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ORLANDO – Uveal melanoma has little in common with it’s cutaneous namesake, and its distinct characteristics necessitated the development of specific guidelines for diagnosis and management, which were released earlier this year by the National Comprehensive Cancer Network (NCCN).
Unlike cutaneous melanoma, uveal melanoma is usually treated with radiotherapy rather than surgery, and primary treatment is based on tumor size, according to Christopher A. Barker, MD, a radiation oncologist and director of clinical investigations in the department of radiation at Memorial Sloan Kettering Cancer Center, New York.
Further, molecular testing aids in prognosis in uveal melanoma but not in predicting treatment response as it can in cutaneous disease, and recurrences of uveal melanoma are typically distant – usually occurring in the liver – rather than in the skin or lymph nodes as with cutaneous melanoma.
These and other diagnosis- and treatment-related issues are outlined in the new guidelines, which are the first developed by the NCCN for uveal melanoma.
Guidelines exist in several countries, including Australia, the United Kingdom, Canada, and the United States (published by The American Brachytherapy Society), but until now none have provided pathway-based strategies for the management of all stages of this rare disease that affects about 1 in 200,000 Americans, typically Caucasians in their 50s, 60s, or 70s, Dr. Barker, a member of the NCCN Melanoma guidelines panel and the uveal melanoma subcommittee, said at the NCCN’s annual meeting where he presented the guidelines.
The median age of diagnosis is 60 years, he noted.
The NCCN guidelines specifically address melanoma arising in the choroid and ciliary body of the uvea. The choroid is the predominant site of uveal melanoma origin, and tumors arising there may involve the ciliary body as well, although the latter is a rare site of melanoma origin. The iris is also a rare site of origin, and tumors arising there are typically indolent in nature and thus are not part of the new guidelines, he explained.
Risk factors include choroidal nevi, ocular melanocytosis, and familial uveal melanoma associated with germline BAP1 mutation, neurofibromatosis, or dysplastic nevus syndrome; cutaneous melanoma is not a risk factor, he said.
The guidelines address clinical presentation, diagnostic work-up, and staging; primary treatments; and metastatic risks and follow-up imaging.
Presentation, diagnosis, and staging
About two-thirds of patients with uveal melanoma present because of changes in their vision, and about a third present with no new symptoms and are diagnosed during routine evaluation, Dr. Barker said.
“History and physical exam, and specifically attention to any prior malignancies, is important,” he said. “A comprehensive eye examination is absolutely vital to the evaluation and staging of patients with uveal melanoma.”
Numerous additional testing options, including autofluorescence of the ocular fundus, retinal fluorescein angiography of the ocular fundus, and transillumination, among others, are listed in the guidelines, which note that MRI is sometimes needed to confirm diagnosis.
Biopsies, however, are generally only performed to confirm diagnosis if needed or for prognostic analysis for risk stratification.
Staging is determined mainly by tumor size, which is known to be associated with outcomes in patients with uveal melanoma, and is based on criteria from both the Collaborative Ocular Melanoma Study (COMS) staging system and the American Joint Committee on Cancer (AJCC) staging manual, Dr. Barker said.
The COMS system was developed based on separate studies of small, medium, and large tumors and helped define primary tumor management and establish existing standards of care. The AJCC system was developed subsequently and focuses more on tumor features that may improve clinical predictions.
Primary treatments
Options for primary treatment for small tumors (largest diameter 5-16 mm and thickness less than 2.5 mm) include plaque brachytherapy, partical beam radiation, and laser ablation in highly select patients. For medium tumors (18mm or less at largest diameter and thickness of 2.5-10 mm), they include plaque brachytherapy, particle beam radiation, and enucleation, according to the guidelines.
Large tumors can be treated with radiotherapy (preferably particle beam radiation, Dr. Barker said) or enucleation. Large tumors are those greater than 18mm with any thickness, those with thickness greater than 10mm with any diameter, and those with thickness greater than 8mm with optic nerve involvement.
