suspension formulation, in addition to capsules and tablets, which were already available.

Ibrutinib is already approved for use in adults with cGVHD.

The drug is also approved for use in several blood cancers, including chronic lymphocytic leukemia, mantle cell lymphoma, and Waldenström’s macroglobulinemia. All these approvals are for adult patients.

This is the first pediatric indication for the product and is “incredibly meaningful,” said Gauri Sunkersett, DO, associate medical director at AbbVie, which markets the drug together with Jansen. “As a pediatric oncologist, when my patients describe the physical pain they experience from simply hugging their parents, due to their cGVHD, the importance of researching alternative treatment options in this patient population is further validated.”

These children have already been through a lot, having been diagnosed with a leukemia or lymphoma and then undergoing chemotherapy and/or radiotherapy for a stem cell transplant. Just over half (52%-65%) of children who receive allogeneic transplants go on to develop cGVHD, in which the donor bone marrow or stem cells attack the recipient.

“Imagine going through a transplant and then being told you have a moderate to severe chronic disease that can sometimes also be life-threatening,” commented Paul A. Carpenter, MD, attending physician at Seattle Children’s Hospital. “If these children were between 1 and 12 and didn’t respond to steroid treatment, we didn’t have any rigorously studied treatment options – until now.”

The new indication was approved by the U.S. Food and Drug Administration on the basis of results from the iMAGINE trial, for which Dr. Carpenter was a principal investigator.

The phase 1/2 iMAGINE trial was an open-label, multicenter, single-arm trial conducted with 47 patients (mean age, 13 years; range, 1-19 years) with relapsed/refractory cGVHD who had received at least one prior systemic therapy. Ibrutinib was given at a dose of 420 mg orally once daily to patients aged 12 and older and at a dose of 240 mg/m2 orally once daily to patients who were younger than 12 years.

The overall response rate through week 25 was 60% (confidence interval, 95%, 44%-74%). The median duration of response was 5.3 months (95% CI, 2.8-8.8).

The safety profile was consistent with the established profile for ibrutinib. Observed adverse events in pediatric patients were consistent with those observed in adult patients with moderate to severe cGVHD, the companies noted.

The FDA noted that the most common (≥ 20%) adverse reactions, including laboratory abnormalities, were anemia, musculoskeletal pain, pyrexia, diarrhea, pneumonia, abdominal pain, stomatitis, thrombocytopenia, and headache.

Full prescribing information for ibrutinib is available here.

A version of this article first appeared on Medscape.com.

Ibrutinib (Imbruvica) is now available for use in children aged 1-12 years who have chronic graft-versus-host disease (cGVHD), which can develop after stem cell transplantation for treatment of a blood cancer.

Specifically, the indication is for pediatric patients with cGVHD who have already been treated with one or more lines of systemic therapy. The manufacturers have also launched a new oral suspension formulation, in addition to capsules and tablets, which were already available.

Ibrutinib is already approved for use in adults with cGVHD.

The drug is also approved for use in several blood cancers, including chronic lymphocytic leukemia, mantle cell lymphoma, and Waldenström’s macroglobulinemia. All these approvals are for adult patients.

This is the first pediatric indication for the product and is “incredibly meaningful,” said Gauri Sunkersett, DO, associate medical director at AbbVie, which markets the drug together with Jansen. “As a pediatric oncologist, when my patients describe the physical pain they experience from simply hugging their parents, due to their cGVHD, the importance of researching alternative treatment options in this patient population is further validated.”

These children have already been through a lot, having been diagnosed with a leukemia or lymphoma and then undergoing chemotherapy and/or radiotherapy for a stem cell transplant. Just over half (52%-65%) of children who receive allogeneic transplants go on to develop cGVHD, in which the donor bone marrow or stem cells attack the recipient.

“Imagine going through a transplant and then being told you have a moderate to severe chronic disease that can sometimes also be life-threatening,” commented Paul A. Carpenter, MD, attending physician at Seattle Children’s Hospital. “If these children were between 1 and 12 and didn’t respond to steroid treatment, we didn’t have any rigorously studied treatment options – until now.”

The new indication was approved by the U.S. Food and Drug Administration on the basis of results from the iMAGINE trial, for which Dr. Carpenter was a principal investigator.

The phase 1/2 iMAGINE trial was an open-label, multicenter, single-arm trial conducted with 47 patients (mean age, 13 years; range, 1-19 years) with relapsed/refractory cGVHD who had received at least one prior systemic therapy. Ibrutinib was given at a dose of 420 mg orally once daily to patients aged 12 and older and at a dose of 240 mg/m2 orally once daily to patients who were younger than 12 years.

The overall response rate through week 25 was 60% (confidence interval, 95%, 44%-74%). The median duration of response was 5.3 months (95% CI, 2.8-8.8).

The safety profile was consistent with the established profile for ibrutinib. Observed adverse events in pediatric patients were consistent with those observed in adult patients with moderate to severe cGVHD, the companies noted.

The FDA noted that the most common (≥ 20%) adverse reactions, including laboratory abnormalities, were anemia, musculoskeletal pain, pyrexia, diarrhea, pneumonia, abdominal pain, stomatitis, thrombocytopenia, and headache.

Full prescribing information for ibrutinib is available here.

A version of this article first appeared on Medscape.com.

Two new studies offer insights into leukemia survival rates in the United States. From 2000 to 2014, a drop in mortality among children spurred a rise in 5-year leukemia survival rates among patients aged 0-24. But adolescents and young adults who survive 5 years after diagnosis face an ongoing higher risk of death, recent research revealed, and their long-term survival is lower compared to that of the general population.

“Outcomes are improving. However, additional efforts, support, and resources are needed to further improve short- and long-term survival for acute leukemia survivors. Targeted efforts focused on populations that face greater disparities in their survival are needed to move the needle faster,” Michael Roth, MD, codirector of the Adolescent and Young Adult Oncology Program at the University of Texas M.D. Anderson Cancer Center, said in an interview.

In one study, released in The Lancet Child & Adolescent Health, an international team of researchers tracked survival outcomes from various types of leukemia in 61 nations. The study focused on the years 2000-2014 and followed patients aged 0-24.

“Age-standardized 5-year net survival in children, adolescents, and young adults for all leukemias combined during 2010-14 varied widely, ranging from 46% in Mexico to more than 85% in Canada, Cyprus, Belgium, Denmark, Finland, and Australia,” the researchers wrote. “Throughout 2000-14, survival from all leukemias combined remained consistently higher for children than adolescents and young adults, and minimal improvement was seen for adolescents and young adults in most countries.”

The U.S. data came from 41 states that cover 86% of the nation’s population, lead author Naomi Ssenyonga, a research fellow at London School of Hygiene & Tropical Medicine, said in an interview.

The 5-year survival rate for acute lymphoid leukemia (ALL) rose from 80% during 2000-2004 to 86% during 2010-2014. Survival in patients with acute myeloid leukemia (AML) was lower than for other subtypes: 66% in 2010-2014 vs. 57% in 2000-2004.

In regard to all leukemias, “we noted a steady increase in the U.S. of 6 percentage points in 5-year survival, up from 77% for patients diagnosed during 2000-2004 to 83% for those diagnosed during 2010-2014,” Ms. Ssenyonga said. “The gains were largely driven by the improvements seen among children.”

Why haven’t adolescents and young adults gained as much ground in survival?

“They often have unique clinical needs,” Ms. Ssenyonga said. “Over the past few years, adolescents and young adults with leukemia in some parts of the world, including the U.S., have increasingly been treated under pediatric protocols. This has led to higher survival. However, this approach has not been adopted consistently, and survival for adolescents and young adults with leukemia is still generally lower than survival for children.”

Gwen Nichols, MD, chief medical officer of the Leukemia & Lymphoma Society, agreed that pediatric treatment protocols hold promise as treatments for young adults. However, “because we arbitrarily set an age cutoff for being an adult, many of these patients are treated by an adult [nonpediatric] hematologist/oncologist, and some patients in the 20-39 age group do not receive the more intensive treatment regimens given to children,” she said in an interview.

In another study, published in Cancer Epidemiology, Biomarkers, & Prevention, M.D. Anderson Cancer Center’s Dr. Roth and colleagues tracked 1,938 patients with ALL and 2,350 with AML who were diagnosed at ages 15-39 from 1980 to 2009. All lived at least 5 years after diagnosis. In both groups, about 58% were White, and most of the rest were Hispanic. The median age of diagnosis for ALL was 23 (range: 15-39) and 28 years for AML (range: 15-39).

“For ALL, 10-year survival for those diagnosed in the 1980s, 1990s, and 2000s was 83%, 88%, and 88%, respectively,” the researchers reported. “Ten-year survival for AML was 82%, 90%, and 90% for those diagnosed in the 1980s, 1990s, and 2000s, respectively.”

“Early mortality within 10 years of diagnosis was mostly secondary to leukemia progressing or recurring. We believe that later mortality is secondary to the development of late side effects from their cancer treatment,” Dr. Roth said.

He noted that many adolescents and young adults with ALL or AML receive stem-cell transplants. “This treatment approach is effective. However, it is associated with short- and long-term toxicity that impacts patients’ health for many years after treatment.”

Indeed, up to 80% of acute leukemia survivors have significant health complications after therapy, said the Leukemia & Lymphoma Society’s Dr. Nichols, who wasn’t surprised by the findings. According to the society, “even when treatments are effective, more than 70% of childhood cancer survivors have a chronic health condition and 42% have a severe, disabling or life-threatening condition 30 years after diagnosis.”

“It would be interesting to understand the male predominance better,” she added, noting that the study found that male patients had worse long-term survival than females (survival time ratio: 0.61, 95% confidence interval, 0.45-0.82). “While it is tempting to suggest it is due to difference in cardiac disease, I am not aware of data to support why there is this survival difference.”

What’s next? “In ALL, we now have a number of new modalities to treat high-risk and relapsed disease such as antibodies and CAR-T,” Dr. Nichols said. “We anticipate that 5-year survival can improve utilizing these modalities due to getting more patients into remission, hopefully while reducing chemotherapeutic toxicity.”

Dr. Nichol’s also highlighted the society’s new genomic-led Pediatric Acute Leukemia (PedAL) Master Clinical Trial, which began enrolling children with acute leukemia in the United States and Canada this year, in an effort to transform medicine’s traditional high-level chemotherapy strategy to their care. The project was launched in collaboration with the National Cancer Institute, Children’s Oncology Group, and the European Pediatric Acute Leukemia Foundation.

As part of the screening process, the biology of each child’s cancer will be identified, and families will be encouraged to enroll them in appropriate targeted therapy trials.