In patients for whom surgical removal is selected, “ there are a few unusual situations where additional local adjuvant therapy might be considered,” Dr. Barker said, explaining, for example, that the presence of microscopically positive or close margins after enucleation without evidence of gross residual disease in the orbit may be observed or may warrant map biopsy and/or particle beam or photon beam radiotherapy to the orbit.
For visible extraocular tumors or suspicion of gross disease in the orbit, biopsy of the extraocular tissue is recommended when possible, along with either intraoperative cryotherapy, orbital exenteration, or particle beam or photon beam radiotherapy to the orbit, he added.
Metastatic risks and follow-up imaging
Recent studies, including Cancer Genome Atlas Research Network studies, have elucidated the genomics of both uveal and cutaneous melanomas, and they show “a completely different mutation spectrum” for uveal melanoma, Dr. Barker said.
These genomic studies demonstrate that cutaneous melanoma involves mutations that predict response to certain treatments, while those found in uveal melanoma do not, but they are, however, associated with the probability of metastasis, he said.
For example, various studies have shown that BRAF mutation in cutaneous melanoma predicts response to RAF or MEK inhibition and that the overall number of mutations in cutaneous melanoma may predict response to immunotherapy.
In uveal melanoma, alterations in ElFAX1, SF3B1, or BAP1 have been shown to indicate low, intermediate, and high risk of metastasis, respectively.
Other factors associated with the risk of metastasis after primary tumor treatment in uveal melanoma include clinical factors (tumor size, ciliary body involvement, and extraocular extension); histopathologic factors (spindle or epithelioid cell type); and cytogenetics (status of chromosomes 3, 6, and 8), he said.
An AJCC Ophthalmic Oncology Task Force study published in 2015, for example, showed that the 5-year metastasis-free survival was 97% for AJCC stage T1 disease, 85% for stage T2, 77% for stage T3, and 61% for stage T4. T-stage modifiers, which are based on particular tumor characteristics, such as ciliary body involvement (CBI) and extraocular extension (EXE), were also associated with the risk of distant metastasis: 5-year metastasis-free survival was 90%, 72%, 54% and 33% for AJCC T_a (no CBI or EXE), T_b (CBI only), T_c (EXE only), and T_d tumors (CBI and EXE), respectively.
Follow-up imaging after primary tumor treatment should be based on the most likely site of metastatic recurrence, which is the liver in 90% of uveal melanoma metastases.
“For this reason, surveillance of high-risk patients with uveal melanoma should include specific imaging of the liver,” Dr. Barker said, who noted that the NCCN risk stratification–based surveillance guidelines categorize patients as either low, medium, or high risk for metastasis based on the various characteristics that can affect risk.
“These risk groups help clinicians identify how often imaging should be performed in their surveillance strategy,” he said, adding that those who are high risk based on BAP1 mutation, PRAME mutation, CBI, or EXE, for example, should undergo imaging to evaluate signs or symptoms every 3-6 months for 5 years, every 6-12 months for 10 years, and then as clinically indicated thereafter.
The guideline calls for less stringent imaging for low- and medium-risk patients.
“Now, what happens when distant metastases are identified? Unfortunately there is no single systemic therapy that has proven to be most effective for uveal melanoma,” he said. “For this reason, the NCCN guideline encourages clinical trial participation whenever possible for patients who develop distant metastasis.”
This is because drugs effective for cutaneous melanoma are far less effective for uveal melanoma, but do elicit response in some patients and can be considered, he explained.
“Moreover, because the liver is the site of metastasis most often, and is often the exclusive site of metastasis, liver metastasis–directed therapy is considered part of the management of patients with uveal melanoma,” he said, adding that this can involve resection, ablation, chemo/radio embolization, or regional perfusion.”
The NCCN Uveal Melanoma Guidelines were developed by a panel of experts from various institutions based on the available evidence and on consensus; they are category 2A (based on lower-level evidence with uniform NCCN consensus that the intervention is appropriate).
Dr. Barker reported receiving clinical research support from Amgen, Bristol-Myers Squibb, Elekta, Merck, University of California San Francisco, and University of Florida Health Cancer Center Orlando, and serving as an advisor, consultant, or expert witness for Pfizer.