“Until we are able to decrease the toxicity of leukemia regimens, we won’t see a dramatic shift in late effects and thus in morbidity and mortality,” Dr. Nichols said. “The trial is an effort to test newer, less toxic regimens to begin to change that cycle.”

The 5-year survival study was funded by Children with Cancer UK, Institut National du Cancer, La Ligue Contre le Cancer, Centers for Disease Control and Prevention, Swiss Re, Swiss Cancer Research foundation, Swiss Cancer League, Rossy Family Foundation, National Cancer Institute, and the American Cancer Society. One author reports a grant from Macmillan Cancer Support, consultancy fees from Pfizer, and unsolicited small gifts from Moondance Cancer Initiative for philanthropic work. The other authors report no disclosures.

The long-term survival study was funded by the National Cancer Institute, the Archer Foundation and LyondellBasell Industries. Dr. Roth reports no disclosures; other authors report various disclosures. Dr. Nichols reports no disclosures.

Two new studies offer insights into leukemia survival rates in the United States. From 2000 to 2014, a drop in mortality among children spurred a rise in 5-year leukemia survival rates among patients aged 0-24. But adolescents and young adults who survive 5 years after diagnosis face an ongoing higher risk of death, recent research revealed, and their long-term survival is lower compared to that of the general population.

“Outcomes are improving. However, additional efforts, support, and resources are needed to further improve short- and long-term survival for acute leukemia survivors. Targeted efforts focused on populations that face greater disparities in their survival are needed to move the needle faster,” Michael Roth, MD, codirector of the Adolescent and Young Adult Oncology Program at the University of Texas M.D. Anderson Cancer Center, said in an interview.

In one study, released in The Lancet Child & Adolescent Health, an international team of researchers tracked survival outcomes from various types of leukemia in 61 nations. The study focused on the years 2000-2014 and followed patients aged 0-24.

“Age-standardized 5-year net survival in children, adolescents, and young adults for all leukemias combined during 2010-14 varied widely, ranging from 46% in Mexico to more than 85% in Canada, Cyprus, Belgium, Denmark, Finland, and Australia,” the researchers wrote. “Throughout 2000-14, survival from all leukemias combined remained consistently higher for children than adolescents and young adults, and minimal improvement was seen for adolescents and young adults in most countries.”

The U.S. data came from 41 states that cover 86% of the nation’s population, lead author Naomi Ssenyonga, a research fellow at London School of Hygiene & Tropical Medicine, said in an interview.

The 5-year survival rate for acute lymphoid leukemia (ALL) rose from 80% during 2000-2004 to 86% during 2010-2014. Survival in patients with acute myeloid leukemia (AML) was lower than for other subtypes: 66% in 2010-2014 vs. 57% in 2000-2004.

In regard to all leukemias, “we noted a steady increase in the U.S. of 6 percentage points in 5-year survival, up from 77% for patients diagnosed during 2000-2004 to 83% for those diagnosed during 2010-2014,” Ms. Ssenyonga said. “The gains were largely driven by the improvements seen among children.”

Why haven’t adolescents and young adults gained as much ground in survival?

“They often have unique clinical needs,” Ms. Ssenyonga said. “Over the past few years, adolescents and young adults with leukemia in some parts of the world, including the U.S., have increasingly been treated under pediatric protocols. This has led to higher survival. However, this approach has not been adopted consistently, and survival for adolescents and young adults with leukemia is still generally lower than survival for children.”

Gwen Nichols, MD, chief medical officer of the Leukemia & Lymphoma Society, agreed that pediatric treatment protocols hold promise as treatments for young adults. However, “because we arbitrarily set an age cutoff for being an adult, many of these patients are treated by an adult [nonpediatric] hematologist/oncologist, and some patients in the 20-39 age group do not receive the more intensive treatment regimens given to children,” she said in an interview.

In another study, published in Cancer Epidemiology, Biomarkers, & Prevention, M.D. Anderson Cancer Center’s Dr. Roth and colleagues tracked 1,938 patients with ALL and 2,350 with AML who were diagnosed at ages 15-39 from 1980 to 2009. All lived at least 5 years after diagnosis. In both groups, about 58% were White, and most of the rest were Hispanic. The median age of diagnosis for ALL was 23 (range: 15-39) and 28 years for AML (range: 15-39).

“For ALL, 10-year survival for those diagnosed in the 1980s, 1990s, and 2000s was 83%, 88%, and 88%, respectively,” the researchers reported. “Ten-year survival for AML was 82%, 90%, and 90% for those diagnosed in the 1980s, 1990s, and 2000s, respectively.”

“Early mortality within 10 years of diagnosis was mostly secondary to leukemia progressing or recurring. We believe that later mortality is secondary to the development of late side effects from their cancer treatment,” Dr. Roth said.

He noted that many adolescents and young adults with ALL or AML receive stem-cell transplants. “This treatment approach is effective. However, it is associated with short- and long-term toxicity that impacts patients’ health for many years after treatment.”

Indeed, up to 80% of acute leukemia survivors have significant health complications after therapy, said the Leukemia & Lymphoma Society’s Dr. Nichols, who wasn’t surprised by the findings. According to the society, “even when treatments are effective, more than 70% of childhood cancer survivors have a chronic health condition and 42% have a severe, disabling or life-threatening condition 30 years after diagnosis.”

“It would be interesting to understand the male predominance better,” she added, noting that the study found that male patients had worse long-term survival than females (survival time ratio: 0.61, 95% confidence interval, 0.45-0.82). “While it is tempting to suggest it is due to difference in cardiac disease, I am not aware of data to support why there is this survival difference.”

What’s next? “In ALL, we now have a number of new modalities to treat high-risk and relapsed disease such as antibodies and CAR-T,” Dr. Nichols said. “We anticipate that 5-year survival can improve utilizing these modalities due to getting more patients into remission, hopefully while reducing chemotherapeutic toxicity.”

Dr. Nichol’s also highlighted the society’s new genomic-led Pediatric Acute Leukemia (PedAL) Master Clinical Trial, which began enrolling children with acute leukemia in the United States and Canada this year, in an effort to transform medicine’s traditional high-level chemotherapy strategy to their care. The project was launched in collaboration with the National Cancer Institute, Children’s Oncology Group, and the European Pediatric Acute Leukemia Foundation.

As part of the screening process, the biology of each child’s cancer will be identified, and families will be encouraged to enroll them in appropriate targeted therapy trials.

“Until we are able to decrease the toxicity of leukemia regimens, we won’t see a dramatic shift in late effects and thus in morbidity and mortality,” Dr. Nichols said. “The trial is an effort to test newer, less toxic regimens to begin to change that cycle.”

The 5-year survival study was funded by Children with Cancer UK, Institut National du Cancer, La Ligue Contre le Cancer, Centers for Disease Control and Prevention, Swiss Re, Swiss Cancer Research foundation, Swiss Cancer League, Rossy Family Foundation, National Cancer Institute, and the American Cancer Society. One author reports a grant from Macmillan Cancer Support, consultancy fees from Pfizer, and unsolicited small gifts from Moondance Cancer Initiative for philanthropic work. The other authors report no disclosures.

The long-term survival study was funded by the National Cancer Institute, the Archer Foundation and LyondellBasell Industries. Dr. Roth reports no disclosures; other authors report various disclosures. Dr. Nichols reports no disclosures.

Two new studies offer insights into leukemia survival rates in the United States. From 2000 to 2014, a drop in mortality among children spurred a rise in 5-year leukemia survival rates among patients aged 0-24. But adolescents and young adults who survive 5 years after diagnosis face an ongoing higher risk of death, recent research revealed, and their long-term survival is lower compared to that of the general population.

“Outcomes are improving. However, additional efforts, support, and resources are needed to further improve short- and long-term survival for acute leukemia survivors. Targeted efforts focused on populations that face greater disparities in their survival are needed to move the needle faster,” Michael Roth, MD, codirector of the Adolescent and Young Adult Oncology Program at the University of Texas M.D. Anderson Cancer Center, said in an interview.

In one study, released in The Lancet Child & Adolescent Health, an international team of researchers tracked survival outcomes from various types of leukemia in 61 nations. The study focused on the years 2000-2014 and followed patients aged 0-24.

“Age-standardized 5-year net survival in children, adolescents, and young adults for all leukemias combined during 2010-14 varied widely, ranging from 46% in Mexico to more than 85% in Canada, Cyprus, Belgium, Denmark, Finland, and Australia,” the researchers wrote. “Throughout 2000-14, survival from all leukemias combined remained consistently higher for children than adolescents and young adults, and minimal improvement was seen for adolescents and young adults in most countries.”

The U.S. data came from 41 states that cover 86% of the nation’s population, lead author Naomi Ssenyonga, a research fellow at London School of Hygiene & Tropical Medicine, said in an interview.

The 5-year survival rate for acute lymphoid leukemia (ALL) rose from 80% during 2000-2004 to 86% during 2010-2014. Survival in patients with acute myeloid leukemia (AML) was lower than for other subtypes: 66% in 2010-2014 vs. 57% in 2000-2004.

In regard to all leukemias, “we noted a steady increase in the U.S. of 6 percentage points in 5-year survival, up from 77% for patients diagnosed during 2000-2004 to 83% for those diagnosed during 2010-2014,” Ms. Ssenyonga said. “The gains were largely driven by the improvements seen among children.”

Why haven’t adolescents and young adults gained as much ground in survival?

“They often have unique clinical needs,” Ms. Ssenyonga said. “Over the past few years, adolescents and young adults with leukemia in some parts of the world, including the U.S., have increasingly been treated under pediatric protocols. This has led to higher survival. However, this approach has not been adopted consistently, and survival for adolescents and young adults with leukemia is still generally lower than survival for children.”

Gwen Nichols, MD, chief medical officer of the Leukemia & Lymphoma Society, agreed that pediatric treatment protocols hold promise as treatments for young adults. However, “because we arbitrarily set an age cutoff for being an adult, many of these patients are treated by an adult [nonpediatric] hematologist/oncologist, and some patients in the 20-39 age group do not receive the more intensive treatment regimens given to children,” she said in an interview.

In another study, published in Cancer Epidemiology, Biomarkers, & Prevention, M.D. Anderson Cancer Center’s Dr. Roth and colleagues tracked 1,938 patients with ALL and 2,350 with AML who were diagnosed at ages 15-39 from 1980 to 2009. All lived at least 5 years after diagnosis. In both groups, about 58% were White, and most of the rest were Hispanic. The median age of diagnosis for ALL was 23 (range: 15-39) and 28 years for AML (range: 15-39).