ORLANDO – Uveal melanoma has little in common with it’s cutaneous namesake, and its distinct characteristics necessitated the development of specific guidelines for diagnosis and management, which were released earlier this year by the National Comprehensive Cancer Network (NCCN).
Unlike cutaneous melanoma, uveal melanoma is usually treated with radiotherapy rather than surgery, and primary treatment is based on tumor size, according to Christopher A. Barker, MD, a radiation oncologist and director of clinical investigations in the department of radiation at Memorial Sloan Kettering Cancer Center, New York.
Further, molecular testing aids in prognosis in uveal melanoma but not in predicting treatment response as it can in cutaneous disease, and recurrences of uveal melanoma are typically distant – usually occurring in the liver – rather than in the skin or lymph nodes as with cutaneous melanoma.
These and other diagnosis- and treatment-related issues are outlined in the new guidelines, which are the first developed by the NCCN for uveal melanoma.
Guidelines exist in several countries, including Australia, the United Kingdom, Canada, and the United States (published by The American Brachytherapy Society), but until now none have provided pathway-based strategies for the management of all stages of this rare disease that affects about 1 in 200,000 Americans, typically Caucasians in their 50s, 60s, or 70s, Dr. Barker, a member of the NCCN Melanoma guidelines panel and the uveal melanoma subcommittee, said at the NCCN’s annual meeting where he presented the guidelines.
The median age of diagnosis is 60 years, he noted.
The NCCN guidelines specifically address melanoma arising in the choroid and ciliary body of the uvea. The choroid is the predominant site of uveal melanoma origin, and tumors arising there may involve the ciliary body as well, although the latter is a rare site of melanoma origin. The iris is also a rare site of origin, and tumors arising there are typically indolent in nature and thus are not part of the new guidelines, he explained.
Risk factors include choroidal nevi, ocular melanocytosis, and familial uveal melanoma associated with germline BAP1 mutation, neurofibromatosis, or dysplastic nevus syndrome; cutaneous melanoma is not a risk factor, he said.
The guidelines address clinical presentation, diagnostic work-up, and staging; primary treatments; and metastatic risks and follow-up imaging.
Presentation, diagnosis, and staging
About two-thirds of patients with uveal melanoma present because of changes in their vision, and about a third present with no new symptoms and are diagnosed during routine evaluation, Dr. Barker said.
“History and physical exam, and specifically attention to any prior malignancies, is important,” he said. “A comprehensive eye examination is absolutely vital to the evaluation and staging of patients with uveal melanoma.”
Numerous additional testing options, including autofluorescence of the ocular fundus, retinal fluorescein angiography of the ocular fundus, and transillumination, among others, are listed in the guidelines, which note that MRI is sometimes needed to confirm diagnosis.
Biopsies, however, are generally only performed to confirm diagnosis if needed or for prognostic analysis for risk stratification.
Staging is determined mainly by tumor size, which is known to be associated with outcomes in patients with uveal melanoma, and is based on criteria from both the Collaborative Ocular Melanoma Study (COMS) staging system and the American Joint Committee on Cancer (AJCC) staging manual, Dr. Barker said.
The COMS system was developed based on separate studies of small, medium, and large tumors and helped define primary tumor management and establish existing standards of care. The AJCC system was developed subsequently and focuses more on tumor features that may improve clinical predictions.
Primary treatments
Options for primary treatment for small tumors (largest diameter 5-16 mm and thickness less than 2.5 mm) include plaque brachytherapy, partical beam radiation, and laser ablation in highly select patients. For medium tumors (18mm or less at largest diameter and thickness of 2.5-10 mm), they include plaque brachytherapy, particle beam radiation, and enucleation, according to the guidelines.
Large tumors can be treated with radiotherapy (preferably particle beam radiation, Dr. Barker said) or enucleation. Large tumors are those greater than 18mm with any thickness, those with thickness greater than 10mm with any diameter, and those with thickness greater than 8mm with optic nerve involvement.