“For ALL, 10-year survival for those diagnosed in the 1980s, 1990s, and 2000s was 83%, 88%, and 88%, respectively,” the researchers reported. “Ten-year survival for AML was 82%, 90%, and 90% for those diagnosed in the 1980s, 1990s, and 2000s, respectively.”

“Early mortality within 10 years of diagnosis was mostly secondary to leukemia progressing or recurring. We believe that later mortality is secondary to the development of late side effects from their cancer treatment,” Dr. Roth said.

He noted that many adolescents and young adults with ALL or AML receive stem-cell transplants. “This treatment approach is effective. However, it is associated with short- and long-term toxicity that impacts patients’ health for many years after treatment.”

Indeed, up to 80% of acute leukemia survivors have significant health complications after therapy, said the Leukemia & Lymphoma Society’s Dr. Nichols, who wasn’t surprised by the findings. According to the society, “even when treatments are effective, more than 70% of childhood cancer survivors have a chronic health condition and 42% have a severe, disabling or life-threatening condition 30 years after diagnosis.”

“It would be interesting to understand the male predominance better,” she added, noting that the study found that male patients had worse long-term survival than females (survival time ratio: 0.61, 95% confidence interval, 0.45-0.82). “While it is tempting to suggest it is due to difference in cardiac disease, I am not aware of data to support why there is this survival difference.”

What’s next? “In ALL, we now have a number of new modalities to treat high-risk and relapsed disease such as antibodies and CAR-T,” Dr. Nichols said. “We anticipate that 5-year survival can improve utilizing these modalities due to getting more patients into remission, hopefully while reducing chemotherapeutic toxicity.”

Dr. Nichol’s also highlighted the society’s new genomic-led Pediatric Acute Leukemia (PedAL) Master Clinical Trial, which began enrolling children with acute leukemia in the United States and Canada this year, in an effort to transform medicine’s traditional high-level chemotherapy strategy to their care. The project was launched in collaboration with the National Cancer Institute, Children’s Oncology Group, and the European Pediatric Acute Leukemia Foundation.

As part of the screening process, the biology of each child’s cancer will be identified, and families will be encouraged to enroll them in appropriate targeted therapy trials.

“Until we are able to decrease the toxicity of leukemia regimens, we won’t see a dramatic shift in late effects and thus in morbidity and mortality,” Dr. Nichols said. “The trial is an effort to test newer, less toxic regimens to begin to change that cycle.”

The 5-year survival study was funded by Children with Cancer UK, Institut National du Cancer, La Ligue Contre le Cancer, Centers for Disease Control and Prevention, Swiss Re, Swiss Cancer Research foundation, Swiss Cancer League, Rossy Family Foundation, National Cancer Institute, and the American Cancer Society. One author reports a grant from Macmillan Cancer Support, consultancy fees from Pfizer, and unsolicited small gifts from Moondance Cancer Initiative for philanthropic work. The other authors report no disclosures.

The long-term survival study was funded by the National Cancer Institute, the Archer Foundation and LyondellBasell Industries. Dr. Roth reports no disclosures; other authors report various disclosures. Dr. Nichols reports no disclosures.

Some patients with blood cancers for whom all other therapeutic options have been exhausted have one final chance of getting rid of their disease: treatment with chimeric antigen-receptor (CAR) T cells.

Described as a “living drug,” the treatment involves genetically engineering the patient’s own blood cells and reinfusing them back into their system. These CAR T cells then hunt down and destroy cancer cells; in some cases, they manage to eradicate the disease completely.

About half of patients with leukemia or lymphoma and about a third of those with multiple myeloma who receive this treatment have a complete remission and achieve a functional “cure.”

But not all patients who could benefit from this therapy are able to get it. Some are spending months on waiting lists, often deteriorating while they wait. These patients have exhausted all other therapeutic options, and many are facing hospice and death.

The scope of this problem was illustrated by a recent survey of the centers that are certified to deliver this complex therapy.

The survey was led by Yi Lin, MD, PhD, associate professor of medicine at the Mayo Clinic, Rochester, Minn., and medical director for the cellular therapy program. It was published as an abstract at the annual meeting of the American Society of Clinical Oncology recently, although it was not presented there.

“We wanted to find out just how widespread this problem is,” Dr. Lin said, adding: “There had been nothing in the literature thus far about it.”

The team contacted 20 centers across the United States and received responses from 17. Results showed that the median time on the waiting list was 6 months and that only 25% of patients eventually received CAR T-cell therapy. An additional 25% were able to enter a CAR T clinical trial. The remaining 50% of patients either were enrolled in a different type of trial, entered hospice, or died.

For patient selection, all centers reported using a committee of experienced physicians to ensure consistency. They employed different ethical principles for selection. Some centers sought to maximize the total benefit, such as selecting the patients most likely to achieve leukapheresis or a clinical response, while others based their decisions on the time patients spent on waiting list or gave priority to the patients who were the “worst off” with the most limited therapeutic options.
 

Shortage affecting mostly myeloma patients

The shortages in CAR T-cell therapies primarily involve the products used for patients with multiple myeloma.

The problem has not, as yet, noticeably spilled over to lymphoma and leukemia treatments, which use a slightly different type of CAR T-cell therapy (it targets CD19, whereas the cell therapies used for myeloma target BCMA).

“We have backlog of myeloma patients who don’t have access,” said Nina Shah, MD, a hematologist and professor of medicine at the University of California, San Francisco. “We have only four slots for the two myeloma products but about 50-60 eligible patients.”

Long waiting times for CAR T cells for myeloma have been an issue ever since the first of these products appeared on the market: idecabtagene vicleucel (ide-cel; Abecma), developed by Bluebird Bio and Bristol-Myers Squibb. “As soon as it became available in March 2021, we had people waiting and limits on our access to it,” Dr. Shah said.

A second CAR T-cell therapy for myeloma, ciltacabtagene autoleucel (cilta-cel, Carvykti), developed by Janssen and Legend Biotech, received approval in February 2022. While that helped provide centers with a few more slots, it wasn’t sufficient to cut waiting times, and the demand for these myeloma therapies continues to outstrip the capacity to produce CAR-T products in a timely manner.

“For myeloma, the demand is very high, as most patients are not cured from any other existing myeloma therapies, and most patients will make it to fifth-line therapy where the two CAR T-cell products are approved right now,” said Krina K. Patel, MD, medical director of the department of lymphoma/myeloma in the division of cancer medicine at the University of Texas MD Anderson Cancer Center, Houston.

“We likely have 10 eligible CAR-T myeloma patients each month at our center,” she said, “but were getting two slots per month for the past 8 months, and now are getting four slots a month.”

“Our clinic has also experienced the impact of the low number of manufacturing slots offered to each cancer center for some CAR T-cell products,” said David Maloney, MD, PhD, medical director, Cellular Immunotherapy and Bezos Family Immunotherapy Clinic, Seattle Cancer Care Alliance.

He noted that, as with other cancer centers, for multiple myeloma they are provided a specific number of manufacturing slots for each treatment. “Our providers discuss which patients are most appropriate for available slots for that month,” said Dr. Maloney.

“Additionally, juggling patient schedules may be required to address the extended manufacturing time for some products. In some cases, clinical trials may be available in a more timely fashion for appropriate patients, and in some cases, switching to an alternative product is possible,” he commented.
 

Complex causes behind bottleneck

The cause of the current bottleneck for myeloma patients is complex. It stems from a shortage of raw materials and supply chain restraints, among other things.

While the biggest impact of shortages has been on patients with multiple myeloma, Dr. Patel pointed out that these constraints are also affecting patients with lymphoma at her institution, but to a lesser degree.

“This is multifactorial as to why, but most of the issues arise from manufacturing,” Dr. Patel said in an interview. “Initially, the FDA limited how many slots each new product could have per month, then there was a viral vector shortage, and then the quality-control process the FDA requires takes longer than the manufacturing of the cells actually do.”

On top of that, “we have about a 5% manufacturing fail rate so far,” she added. Such failures occur when the cells taken from a patient cannot be converted into CAR T cells for therapy.

Matthew J. Frigault, MD, from the Center for Cellular Therapies, Mass General Cancer Center, Boston, explained that the growing excitement about the potential for cellular therapy and recent approvals for these products for use in earlier lines of treatment have increased demand for them.

There are also problems regarding supply. Manufacture and delivery of CAR T is complicated and takes time to scale up, Dr. Frigault pointed out. “Therefore, we are seeing limited access, more so for the BCMA-directed therapies [which are used for myeloma].”

The shortages and delays likely involve two main factors. “For the newer indications, there is a significant backlog of patients who have been waiting for these therapies and have not been able to access them in the clinical trial setting, and manufacturing is extremely complicated and not easily scaled up,” he said.

“That being said, manufacturers are trying to increase the number of available manufacturing slots and decrease the time needed to manufacture cells,” Dr. Frigault commented.

Delays in access to myeloma CAR T-cell therapy are also affecting patient care at Fox Chase Cancer Center in Philadelphia. “We have had about one slot every 2 months for Abecma,” noted Henry Fung, MD, chair of the department of bone marrow transplant and cellular therapies at Fox Chase. “For Carvykti, there are only 32 certified centers in [the] U.S., and access is very limited.”

Dr. Fung explained that they have had to offer alternative treatments to many of their patients. “There are rumors that there’s shortage in obtaining raw materials, such as the virus used for transduction, although we have not encountered any problems in other CAR T products used for lymphomas.”
 

Pharma companies trying to meet the demand

This news organization reached out to the manufacturers of CAR T products. All have reported that they are doing what they feasibly can to ramp up production.

“The complexity of delivering CAR T-cell therapies is unlike any other traditional biologic or small-molecule medicine, using a patient’s own cells to start a highly sophisticated and personalized manufacturing process,” commented a spokesperson for BMS, which has two CAR T-cell products currently on the market.

“In this nascent field of cell therapy, we continue to evolve every day, addressing supply and manufacturing challenges head on by applying key learnings across our three state-of-the-art cell therapy facilities and two new facilities in progress.

“We have been encouraged by a steady increase in our manufacturing capacity, and we continue efforts to ramp up further to meet the demand for our cell therapies,” the BMS spokesperson commented. “We have already seen improvements in the stabilization of vector supply and expect additional improvements in capacity in the second half of 2022.”

Novartis said much the same thing. They have a “comprehensive, integrated global CAR-T manufacturing footprint that strengthens the flexibility, resilience, and sustainability of the Novartis manufacturing and supply chain. Together with an improved manufacturing process, we are confident in our ability to meet patient demand with timely delivery,” according to a Novartis spokesperson.

The spokesperson also pointed out that the company has continuously incorporated process improvements that have significantly increased manufacturing capacity and success rates for patients in need of CAR T cells.

“Data presented at [the] American Society of Hematology annual meeting in 2021 showed the Novartis Morris Plains facility, our flagship CAR T manufacturing site, had commercial manufacturing and shipping success rates of 96% and 99%, respectively, between January and August 2021,” according to the spokesperson.

Legend and Janssen, the companies behind Carvykti, one of the two approved cell products for myeloma, which launched earlier in 2022, said that they have continued to activate certified treatment centers in a phased approach that will enable them to expand availability throughout 2022 and beyond.

“This phased approach was designed to ensure the highest level of predictability and reliability for the patient and the certified treatment centers,” the spokesperson said. “We understand the urgency for patients in need of Carvyki and are committed to doing everything we can to accelerate our ability to deliver this important cell therapy in a reliable and timely manner.”

With regard to the industry-wide supply shortage of lentivirus, Legend and Janssen say they have put in place multiple processes to address the shortage, “including enhancing our own internal manufacturing capabilities of this essential drug substance, to ensure sufficient and sustained supply.”
 

Incredibly exciting potential

Given the immense potential of CAR T-cell therapy, the supply shortage that myeloma patients are experiencing is all the more poignant and distressing. While not everyone benefits, some patients for whom every other therapy failed and who were facing hospice have had dramatic results.

“Incredibly exciting with unbelievable potential” was how one expert described these new therapies when the first product was about to enter the marketplace. Since then, six CAR T-cell therapies have received regulatory approval for an ever-increasing range of hematologic malignancies.

But these CAR T-cell therapies have their own set of adverse events, which can be serious and even life-threatening. In addition, not all patients become cancer free, although long-term data are impressive.

A study that included one of the longest follow-ups to date was reported at the 2020 annual meeting of the American Society of Clinical Oncology. The researchers reported that remissions lasted over 9 years for patients with relapsed/refractory B-cell lymphoma or chronic lymphocytic leukemia who underwent treatment with Kite’s axicaptagene cilleucel (Yescarta). This review included 43 patients and showed an overall remission rate of 76%. Complete remission was achieved for 54% of patients, and partial remission was achieved for 22%.

The results with CAR T-cell therapy in multiple myeloma are not quite as impressive, but even so, the clinical data that supported the approval of Abecma showed that a third of patients, who had previously received a median of six prior therapies, achieved a complete response.

At the time of the Abecma approval, the lead investigator of the study, Nikhil Munshi, MD, of Dana-Farber Cancer Institute, Boston, commented: “The results of this trial represent a true turning point in the treatment of this disease. In my 30 years of treating myeloma, I have not seen any other therapy as effective in this group of patients.”

A version of this article first appeared on Medscape.com.

Some patients with blood cancers for whom all other therapeutic options have been exhausted have one final chance of getting rid of their disease: treatment with chimeric antigen-receptor (CAR) T cells.

Described as a “living drug,” the treatment involves genetically engineering the patient’s own blood cells and reinfusing them back into their system. These CAR T cells then hunt down and destroy cancer cells; in some cases, they manage to eradicate the disease completely.

About half of patients with leukemia or lymphoma and about a third of those with multiple myeloma who receive this treatment have a complete remission and achieve a functional “cure.”

But not all patients who could benefit from this therapy are able to get it. Some are spending months on waiting lists, often deteriorating while they wait. These patients have exhausted all other therapeutic options, and many are facing hospice and death.

The scope of this problem was illustrated by a recent survey of the centers that are certified to deliver this complex therapy.

The survey was led by Yi Lin, MD, PhD, associate professor of medicine at the Mayo Clinic, Rochester, Minn., and medical director for the cellular therapy program. It was published as an abstract at the annual meeting of the American Society of Clinical Oncology recently, although it was not presented there.

“We wanted to find out just how widespread this problem is,” Dr. Lin said, adding: “There had been nothing in the literature thus far about it.”

The team contacted 20 centers across the United States and received responses from 17. Results showed that the median time on the waiting list was 6 months and that only 25% of patients eventually received CAR T-cell therapy. An additional 25% were able to enter a CAR T clinical trial. The remaining 50% of patients either were enrolled in a different type of trial, entered hospice, or died.

For patient selection, all centers reported using a committee of experienced physicians to ensure consistency. They employed different ethical principles for selection. Some centers sought to maximize the total benefit, such as selecting the patients most likely to achieve leukapheresis or a clinical response, while others based their decisions on the time patients spent on waiting list or gave priority to the patients who were the “worst off” with the most limited therapeutic options.
 

Shortage affecting mostly myeloma patients

The shortages in CAR T-cell therapies primarily involve the products used for patients with multiple myeloma.

The problem has not, as yet, noticeably spilled over to lymphoma and leukemia treatments, which use a slightly different type of CAR T-cell therapy (it targets CD19, whereas the cell therapies used for myeloma target BCMA).

“We have backlog of myeloma patients who don’t have access,” said Nina Shah, MD, a hematologist and professor of medicine at the University of California, San Francisco. “We have only four slots for the two myeloma products but about 50-60 eligible patients.”

Long waiting times for CAR T cells for myeloma have been an issue ever since the first of these products appeared on the market: idecabtagene vicleucel (ide-cel; Abecma), developed by Bluebird Bio and Bristol-Myers Squibb. “As soon as it became available in March 2021, we had people waiting and limits on our access to it,” Dr. Shah said.

A second CAR T-cell therapy for myeloma, ciltacabtagene autoleucel (cilta-cel, Carvykti), developed by Janssen and Legend Biotech, received approval in February 2022. While that helped provide centers with a few more slots, it wasn’t sufficient to cut waiting times, and the demand for these myeloma therapies continues to outstrip the capacity to produce CAR-T products in a timely manner.

“For myeloma, the demand is very high, as most patients are not cured from any other existing myeloma therapies, and most patients will make it to fifth-line therapy where the two CAR T-cell products are approved right now,” said Krina K. Patel, MD, medical director of the department of lymphoma/myeloma in the division of cancer medicine at the University of Texas MD Anderson Cancer Center, Houston.

“We likely have 10 eligible CAR-T myeloma patients each month at our center,” she said, “but were getting two slots per month for the past 8 months, and now are getting four slots a month.”

“Our clinic has also experienced the impact of the low number of manufacturing slots offered to each cancer center for some CAR T-cell products,” said David Maloney, MD, PhD, medical director, Cellular Immunotherapy and Bezos Family Immunotherapy Clinic, Seattle Cancer Care Alliance.

He noted that, as with other cancer centers, for multiple myeloma they are provided a specific number of manufacturing slots for each treatment. “Our providers discuss which patients are most appropriate for available slots for that month,” said Dr. Maloney.

“Additionally, juggling patient schedules may be required to address the extended manufacturing time for some products. In some cases, clinical trials may be available in a more timely fashion for appropriate patients, and in some cases, switching to an alternative product is possible,” he commented.
 

Complex causes behind bottleneck

The cause of the current bottleneck for myeloma patients is complex. It stems from a shortage of raw materials and supply chain restraints, among other things.

While the biggest impact of shortages has been on patients with multiple myeloma, Dr. Patel pointed out that these constraints are also affecting patients with lymphoma at her institution, but to a lesser degree.

“This is multifactorial as to why, but most of the issues arise from manufacturing,” Dr. Patel said in an interview. “Initially, the FDA limited how many slots each new product could have per month, then there was a viral vector shortage, and then the quality-control process the FDA requires takes longer than the manufacturing of the cells actually do.”

On top of that, “we have about a 5% manufacturing fail rate so far,” she added. Such failures occur when the cells taken from a patient cannot be converted into CAR T cells for therapy.

Matthew J. Frigault, MD, from the Center for Cellular Therapies, Mass General Cancer Center, Boston, explained that the growing excitement about the potential for cellular therapy and recent approvals for these products for use in earlier lines of treatment have increased demand for them.

There are also problems regarding supply. Manufacture and delivery of CAR T is complicated and takes time to scale up, Dr. Frigault pointed out. “Therefore, we are seeing limited access, more so for the BCMA-directed therapies [which are used for myeloma].”

The shortages and delays likely involve two main factors. “For the newer indications, there is a significant backlog of patients who have been waiting for these therapies and have not been able to access them in the clinical trial setting, and manufacturing is extremely complicated and not easily scaled up,” he said.

“That being said, manufacturers are trying to increase the number of available manufacturing slots and decrease the time needed to manufacture cells,” Dr. Frigault commented.

Delays in access to myeloma CAR T-cell therapy are also affecting patient care at Fox Chase Cancer Center in Philadelphia. “We have had about one slot every 2 months for Abecma,” noted Henry Fung, MD, chair of the department of bone marrow transplant and cellular therapies at Fox Chase. “For Carvykti, there are only 32 certified centers in [the] U.S., and access is very limited.”

Dr. Fung explained that they have had to offer alternative treatments to many of their patients. “There are rumors that there’s shortage in obtaining raw materials, such as the virus used for transduction, although we have not encountered any problems in other CAR T products used for lymphomas.”
 

Pharma companies trying to meet the demand

This news organization reached out to the manufacturers of CAR T products. All have reported that they are doing what they feasibly can to ramp up production.

“The complexity of delivering CAR T-cell therapies is unlike any other traditional biologic or small-molecule medicine, using a patient’s own cells to start a highly sophisticated and personalized manufacturing process,” commented a spokesperson for BMS, which has two CAR T-cell products currently on the market.

“In this nascent field of cell therapy, we continue to evolve every day, addressing supply and manufacturing challenges head on by applying key learnings across our three state-of-the-art cell therapy facilities and two new facilities in progress.

“We have been encouraged by a steady increase in our manufacturing capacity, and we continue efforts to ramp up further to meet the demand for our cell therapies,” the BMS spokesperson commented. “We have already seen improvements in the stabilization of vector supply and expect additional improvements in capacity in the second half of 2022.”

Novartis said much the same thing. They have a “comprehensive, integrated global CAR-T manufacturing footprint that strengthens the flexibility, resilience, and sustainability of the Novartis manufacturing and supply chain. Together with an improved manufacturing process, we are confident in our ability to meet patient demand with timely delivery,” according to a Novartis spokesperson.

The spokesperson also pointed out that the company has continuously incorporated process improvements that have significantly increased manufacturing capacity and success rates for patients in need of CAR T cells.

“Data presented at [the] American Society of Hematology annual meeting in 2021 showed the Novartis Morris Plains facility, our flagship CAR T manufacturing site, had commercial manufacturing and shipping success rates of 96% and 99%, respectively, between January and August 2021,” according to the spokesperson.