In patients for whom surgical removal is selected, “ there are a few unusual situations where additional local adjuvant therapy might be considered,” Dr. Barker said, explaining, for example, that the presence of microscopically positive or close margins after enucleation without evidence of gross residual disease in the orbit may be observed or may warrant map biopsy and/or particle beam or photon beam radiotherapy to the orbit.
For visible extraocular tumors or suspicion of gross disease in the orbit, biopsy of the extraocular tissue is recommended when possible, along with either intraoperative cryotherapy, orbital exenteration, or particle beam or photon beam radiotherapy to the orbit, he added.
Metastatic risks and follow-up imaging
Recent studies, including Cancer Genome Atlas Research Network studies, have elucidated the genomics of both uveal and cutaneous melanomas, and they show “a completely different mutation spectrum” for uveal melanoma, Dr. Barker said.
These genomic studies demonstrate that cutaneous melanoma involves mutations that predict response to certain treatments, while those found in uveal melanoma do not, but they are, however, associated with the probability of metastasis, he said.
For example, various studies have shown that BRAF mutation in cutaneous melanoma predicts response to RAF or MEK inhibition and that the overall number of mutations in cutaneous melanoma may predict response to immunotherapy.
In uveal melanoma, alterations in ElFAX1, SF3B1, or BAP1 have been shown to indicate low, intermediate, and high risk of metastasis, respectively.
Other factors associated with the risk of metastasis after primary tumor treatment in uveal melanoma include clinical factors (tumor size, ciliary body involvement, and extraocular extension); histopathologic factors (spindle or epithelioid cell type); and cytogenetics (status of chromosomes 3, 6, and 8), he said.
An AJCC Ophthalmic Oncology Task Force study published in 2015, for example, showed that the 5-year metastasis-free survival was 97% for AJCC stage T1 disease, 85% for stage T2, 77% for stage T3, and 61% for stage T4. T-stage modifiers, which are based on particular tumor characteristics, such as ciliary body involvement (CBI) and extraocular extension (EXE), were also associated with the risk of distant metastasis: 5-year metastasis-free survival was 90%, 72%, 54% and 33% for AJCC T_a (no CBI or EXE), T_b (CBI only), T_c (EXE only), and T_d tumors (CBI and EXE), respectively.
Follow-up imaging after primary tumor treatment should be based on the most likely site of metastatic recurrence, which is the liver in 90% of uveal melanoma metastases.
“For this reason, surveillance of high-risk patients with uveal melanoma should include specific imaging of the liver,” Dr. Barker said, who noted that the NCCN risk stratification–based surveillance guidelines categorize patients as either low, medium, or high risk for metastasis based on the various characteristics that can affect risk.
“These risk groups help clinicians identify how often imaging should be performed in their surveillance strategy,” he said, adding that those who are high risk based on BAP1 mutation, PRAME mutation, CBI, or EXE, for example, should undergo imaging to evaluate signs or symptoms every 3-6 months for 5 years, every 6-12 months for 10 years, and then as clinically indicated thereafter.
The guideline calls for less stringent imaging for low- and medium-risk patients.
“Now, what happens when distant metastases are identified? Unfortunately there is no single systemic therapy that has proven to be most effective for uveal melanoma,” he said. “For this reason, the NCCN guideline encourages clinical trial participation whenever possible for patients who develop distant metastasis.”
This is because drugs effective for cutaneous melanoma are far less effective for uveal melanoma, but do elicit response in some patients and can be considered, he explained.
“Moreover, because the liver is the site of metastasis most often, and is often the exclusive site of metastasis, liver metastasis–directed therapy is considered part of the management of patients with uveal melanoma,” he said, adding that this can involve resection, ablation, chemo/radio embolization, or regional perfusion.”
The NCCN Uveal Melanoma Guidelines were developed by a panel of experts from various institutions based on the available evidence and on consensus; they are category 2A (based on lower-level evidence with uniform NCCN consensus that the intervention is appropriate).
Dr. Barker reported receiving clinical research support from Amgen, Bristol-Myers Squibb, Elekta, Merck, University of California San Francisco, and University of Florida Health Cancer Center Orlando, and serving as an advisor, consultant, or expert witness for Pfizer.
ORLANDO – Uveal melanoma has little in common with it’s cutaneous namesake, and its distinct characteristics necessitated the development of specific guidelines for diagnosis and management, which were released earlier this year by the National Comprehensive Cancer Network (NCCN).
Unlike cutaneous melanoma, uveal melanoma is usually treated with radiotherapy rather than surgery, and primary treatment is based on tumor size, according to Christopher A. Barker, MD, a radiation oncologist and director of clinical investigations in the department of radiation at Memorial Sloan Kettering Cancer Center, New York.
Further, molecular testing aids in prognosis in uveal melanoma but not in predicting treatment response as it can in cutaneous disease, and recurrences of uveal melanoma are typically distant – usually occurring in the liver – rather than in the skin or lymph nodes as with cutaneous melanoma.
These and other diagnosis- and treatment-related issues are outlined in the new guidelines, which are the first developed by the NCCN for uveal melanoma.
Guidelines exist in several countries, including Australia, the United Kingdom, Canada, and the United States (published by The American Brachytherapy Society), but until now none have provided pathway-based strategies for the management of all stages of this rare disease that affects about 1 in 200,000 Americans, typically Caucasians in their 50s, 60s, or 70s, Dr. Barker, a member of the NCCN Melanoma guidelines panel and the uveal melanoma subcommittee, said at the NCCN’s annual meeting where he presented the guidelines.
The median age of diagnosis is 60 years, he noted.
The NCCN guidelines specifically address melanoma arising in the choroid and ciliary body of the uvea. The choroid is the predominant site of uveal melanoma origin, and tumors arising there may involve the ciliary body as well, although the latter is a rare site of melanoma origin. The iris is also a rare site of origin, and tumors arising there are typically indolent in nature and thus are not part of the new guidelines, he explained.
Risk factors include choroidal nevi, ocular melanocytosis, and familial uveal melanoma associated with germline BAP1 mutation, neurofibromatosis, or dysplastic nevus syndrome; cutaneous melanoma is not a risk factor, he said.
The guidelines address clinical presentation, diagnostic work-up, and staging; primary treatments; and metastatic risks and follow-up imaging.
Presentation, diagnosis, and staging
About two-thirds of patients with uveal melanoma present because of changes in their vision, and about a third present with no new symptoms and are diagnosed during routine evaluation, Dr. Barker said.
“History and physical exam, and specifically attention to any prior malignancies, is important,” he said. “A comprehensive eye examination is absolutely vital to the evaluation and staging of patients with uveal melanoma.”
Numerous additional testing options, including autofluorescence of the ocular fundus, retinal fluorescein angiography of the ocular fundus, and transillumination, among others, are listed in the guidelines, which note that MRI is sometimes needed to confirm diagnosis.
Biopsies, however, are generally only performed to confirm diagnosis if needed or for prognostic analysis for risk stratification.
Staging is determined mainly by tumor size, which is known to be associated with outcomes in patients with uveal melanoma, and is based on criteria from both the Collaborative Ocular Melanoma Study (COMS) staging system and the American Joint Committee on Cancer (AJCC) staging manual, Dr. Barker said.
The COMS system was developed based on separate studies of small, medium, and large tumors and helped define primary tumor management and establish existing standards of care. The AJCC system was developed subsequently and focuses more on tumor features that may improve clinical predictions.
Primary treatments
Options for primary treatment for small tumors (largest diameter 5-16 mm and thickness less than 2.5 mm) include plaque brachytherapy, partical beam radiation, and laser ablation in highly select patients. For medium tumors (18mm or less at largest diameter and thickness of 2.5-10 mm), they include plaque brachytherapy, particle beam radiation, and enucleation, according to the guidelines.
Large tumors can be treated with radiotherapy (preferably particle beam radiation, Dr. Barker said) or enucleation. Large tumors are those greater than 18mm with any thickness, those with thickness greater than 10mm with any diameter, and those with thickness greater than 8mm with optic nerve involvement.
In patients for whom surgical removal is selected, “ there are a few unusual situations where additional local adjuvant therapy might be considered,” Dr. Barker said, explaining, for example, that the presence of microscopically positive or close margins after enucleation without evidence of gross residual disease in the orbit may be observed or may warrant map biopsy and/or particle beam or photon beam radiotherapy to the orbit.