Legend and Janssen, the companies behind Carvykti, one of the two approved cell products for myeloma, which launched earlier in 2022, said that they have continued to activate certified treatment centers in a phased approach that will enable them to expand availability throughout 2022 and beyond.

“This phased approach was designed to ensure the highest level of predictability and reliability for the patient and the certified treatment centers,” the spokesperson said. “We understand the urgency for patients in need of Carvyki and are committed to doing everything we can to accelerate our ability to deliver this important cell therapy in a reliable and timely manner.”

With regard to the industry-wide supply shortage of lentivirus, Legend and Janssen say they have put in place multiple processes to address the shortage, “including enhancing our own internal manufacturing capabilities of this essential drug substance, to ensure sufficient and sustained supply.”
 

Incredibly exciting potential

Given the immense potential of CAR T-cell therapy, the supply shortage that myeloma patients are experiencing is all the more poignant and distressing. While not everyone benefits, some patients for whom every other therapy failed and who were facing hospice have had dramatic results.

“Incredibly exciting with unbelievable potential” was how one expert described these new therapies when the first product was about to enter the marketplace. Since then, six CAR T-cell therapies have received regulatory approval for an ever-increasing range of hematologic malignancies.

But these CAR T-cell therapies have their own set of adverse events, which can be serious and even life-threatening. In addition, not all patients become cancer free, although long-term data are impressive.

A study that included one of the longest follow-ups to date was reported at the 2020 annual meeting of the American Society of Clinical Oncology. The researchers reported that remissions lasted over 9 years for patients with relapsed/refractory B-cell lymphoma or chronic lymphocytic leukemia who underwent treatment with Kite’s axicaptagene cilleucel (Yescarta). This review included 43 patients and showed an overall remission rate of 76%. Complete remission was achieved for 54% of patients, and partial remission was achieved for 22%.

The results with CAR T-cell therapy in multiple myeloma are not quite as impressive, but even so, the clinical data that supported the approval of Abecma showed that a third of patients, who had previously received a median of six prior therapies, achieved a complete response.

At the time of the Abecma approval, the lead investigator of the study, Nikhil Munshi, MD, of Dana-Farber Cancer Institute, Boston, commented: “The results of this trial represent a true turning point in the treatment of this disease. In my 30 years of treating myeloma, I have not seen any other therapy as effective in this group of patients.”

A version of this article first appeared on Medscape.com.

Some patients with blood cancers for whom all other therapeutic options have been exhausted have one final chance of getting rid of their disease: treatment with chimeric antigen-receptor (CAR) T cells.

Described as a “living drug,” the treatment involves genetically engineering the patient’s own blood cells and reinfusing them back into their system. These CAR T cells then hunt down and destroy cancer cells; in some cases, they manage to eradicate the disease completely.

About half of patients with leukemia or lymphoma and about a third of those with multiple myeloma who receive this treatment have a complete remission and achieve a functional “cure.”

But not all patients who could benefit from this therapy are able to get it. Some are spending months on waiting lists, often deteriorating while they wait. These patients have exhausted all other therapeutic options, and many are facing hospice and death.

The scope of this problem was illustrated by a recent survey of the centers that are certified to deliver this complex therapy.

The survey was led by Yi Lin, MD, PhD, associate professor of medicine at the Mayo Clinic, Rochester, Minn., and medical director for the cellular therapy program. It was published as an abstract at the annual meeting of the American Society of Clinical Oncology recently, although it was not presented there.

“We wanted to find out just how widespread this problem is,” Dr. Lin said, adding: “There had been nothing in the literature thus far about it.”

The team contacted 20 centers across the United States and received responses from 17. Results showed that the median time on the waiting list was 6 months and that only 25% of patients eventually received CAR T-cell therapy. An additional 25% were able to enter a CAR T clinical trial. The remaining 50% of patients either were enrolled in a different type of trial, entered hospice, or died.

For patient selection, all centers reported using a committee of experienced physicians to ensure consistency. They employed different ethical principles for selection. Some centers sought to maximize the total benefit, such as selecting the patients most likely to achieve leukapheresis or a clinical response, while others based their decisions on the time patients spent on waiting list or gave priority to the patients who were the “worst off” with the most limited therapeutic options.
 

Shortage affecting mostly myeloma patients

The shortages in CAR T-cell therapies primarily involve the products used for patients with multiple myeloma.

The problem has not, as yet, noticeably spilled over to lymphoma and leukemia treatments, which use a slightly different type of CAR T-cell therapy (it targets CD19, whereas the cell therapies used for myeloma target BCMA).

“We have backlog of myeloma patients who don’t have access,” said Nina Shah, MD, a hematologist and professor of medicine at the University of California, San Francisco. “We have only four slots for the two myeloma products but about 50-60 eligible patients.”

Long waiting times for CAR T cells for myeloma have been an issue ever since the first of these products appeared on the market: idecabtagene vicleucel (ide-cel; Abecma), developed by Bluebird Bio and Bristol-Myers Squibb. “As soon as it became available in March 2021, we had people waiting and limits on our access to it,” Dr. Shah said.

A second CAR T-cell therapy for myeloma, ciltacabtagene autoleucel (cilta-cel, Carvykti), developed by Janssen and Legend Biotech, received approval in February 2022. While that helped provide centers with a few more slots, it wasn’t sufficient to cut waiting times, and the demand for these myeloma therapies continues to outstrip the capacity to produce CAR-T products in a timely manner.

“For myeloma, the demand is very high, as most patients are not cured from any other existing myeloma therapies, and most patients will make it to fifth-line therapy where the two CAR T-cell products are approved right now,” said Krina K. Patel, MD, medical director of the department of lymphoma/myeloma in the division of cancer medicine at the University of Texas MD Anderson Cancer Center, Houston.

“We likely have 10 eligible CAR-T myeloma patients each month at our center,” she said, “but were getting two slots per month for the past 8 months, and now are getting four slots a month.”

“Our clinic has also experienced the impact of the low number of manufacturing slots offered to each cancer center for some CAR T-cell products,” said David Maloney, MD, PhD, medical director, Cellular Immunotherapy and Bezos Family Immunotherapy Clinic, Seattle Cancer Care Alliance.

He noted that, as with other cancer centers, for multiple myeloma they are provided a specific number of manufacturing slots for each treatment. “Our providers discuss which patients are most appropriate for available slots for that month,” said Dr. Maloney.

“Additionally, juggling patient schedules may be required to address the extended manufacturing time for some products. In some cases, clinical trials may be available in a more timely fashion for appropriate patients, and in some cases, switching to an alternative product is possible,” he commented.
 

Complex causes behind bottleneck

The cause of the current bottleneck for myeloma patients is complex. It stems from a shortage of raw materials and supply chain restraints, among other things.

While the biggest impact of shortages has been on patients with multiple myeloma, Dr. Patel pointed out that these constraints are also affecting patients with lymphoma at her institution, but to a lesser degree.

“This is multifactorial as to why, but most of the issues arise from manufacturing,” Dr. Patel said in an interview. “Initially, the FDA limited how many slots each new product could have per month, then there was a viral vector shortage, and then the quality-control process the FDA requires takes longer than the manufacturing of the cells actually do.”

On top of that, “we have about a 5% manufacturing fail rate so far,” she added. Such failures occur when the cells taken from a patient cannot be converted into CAR T cells for therapy.

Matthew J. Frigault, MD, from the Center for Cellular Therapies, Mass General Cancer Center, Boston, explained that the growing excitement about the potential for cellular therapy and recent approvals for these products for use in earlier lines of treatment have increased demand for them.

There are also problems regarding supply. Manufacture and delivery of CAR T is complicated and takes time to scale up, Dr. Frigault pointed out. “Therefore, we are seeing limited access, more so for the BCMA-directed therapies [which are used for myeloma].”

The shortages and delays likely involve two main factors. “For the newer indications, there is a significant backlog of patients who have been waiting for these therapies and have not been able to access them in the clinical trial setting, and manufacturing is extremely complicated and not easily scaled up,” he said.

“That being said, manufacturers are trying to increase the number of available manufacturing slots and decrease the time needed to manufacture cells,” Dr. Frigault commented.

Delays in access to myeloma CAR T-cell therapy are also affecting patient care at Fox Chase Cancer Center in Philadelphia. “We have had about one slot every 2 months for Abecma,” noted Henry Fung, MD, chair of the department of bone marrow transplant and cellular therapies at Fox Chase. “For Carvykti, there are only 32 certified centers in [the] U.S., and access is very limited.”

Dr. Fung explained that they have had to offer alternative treatments to many of their patients. “There are rumors that there’s shortage in obtaining raw materials, such as the virus used for transduction, although we have not encountered any problems in other CAR T products used for lymphomas.”
 

Pharma companies trying to meet the demand

This news organization reached out to the manufacturers of CAR T products. All have reported that they are doing what they feasibly can to ramp up production.

“The complexity of delivering CAR T-cell therapies is unlike any other traditional biologic or small-molecule medicine, using a patient’s own cells to start a highly sophisticated and personalized manufacturing process,” commented a spokesperson for BMS, which has two CAR T-cell products currently on the market.

“In this nascent field of cell therapy, we continue to evolve every day, addressing supply and manufacturing challenges head on by applying key learnings across our three state-of-the-art cell therapy facilities and two new facilities in progress.

“We have been encouraged by a steady increase in our manufacturing capacity, and we continue efforts to ramp up further to meet the demand for our cell therapies,” the BMS spokesperson commented. “We have already seen improvements in the stabilization of vector supply and expect additional improvements in capacity in the second half of 2022.”

Novartis said much the same thing. They have a “comprehensive, integrated global CAR-T manufacturing footprint that strengthens the flexibility, resilience, and sustainability of the Novartis manufacturing and supply chain. Together with an improved manufacturing process, we are confident in our ability to meet patient demand with timely delivery,” according to a Novartis spokesperson.

The spokesperson also pointed out that the company has continuously incorporated process improvements that have significantly increased manufacturing capacity and success rates for patients in need of CAR T cells.

“Data presented at [the] American Society of Hematology annual meeting in 2021 showed the Novartis Morris Plains facility, our flagship CAR T manufacturing site, had commercial manufacturing and shipping success rates of 96% and 99%, respectively, between January and August 2021,” according to the spokesperson.

Legend and Janssen, the companies behind Carvykti, one of the two approved cell products for myeloma, which launched earlier in 2022, said that they have continued to activate certified treatment centers in a phased approach that will enable them to expand availability throughout 2022 and beyond.

“This phased approach was designed to ensure the highest level of predictability and reliability for the patient and the certified treatment centers,” the spokesperson said. “We understand the urgency for patients in need of Carvyki and are committed to doing everything we can to accelerate our ability to deliver this important cell therapy in a reliable and timely manner.”