For visible extraocular tumors or suspicion of gross disease in the orbit, biopsy of the extraocular tissue is recommended when possible, along with either intraoperative cryotherapy, orbital exenteration, or particle beam or photon beam radiotherapy to the orbit, he added.
Metastatic risks and follow-up imaging
Recent studies, including Cancer Genome Atlas Research Network studies, have elucidated the genomics of both uveal and cutaneous melanomas, and they show “a completely different mutation spectrum” for uveal melanoma, Dr. Barker said.
These genomic studies demonstrate that cutaneous melanoma involves mutations that predict response to certain treatments, while those found in uveal melanoma do not, but they are, however, associated with the probability of metastasis, he said.
For example, various studies have shown that BRAF mutation in cutaneous melanoma predicts response to RAF or MEK inhibition and that the overall number of mutations in cutaneous melanoma may predict response to immunotherapy.
In uveal melanoma, alterations in ElFAX1, SF3B1, or BAP1 have been shown to indicate low, intermediate, and high risk of metastasis, respectively.
Other factors associated with the risk of metastasis after primary tumor treatment in uveal melanoma include clinical factors (tumor size, ciliary body involvement, and extraocular extension); histopathologic factors (spindle or epithelioid cell type); and cytogenetics (status of chromosomes 3, 6, and 8), he said.
An AJCC Ophthalmic Oncology Task Force study published in 2015, for example, showed that the 5-year metastasis-free survival was 97% for AJCC stage T1 disease, 85% for stage T2, 77% for stage T3, and 61% for stage T4. T-stage modifiers, which are based on particular tumor characteristics, such as ciliary body involvement (CBI) and extraocular extension (EXE), were also associated with the risk of distant metastasis: 5-year metastasis-free survival was 90%, 72%, 54% and 33% for AJCC T_a (no CBI or EXE), T_b (CBI only), T_c (EXE only), and T_d tumors (CBI and EXE), respectively.
Follow-up imaging after primary tumor treatment should be based on the most likely site of metastatic recurrence, which is the liver in 90% of uveal melanoma metastases.
“For this reason, surveillance of high-risk patients with uveal melanoma should include specific imaging of the liver,” Dr. Barker said, who noted that the NCCN risk stratification–based surveillance guidelines categorize patients as either low, medium, or high risk for metastasis based on the various characteristics that can affect risk.
“These risk groups help clinicians identify how often imaging should be performed in their surveillance strategy,” he said, adding that those who are high risk based on BAP1 mutation, PRAME mutation, CBI, or EXE, for example, should undergo imaging to evaluate signs or symptoms every 3-6 months for 5 years, every 6-12 months for 10 years, and then as clinically indicated thereafter.
The guideline calls for less stringent imaging for low- and medium-risk patients.
“Now, what happens when distant metastases are identified? Unfortunately there is no single systemic therapy that has proven to be most effective for uveal melanoma,” he said. “For this reason, the NCCN guideline encourages clinical trial participation whenever possible for patients who develop distant metastasis.”
This is because drugs effective for cutaneous melanoma are far less effective for uveal melanoma, but do elicit response in some patients and can be considered, he explained.
“Moreover, because the liver is the site of metastasis most often, and is often the exclusive site of metastasis, liver metastasis–directed therapy is considered part of the management of patients with uveal melanoma,” he said, adding that this can involve resection, ablation, chemo/radio embolization, or regional perfusion.”
The NCCN Uveal Melanoma Guidelines were developed by a panel of experts from various institutions based on the available evidence and on consensus; they are category 2A (based on lower-level evidence with uniform NCCN consensus that the intervention is appropriate).
Dr. Barker reported receiving clinical research support from Amgen, Bristol-Myers Squibb, Elekta, Merck, University of California San Francisco, and University of Florida Health Cancer Center Orlando, and serving as an advisor, consultant, or expert witness for Pfizer.
EXPERT ANALYSIS FROM THE NCCN ANNUAL CONFERENCE