With regard to the industry-wide supply shortage of lentivirus, Legend and Janssen say they have put in place multiple processes to address the shortage, “including enhancing our own internal manufacturing capabilities of this essential drug substance, to ensure sufficient and sustained supply.”
 

Incredibly exciting potential

Given the immense potential of CAR T-cell therapy, the supply shortage that myeloma patients are experiencing is all the more poignant and distressing. While not everyone benefits, some patients for whom every other therapy failed and who were facing hospice have had dramatic results.

“Incredibly exciting with unbelievable potential” was how one expert described these new therapies when the first product was about to enter the marketplace. Since then, six CAR T-cell therapies have received regulatory approval for an ever-increasing range of hematologic malignancies.

But these CAR T-cell therapies have their own set of adverse events, which can be serious and even life-threatening. In addition, not all patients become cancer free, although long-term data are impressive.

A study that included one of the longest follow-ups to date was reported at the 2020 annual meeting of the American Society of Clinical Oncology. The researchers reported that remissions lasted over 9 years for patients with relapsed/refractory B-cell lymphoma or chronic lymphocytic leukemia who underwent treatment with Kite’s axicaptagene cilleucel (Yescarta). This review included 43 patients and showed an overall remission rate of 76%. Complete remission was achieved for 54% of patients, and partial remission was achieved for 22%.

The results with CAR T-cell therapy in multiple myeloma are not quite as impressive, but even so, the clinical data that supported the approval of Abecma showed that a third of patients, who had previously received a median of six prior therapies, achieved a complete response.

At the time of the Abecma approval, the lead investigator of the study, Nikhil Munshi, MD, of Dana-Farber Cancer Institute, Boston, commented: “The results of this trial represent a true turning point in the treatment of this disease. In my 30 years of treating myeloma, I have not seen any other therapy as effective in this group of patients.”

A version of this article first appeared on Medscape.com.

Ten years ago, Stephan Grupp, MD, PhD, plunged into an unexplored area of pediatric cancer treatment with a 6-year-old patient for whom every treatment available for her acute lymphoblastic leukemia (ALL) had been exhausted.

Dr. Grupp, a pioneer in cellular immunotherapy at Children’s Hospital of Philadelphia, had just got the green light to launch the first phase 1 trial of chimeric antigen receptor (CAR) T-cell therapy for children.

“The trial opened at the absolute last possible moment that it could have been helpful to her,” he said in an interview. “There was nothing else to do to temporize her further. ... It had to open then or never.”

The patient was Emily Whitehead, who has since become a poster girl for the dramatic results that can be achieved with these novel therapies. After that one CAR T-cell treatment back in 2012, she has been free of her leukemia and has remained in remission for more than 10 years.

Dr. Grupp said that he is, at last, starting to use the “cure” word.

“I’m not just a doctor, I’m a scientist – and one case isn’t enough to have confidence about anything,” he said. “We wanted more patients to be out longer to be able to say that thing which we have for a long time called the ‘c word.’

“CAR T-cell therapy has now been given to hundreds of patients at CHOP, and – we are unique in this – we have a couple dozen patients who are 5, 6, 7, 9 years out or more without further therapy. That feels like a cure to me,” he commented.
 

First patient with ALL

Emily was the first patient with ALL to receive the novel treatment, and also the first child.

There was a precedent, however. After having been “stuck” for decades, the CAR T-cell field had recently made a breakthrough, thanks to research by Dr. Grupp’s colleague Carl June, MD, and associates at the University of Pennsylvania, Philadelphia. By tweaking two key steps in the genetic modification of T cells, Dr. June’s team had successfully treated three adults with chronic lymphocytic leukemia (CLL), two of whom were in complete remission.

But using the treatment for a child and for a different type of leukemia was a daunting prospect. Dr. Grupp said that he was candid with Emily’s parents, Tom and Kari Whitehead, emphasizing that there are no guarantees in cancer treatment, particularly in a phase 1 trial.

But the Whiteheads had no time to waste and nowhere else to turn. Her father, Tom, recalled saying: “This is something outside the box, this is going to give her a chance.”

Dr. Grupp, who described himself as being “on the cowboy end” of oncology care, was ready to take the plunge.

Little did any of them know that the treatment would make Emily even sicker than she already was, putting her in intensive care. But thanks to a combination of several lucky breaks and a lot of brain power, she would make a breathtakingly rapid recovery.
 

The ‘magic formula’

CAR T-cell therapy involves harvesting a patient’s T cells and modifying them in the lab with a chimeric antigen receptor to target CD19, a protein found on the surface of ALL cancer cells.

Before the University of Pennsylvania team tweaked the process, clinical trials of the therapy yielded only modest results because the modified T cells “were very powerful in the short term but had almost no proliferative capacity” once they were infused back into the patient, Dr. Grupp explained.

“It does not matter how many cells you give to a patient, what matters is that the cells grow in the patient to the level needed to control the leukemia,” he said.

Dr. June’s team came up with what Dr. Grupp calls “the magic formula”: A bead-based manufacturing process that produced younger T-cell phenotypes with “enormous” proliferative capacity, and a lentiviral approach to the genetic modification, enabling prolonged expression of the CAR-T molecule.

“Was it rogue? Absolutely, positively not,” said Dr. Grupp, thinking back to the day he enrolled Emily in the trial. “Was it risky? Obviously ... we all dived into this pool without knowing what was under the water, so I would say, rogue, no, risky, yes. And I would say we didn’t know nearly enough about the risks.”
 

Cytokine storm

The gravest risk that Dr. Grupp and his team encountered was something they had not anticipated. At the time, they had no name for it.

The three adults with CLL who had received CAR T-cell therapy had experienced a mild version that the researchers referred to as “tumor lysis syndrome”.

But for Emily, on day 3 of her CAR T-cell infusion, there was a ferocious reaction storm that later came to be called cytokine release syndrome.

“The wheels just came off then,” said Mr. Whitehead. “I remember her blood pressure was 53 over 29. They took her to the ICU, induced a coma, and put her on a ventilator. It was brutal to watch. The oscillatory ventilator just pounds on you, and there was blood bubbling out around the hose in her mouth.

“I remember the third or fourth night, a doctor took me in the hallway and said, ‘There’s a one-in-a-thousand chance your daughter is alive when the sun comes up,’” Mr. Whitehead said in an interview. “And I said: ‘All right, I’ll see you at rounds tomorrow, because she’ll still be here.’ ”

“We had some vague notion of toxicity ... but it turned out not nearly enough,” said Dr. Grupp. The ICU “worked flat out” to save her life. “They had deployed everything they had to keep a human being alive and they had nothing more to add. At some point, you run out of things that you can do, and we had run out.”
 

On the fly

It was then that the team ran into some good luck. The first break was when they decided to look at her cytokines. “Our whole knowledge base came together in the moment, on the fly, at the exact moment when Emily was so very sick,” he recalled. “Could we get the result fast enough? The lab dropped everything to run the test.”

They ordered a broad cytokine panel that included 30 analytes. The results showed that a number of cytokines “were just unbelievably elevated,” he said. Among them was interleukin-6.

“IL-6 isn’t even made by T cells, so nobody in the world would have guessed that this would have mattered. If we’d ordered a smaller panel, it might not even have been on it. Yet this was the one cytokine we had a drug for – tocilizumab – so that was chance. And then, another chance was that the drug was at the hospital, because there are rheumatology patients who get it.

“So, we went from making the determination that IL-6 was high and figuring out there was a drug for it at 3:00 o’clock to giving the drug to her at 8:00 o’clock, and then her clinical situation turned around so quickly – I mean hours later.”

Emily woke up from a 14-day medically induced coma on her seventh birthday.

Eight days later, her bone marrow showed complete remission. “The doctors said, ‘We’ve never seen anyone this sick get better any faster,’ ” Mr. Whitehead said.

She had already been through a battery of treatments for her leukemia. “It was 22 months of failed, standard treatment, and then just 23 days after they gave her the first dose of CAR T-cells that she was cancer free,” he added.
 

Talking about ‘cure’

Now that Emily, 17, has remained in remission for 10 years, Dr. Grupp is finally willing to use the word “cure” – but it has taken him a long time.

Now, he says, the challenge from the bedside is to keep parents’ and patients’ expectations realistic about what they see as a miracle cure.

“It’s not a miracle. We can get patients into remission 90-plus percent of the time – but some patients do relapse – and then there are the risks [of the cytokine storm, which can be life-threatening].

“Right now, our experience is that about 12% of patients end up in the ICU, but they hardly ever end up as sick as Emily ... because now we’re giving the tocilizumab much earlier,” Dr. Grupp said.
 

Hearing whispers

Since their daughter’s recovery, Tom and Kari Whitehead have dedicated much of their time to spreading the word about the treatment that saved Emily’s life. Mr. Whitehead testified at the Food and Drug Administration’s advisory committee meeting in 2017 when approval was being considered for the CAR T-cell product that Emily received. The product was tisagenlecleucel-T (Novartis); at that meeting, there was a unanimous vote to recommend approval. This was the first CAR T cell to reach the market.

As cofounders of the Emily Whitehead Foundation, Emily’s parents have helped raise more than $2 million to support research in the field, and they travel around the world telling their story to “move this revolution forward.”

Despite their fierce belief in the science that saved Emily, they also acknowledge there was luck – and faith. Early in their journey, when Emily experienced relapse after her initial treatments, Mr. Whitehead drew comfort from two visions, which he calls “whispers,” that guided them through several forks in the road and through tough decisions about Emily’s treatment.

Several times the parents refused treatment that was offered to Emily, and once they had her discharged against medical advice. “I told Kari she’s definitely going to beat her cancer – I saw it. I don’t know how it’s going to happen, but we’re going to be in the bone marrow transplant hallway [at CHOP] teaching her to walk again. I know a lot of doctors don’t want to hear anything about ‘a sign,’ or what guided us, but I don’t think you have to separate faith and science, I think it takes everything to make something like this to happen.”
 

Enduring effect

The key to the CAR T-cell breakthrough that gave rise to Emily’s therapy was cell proliferation, and the effect is enduring, beyond all expectations, said Dr. Grupp. The modified T cells are still detectable in Emily and other patients in long-term remission.

“The fundamental question is, are the cells still working, or are the patients cured and they don’t need them?” said Dr. Grupp. “I think it’s the latter. The data that we have from several large datasets that we developed with Novartis are that, if you get to a year and your minimal residual disease testing both by flow and by next-generation sequencing is negative and you still have B-cell aplasia, the relapse risk is close to zero at that point.”

While it’s still not clear if and when that risk will ever get to zero, Emily and Dr. Grupp have successfully closed the chapter.

“Oncologists have different notions of what the word ‘cure’ means. If your attitude is you’re not cured until you’ve basically reached the end of your life and you haven’t relapsed, well, that’s an impossible bar to hit. My attitude is, if your likelihood of having a disease recurrence is lower than the other risks in your life, like getting into your car and driving to your appointment, then that’s what a functional cure looks like,” he said.

“I’m probably the doctor that still sees her the most, but honestly, the whole conversation is not about leukemia at all. She has B-cell aplasia, so we have to treat that, and then it’s about making sure there’s no long-term side effects from the totality of her treatment. Generally, for a patient who’s gotten a moderate amount of chemotherapy and CAR T, that should not interfere with fertility. Has any patient in the history of the world ever relapsed more than 5 years out from their therapy? Of course. Is that incredibly rare? Yes, it is. You can be paralyzed by that, or you can compartmentalize it.”

As for the Whiteheads, they are focused on Emily’s college applications, her new driver’s license, and her project to cowrite a film about her story with a Hollywood filmmaker.

Mr. Whitehead said the one thing he hopes clinicians take away from their story is that sometimes a parent’s instinct transcends science.

A version of this article first appeared on Medscape.com.

Ten years ago, Stephan Grupp, MD, PhD, plunged into an unexplored area of pediatric cancer treatment with a 6-year-old patient for whom every treatment available for her acute lymphoblastic leukemia (ALL) had been exhausted.

Dr. Grupp, a pioneer in cellular immunotherapy at Children’s Hospital of Philadelphia, had just got the green light to launch the first phase 1 trial of chimeric antigen receptor (CAR) T-cell therapy for children.

“The trial opened at the absolute last possible moment that it could have been helpful to her,” he said in an interview. “There was nothing else to do to temporize her further. ... It had to open then or never.”

The patient was Emily Whitehead, who has since become a poster girl for the dramatic results that can be achieved with these novel therapies. After that one CAR T-cell treatment back in 2012, she has been free of her leukemia and has remained in remission for more than 10 years.

Dr. Grupp said that he is, at last, starting to use the “cure” word.

“I’m not just a doctor, I’m a scientist – and one case isn’t enough to have confidence about anything,” he said. “We wanted more patients to be out longer to be able to say that thing which we have for a long time called the ‘c word.’

“CAR T-cell therapy has now been given to hundreds of patients at CHOP, and – we are unique in this – we have a couple dozen patients who are 5, 6, 7, 9 years out or more without further therapy. That feels like a cure to me,” he commented.
 

First patient with ALL

Emily was the first patient with ALL to receive the novel treatment, and also the first child.

There was a precedent, however. After having been “stuck” for decades, the CAR T-cell field had recently made a breakthrough, thanks to research by Dr. Grupp’s colleague Carl June, MD, and associates at the University of Pennsylvania, Philadelphia. By tweaking two key steps in the genetic modification of T cells, Dr. June’s team had successfully treated three adults with chronic lymphocytic leukemia (CLL), two of whom were in complete remission.

But using the treatment for a child and for a different type of leukemia was a daunting prospect. Dr. Grupp said that he was candid with Emily’s parents, Tom and Kari Whitehead, emphasizing that there are no guarantees in cancer treatment, particularly in a phase 1 trial.

But the Whiteheads had no time to waste and nowhere else to turn. Her father, Tom, recalled saying: “This is something outside the box, this is going to give her a chance.”

Dr. Grupp, who described himself as being “on the cowboy end” of oncology care, was ready to take the plunge.

Little did any of them know that the treatment would make Emily even sicker than she already was, putting her in intensive care. But thanks to a combination of several lucky breaks and a lot of brain power, she would make a breathtakingly rapid recovery.
 

The ‘magic formula’

CAR T-cell therapy involves harvesting a patient’s T cells and modifying them in the lab with a chimeric antigen receptor to target CD19, a protein found on the surface of ALL cancer cells.

Before the University of Pennsylvania team tweaked the process, clinical trials of the therapy yielded only modest results because the modified T cells “were very powerful in the short term but had almost no proliferative capacity” once they were infused back into the patient, Dr. Grupp explained.

“It does not matter how many cells you give to a patient, what matters is that the cells grow in the patient to the level needed to control the leukemia,” he said.

Dr. June’s team came up with what Dr. Grupp calls “the magic formula”: A bead-based manufacturing process that produced younger T-cell phenotypes with “enormous” proliferative capacity, and a lentiviral approach to the genetic modification, enabling prolonged expression of the CAR-T molecule.

“Was it rogue? Absolutely, positively not,” said Dr. Grupp, thinking back to the day he enrolled Emily in the trial. “Was it risky? Obviously ... we all dived into this pool without knowing what was under the water, so I would say, rogue, no, risky, yes. And I would say we didn’t know nearly enough about the risks.”
 

Cytokine storm

The gravest risk that Dr. Grupp and his team encountered was something they had not anticipated. At the time, they had no name for it.

The three adults with CLL who had received CAR T-cell therapy had experienced a mild version that the researchers referred to as “tumor lysis syndrome”.

But for Emily, on day 3 of her CAR T-cell infusion, there was a ferocious reaction storm that later came to be called cytokine release syndrome.

“The wheels just came off then,” said Mr. Whitehead. “I remember her blood pressure was 53 over 29. They took her to the ICU, induced a coma, and put her on a ventilator. It was brutal to watch. The oscillatory ventilator just pounds on you, and there was blood bubbling out around the hose in her mouth.

“I remember the third or fourth night, a doctor took me in the hallway and said, ‘There’s a one-in-a-thousand chance your daughter is alive when the sun comes up,’” Mr. Whitehead said in an interview. “And I said: ‘All right, I’ll see you at rounds tomorrow, because she’ll still be here.’ ”

“We had some vague notion of toxicity ... but it turned out not nearly enough,” said Dr. Grupp. The ICU “worked flat out” to save her life. “They had deployed everything they had to keep a human being alive and they had nothing more to add. At some point, you run out of things that you can do, and we had run out.”
 

On the fly

It was then that the team ran into some good luck. The first break was when they decided to look at her cytokines. “Our whole knowledge base came together in the moment, on the fly, at the exact moment when Emily was so very sick,” he recalled. “Could we get the result fast enough? The lab dropped everything to run the test.”

They ordered a broad cytokine panel that included 30 analytes. The results showed that a number of cytokines “were just unbelievably elevated,” he said. Among them was interleukin-6.

“IL-6 isn’t even made by T cells, so nobody in the world would have guessed that this would have mattered. If we’d ordered a smaller panel, it might not even have been on it. Yet this was the one cytokine we had a drug for – tocilizumab – so that was chance. And then, another chance was that the drug was at the hospital, because there are rheumatology patients who get it.

“So, we went from making the determination that IL-6 was high and figuring out there was a drug for it at 3:00 o’clock to giving the drug to her at 8:00 o’clock, and then her clinical situation turned around so quickly – I mean hours later.”

Emily woke up from a 14-day medically induced coma on her seventh birthday.

Eight days later, her bone marrow showed complete remission. “The doctors said, ‘We’ve never seen anyone this sick get better any faster,’ ” Mr. Whitehead said.

She had already been through a battery of treatments for her leukemia. “It was 22 months of failed, standard treatment, and then just 23 days after they gave her the first dose of CAR T-cells that she was cancer free,” he added.
 

Talking about ‘cure’

Now that Emily, 17, has remained in remission for 10 years, Dr. Grupp is finally willing to use the word “cure” – but it has taken him a long time.

Now, he says, the challenge from the bedside is to keep parents’ and patients’ expectations realistic about what they see as a miracle cure.

“It’s not a miracle. We can get patients into remission 90-plus percent of the time – but some patients do relapse – and then there are the risks [of the cytokine storm, which can be life-threatening].

“Right now, our experience is that about 12% of patients end up in the ICU, but they hardly ever end up as sick as Emily ... because now we’re giving the tocilizumab much earlier,” Dr. Grupp said.
 

Hearing whispers

Since their daughter’s recovery, Tom and Kari Whitehead have dedicated much of their time to spreading the word about the treatment that saved Emily’s life. Mr. Whitehead testified at the Food and Drug Administration’s advisory committee meeting in 2017 when approval was being considered for the CAR T-cell product that Emily received. The product was tisagenlecleucel-T (Novartis); at that meeting, there was a unanimous vote to recommend approval. This was the first CAR T cell to reach the market.

As cofounders of the Emily Whitehead Foundation, Emily’s parents have helped raise more than $2 million to support research in the field, and they travel around the world telling their story to “move this revolution forward.”

Despite their fierce belief in the science that saved Emily, they also acknowledge there was luck – and faith. Early in their journey, when Emily experienced relapse after her initial treatments, Mr. Whitehead drew comfort from two visions, which he calls “whispers,” that guided them through several forks in the road and through tough decisions about Emily’s treatment.

Several times the parents refused treatment that was offered to Emily, and once they had her discharged against medical advice. “I told Kari she’s definitely going to beat her cancer – I saw it. I don’t know how it’s going to happen, but we’re going to be in the bone marrow transplant hallway [at CHOP] teaching her to walk again. I know a lot of doctors don’t want to hear anything about ‘a sign,’ or what guided us, but I don’t think you have to separate faith and science, I think it takes everything to make something like this to happen.”
 

Enduring effect

The key to the CAR T-cell breakthrough that gave rise to Emily’s therapy was cell proliferation, and the effect is enduring, beyond all expectations, said Dr. Grupp. The modified T cells are still detectable in Emily and other patients in long-term remission.

“The fundamental question is, are the cells still working, or are the patients cured and they don’t need them?” said Dr. Grupp. “I think it’s the latter. The data that we have from several large datasets that we developed with Novartis are that, if you get to a year and your minimal residual disease testing both by flow and by next-generation sequencing is negative and you still have B-cell aplasia, the relapse risk is close to zero at that point.”

While it’s still not clear if and when that risk will ever get to zero, Emily and Dr. Grupp have successfully closed the chapter.

“Oncologists have different notions of what the word ‘cure’ means. If your attitude is you’re not cured until you’ve basically reached the end of your life and you haven’t relapsed, well, that’s an impossible bar to hit. My attitude is, if your likelihood of having a disease recurrence is lower than the other risks in your life, like getting into your car and driving to your appointment, then that’s what a functional cure looks like,” he said.

“I’m probably the doctor that still sees her the most, but honestly, the whole conversation is not about leukemia at all. She has B-cell aplasia, so we have to treat that, and then it’s about making sure there’s no long-term side effects from the totality of her treatment. Generally, for a patient who’s gotten a moderate amount of chemotherapy and CAR T, that should not interfere with fertility. Has any patient in the history of the world ever relapsed more than 5 years out from their therapy? Of course. Is that incredibly rare? Yes, it is. You can be paralyzed by that, or you can compartmentalize it.”

As for the Whiteheads, they are focused on Emily’s college applications, her new driver’s license, and her project to cowrite a film about her story with a Hollywood filmmaker.

Mr. Whitehead said the one thing he hopes clinicians take away from their story is that sometimes a parent’s instinct transcends science.

A version of this article first appeared on Medscape.com.

Ten years ago, Stephan Grupp, MD, PhD, plunged into an unexplored area of pediatric cancer treatment with a 6-year-old patient for whom every treatment available for her acute lymphoblastic leukemia (ALL) had been exhausted.

Dr. Grupp, a pioneer in cellular immunotherapy at Children’s Hospital of Philadelphia, had just got the green light to launch the first phase 1 trial of chimeric antigen receptor (CAR) T-cell therapy for children.

“The trial opened at the absolute last possible moment that it could have been helpful to her,” he said in an interview. “There was nothing else to do to temporize her further. ... It had to open then or never.”

The patient was Emily Whitehead, who has since become a poster girl for the dramatic results that can be achieved with these novel therapies. After that one CAR T-cell treatment back in 2012, she has been free of her leukemia and has remained in remission for more than 10 years.

Dr. Grupp said that he is, at last, starting to use the “cure” word.

“I’m not just a doctor, I’m a scientist – and one case isn’t enough to have confidence about anything,” he said. “We wanted more patients to be out longer to be able to say that thing which we have for a long time called the ‘c word.’

“CAR T-cell therapy has now been given to hundreds of patients at CHOP, and – we are unique in this – we have a couple dozen patients who are 5, 6, 7, 9 years out or more without further therapy. That feels like a cure to me,” he commented.
 

First patient with ALL

Emily was the first patient with ALL to receive the novel treatment, and also the first child.

There was a precedent, however. After having been “stuck” for decades, the CAR T-cell field had recently made a breakthrough, thanks to research by Dr. Grupp’s colleague Carl June, MD, and associates at the University of Pennsylvania, Philadelphia. By tweaking two key steps in the genetic modification of T cells, Dr. June’s team had successfully treated three adults with chronic lymphocytic leukemia (CLL), two of whom were in complete remission.

But using the treatment for a child and for a different type of leukemia was a daunting prospect. Dr. Grupp said that he was candid with Emily’s parents, Tom and Kari Whitehead, emphasizing that there are no guarantees in cancer treatment, particularly in a phase 1 trial.

But the Whiteheads had no time to waste and nowhere else to turn. Her father, Tom, recalled saying: “This is something outside the box, this is going to give her a chance.”

Dr. Grupp, who described himself as being “on the cowboy end” of oncology care, was ready to take the plunge.

Little did any of them know that the treatment would make Emily even sicker than she already was, putting her in intensive care. But thanks to a combination of several lucky breaks and a lot of brain power, she would make a breathtakingly rapid recovery.
 

The ‘magic formula’

CAR T-cell therapy involves harvesting a patient’s T cells and modifying them in the lab with a chimeric antigen receptor to target CD19, a protein found on the surface of ALL cancer cells.

Before the University of Pennsylvania team tweaked the process, clinical trials of the therapy yielded only modest results because the modified T cells “were very powerful in the short term but had almost no proliferative capacity” once they were infused back into the patient, Dr. Grupp explained.

“It does not matter how many cells you give to a patient, what matters is that the cells grow in the patient to the level needed to control the leukemia,” he said.

Dr. June’s team came up with what Dr. Grupp calls “the magic formula”: A bead-based manufacturing process that produced younger T-cell phenotypes with “enormous” proliferative capacity, and a lentiviral approach to the genetic modification, enabling prolonged expression of the CAR-T molecule.

“Was it rogue? Absolutely, positively not,” said Dr. Grupp, thinking back to the day he enrolled Emily in the trial. “Was it risky? Obviously ... we all dived into this pool without knowing what was under the water, so I would say, rogue, no, risky, yes. And I would say we didn’t know nearly enough about the risks.”
 

Cytokine storm

The gravest risk that Dr. Grupp and his team encountered was something they had not anticipated. At the time, they had no name for it.

The three adults with CLL who had received CAR T-cell therapy had experienced a mild version that the researchers referred to as “tumor lysis syndrome”.

But for Emily, on day 3 of her CAR T-cell infusion, there was a ferocious reaction storm that later came to be called cytokine release syndrome.

“The wheels just came off then,” said Mr. Whitehead. “I remember her blood pressure was 53 over 29. They took her to the ICU, induced a coma, and put her on a ventilator. It was brutal to watch. The oscillatory ventilator just pounds on you, and there was blood bubbling out around the hose in her mouth.

“I remember the third or fourth night, a doctor took me in the hallway and said, ‘There’s a one-in-a-thousand chance your daughter is alive when the sun comes up,’” Mr. Whitehead said in an interview. “And I said: ‘All right, I’ll see you at rounds tomorrow, because she’ll still be here.’ ”

“We had some vague notion of toxicity ... but it turned out not nearly enough,” said Dr. Grupp. The ICU “worked flat out” to save her life. “They had deployed everything they had to keep a human being alive and they had nothing more to add. At some point, you run out of things that you can do, and we had run out.”
 

On the fly

It was then that the team ran into some good luck. The first break was when they decided to look at her cytokines. “Our whole knowledge base came together in the moment, on the fly, at the exact moment when Emily was so very sick,” he recalled. “Could we get the result fast enough? The lab dropped everything to run the test.”

They ordered a broad cytokine panel that included 30 analytes. The results showed that a number of cytokines “were just unbelievably elevated,” he said. Among them was interleukin-6.

“IL-6 isn’t even made by T cells, so nobody in the world would have guessed that this would have mattered. If we’d ordered a smaller panel, it might not even have been on it. Yet this was the one cytokine we had a drug for – tocilizumab – so that was chance. And then, another chance was that the drug was at the hospital, because there are rheumatology patients who get it.

“So, we went from making the determination that IL-6 was high and figuring out there was a drug for it at 3:00 o’clock to giving the drug to her at 8:00 o’clock, and then her clinical situation turned around so quickly – I mean hours later.”

Emily woke up from a 14-day medically induced coma on her seventh birthday.

Eight days later, her bone marrow showed complete remission. “The doctors said, ‘We’ve never seen anyone this sick get better any faster,’ ” Mr. Whitehead said.

She had already been through a battery of treatments for her leukemia. “It was 22 months of failed, standard treatment, and then just 23 days after they gave her the first dose of CAR T-cells that she was cancer free,” he added.
 

Talking about ‘cure’

Now that Emily, 17, has remained in remission for 10 years, Dr. Grupp is finally willing to use the word “cure” – but it has taken him a long time.

Now, he says, the challenge from the bedside is to keep parents’ and patients’ expectations realistic about what they see as a miracle cure.

“It’s not a miracle. We can get patients into remission 90-plus percent of the time – but some patients do relapse – and then there are the risks [of the cytokine storm, which can be life-threatening].

“Right now, our experience is that about 12% of patients end up in the ICU, but they hardly ever end up as sick as Emily ... because now we’re giving the tocilizumab much earlier,” Dr. Grupp said.
 

Hearing whispers

Since their daughter’s recovery, Tom and Kari Whitehead have dedicated much of their time to spreading the word about the treatment that saved Emily’s life. Mr. Whitehead testified at the Food and Drug Administration’s advisory committee meeting in 2017 when approval was being considered for the CAR T-cell product that Emily received. The product was tisagenlecleucel-T (Novartis); at that meeting, there was a unanimous vote to recommend approval. This was the first CAR T cell to reach the market.

As cofounders of the Emily Whitehead Foundation, Emily’s parents have helped raise more than $2 million to support research in the field, and they travel around the world telling their story to “move this revolution forward.”

Despite their fierce belief in the science that saved Emily, they also acknowledge there was luck – and faith. Early in their journey, when Emily experienced relapse after her initial treatments, Mr. Whitehead drew comfort from two visions, which he calls “whispers,” that guided them through several forks in the road and through tough decisions about Emily’s treatment.

Several times the parents refused treatment that was offered to Emily, and once they had her discharged against medical advice. “I told Kari she’s definitely going to beat her cancer – I saw it. I don’t know how it’s going to happen, but we’re going to be in the bone marrow transplant hallway [at CHOP] teaching her to walk again. I know a lot of doctors don’t want to hear anything about ‘a sign,’ or what guided us, but I don’t think you have to separate faith and science, I think it takes everything to make something like this to happen.”
 

Enduring effect

The key to the CAR T-cell breakthrough that gave rise to Emily’s therapy was cell proliferation, and the effect is enduring, beyond all expectations, said Dr. Grupp. The modified T cells are still detectable in Emily and other patients in long-term remission.

“The fundamental question is, are the cells still working, or are the patients cured and they don’t need them?” said Dr. Grupp. “I think it’s the latter. The data that we have from several large datasets that we developed with Novartis are that, if you get to a year and your minimal residual disease testing both by flow and by next-generation sequencing is negative and you still have B-cell aplasia, the relapse risk is close to zero at that point.”

While it’s still not clear if and when that risk will ever get to zero, Emily and Dr. Grupp have successfully closed the chapter.

“Oncologists have different notions of what the word ‘cure’ means. If your attitude is you’re not cured until you’ve basically reached the end of your life and you haven’t relapsed, well, that’s an impossible bar to hit. My attitude is, if your likelihood of having a disease recurrence is lower than the other risks in your life, like getting into your car and driving to your appointment, then that’s what a functional cure looks like,” he said.

“I’m probably the doctor that still sees her the most, but honestly, the whole conversation is not about leukemia at all. She has B-cell aplasia, so we have to treat that, and then it’s about making sure there’s no long-term side effects from the totality of her treatment. Generally, for a patient who’s gotten a moderate amount of chemotherapy and CAR T, that should not interfere with fertility. Has any patient in the history of the world ever relapsed more than 5 years out from their therapy? Of course. Is that incredibly rare? Yes, it is. You can be paralyzed by that, or you can compartmentalize it.”

As for the Whiteheads, they are focused on Emily’s college applications, her new driver’s license, and her project to cowrite a film about her story with a Hollywood filmmaker.

Mr. Whitehead said the one thing he hopes clinicians take away from their story is that sometimes a parent’s instinct transcends science.

A version of this article first appeared on Medscape.com.