Cutis

Human papillomavirus (HPV)-induced tumors of the skin are often varied in clinical presentation, ranging from benign warts to malignant neoplasms. This article reviews the natural history and recommended treatment of some of the common HPV-induced tumors, as well as reviews many of the clinical trials for future wart therapies. This review is not meant to serve as a guideline or to be all-inclusive. Almost invariably, HPV-associated diseases are difficult to treat. The treatment options employed by healthcare professionals are usually dependent on their prior experience or exposure during residency. Many wart treatments are based on anecdotal evidence rather than on carefully conducted clinical trials. A systematic review of the literature was performed using the 1966–April 2002 MEDLINE database, the 1967–2000 PubMed database (National Library of Medicine), and the Cochrane Database of Systematic Reviews. Randomized clinical trials, controlled clinical trials, and multicenter studies were reviewed. Articles were included in the evaluation if they were printed in English, reported on human subjects, and analyzed subjects who had cutaneous nongenital warts.

Human papillomavirus (HPV)-induced tumors of the skin are often varied in clinical presentation, ranging from benign warts to malignant neoplasms. This article reviews the natural history and recommended treatment of some of the common HPV-induced tumors, as well as reviews many of the clinical trials for future wart therapies. This review is not meant to serve as a guideline or to be all-inclusive. Almost invariably, HPV-associated diseases are difficult to treat. The treatment options employed by healthcare professionals are usually dependent on their prior experience or exposure during residency. Many wart treatments are based on anecdotal evidence rather than on carefully conducted clinical trials. A systematic review of the literature was performed using the 1966–April 2002 MEDLINE database, the 1967–2000 PubMed database (National Library of Medicine), and the Cochrane Database of Systematic Reviews. Randomized clinical trials, controlled clinical trials, and multicenter studies were reviewed. Articles were included in the evaluation if they were printed in English, reported on human subjects, and analyzed subjects who had cutaneous nongenital warts.

Human papillomavirus (HPV)-induced tumors of the skin are often varied in clinical presentation, ranging from benign warts to malignant neoplasms. This article reviews the natural history and recommended treatment of some of the common HPV-induced tumors, as well as reviews many of the clinical trials for future wart therapies. This review is not meant to serve as a guideline or to be all-inclusive. Almost invariably, HPV-associated diseases are difficult to treat. The treatment options employed by healthcare professionals are usually dependent on their prior experience or exposure during residency. Many wart treatments are based on anecdotal evidence rather than on carefully conducted clinical trials. A systematic review of the literature was performed using the 1966–April 2002 MEDLINE database, the 1967–2000 PubMed database (National Library of Medicine), and the Cochrane Database of Systematic Reviews. Randomized clinical trials, controlled clinical trials, and multicenter studies were reviewed. Articles were included in the evaluation if they were printed in English, reported on human subjects, and analyzed subjects who had cutaneous nongenital warts.

α1-Antitrypsin deficiency panniculitis (A1ADP) is a rare form of panniculitis that affects children and adults. Clinical and histologic features, precipitating actors, and treatments are discussed.

α1-Antitrypsin, a serine protease inhibitor synthesized in the liver, regulates the action of proteolytic enzymes including trypsin, collagenase, elastase, factor VIII, chymotrypsin, and kallikrein. A deficiency of this protein is hypothesized to lead to
inadequate inhibition of proteases released by neutrophils and monocytes, which in turn results in unchecked inflammation and tissue necrosis.1 The systemic sequelae of this phenomenon include panacinar emphysema, hepatitis, cirrhosis, hemorrhagic diathesis, and panniculitis.2 Panniculitis most commonly occurs in patients with the severe homozygous deficiency PiZZ phenotype, resulting in serum α1-antitrypsin levels that are 10% of normal. The lesions may mimic cellulitis and are most frequently found on the trunk and proximal extremities. Characteristic microscopic features include neutrophils between collagen bundles in
reticular dermis, septal panniculitis with liquefactive necrosis, and collagenolysis with large areas of normal fat lobules adjacent to necrotic fat.3

Case Report
After falling down the stairs at home, a previously healthy 40-year-old woman presented to the emergency department with a tender edematous 25-cm hematoma on the right lateral thigh. The patient was treated empirically for an infected hematoma; use of oral antibiotics resulted in partial improvement. Subsequently, atraumatic indurated plaques and nodules developed on the
extremities; these plaques and nodules were minimally responsive to oral and intravenous antibiotics. The hematoma was incised and drained. Culture results were negative for bacterial and fungal growth. Serous fluid drained from a left-buttock nodule that had spontaneously ulcerated. The patient was admitted to our hospital for further diagnosis and management.

The patient was comfortable and nontoxic. Her temperature was 99.8ºF, and her heart rate was 88 bpm. Distributed over the right axilla, the medial area of the left elbow, the left ankle, the distal area of the right tibia, and the lateral area of the right thigh were multiple, deep, red, tender, indurated, 4- to 25-cm nodules and plaques (Figure 1). On the left buttock was an ulcerated 5-cm nodule.

A biopsy of the right axillary lesion was performed. Results of histologic examination showed normal epidermis and dermis. Mixed lobular and septal panniculitis included normal fat lobules adjacent to necrotic fat lobules (Figure 2). The infiltrate was composed of lymphocytes, histiocytes, and pools of neutrophils with suppuration, liquefactive necrosis, and collagenolysis (Figure 3). Neutrophils were splayed between collagen bundles (Figure 4). Granulomata were not evident, and there was no evidence of vasculitis. Periodic acid–Schiff, Gram, and acid-fast bacillus stains were negative for microorganisms. Refractile material was not evident under polariscopic examination. The microscopic differential diagnosis included infections, factitial panniculitis, subcutaneous Sweet syndrome, pancreatic fat necrosis, and α1-antitrypsin deficiency panniculitis (A1ADP).

Levels of antineutrophil cytoplasmic antibodies (p-ANCA, c-ANCA), C3, C4, and CH50 were normal. Cryoglobulins were not detected. Complete blood cell count and amylase and lipase levels were normal. Erythrocyte sedimentation rate was
elevated (52 mm/h).

Serum α1-antitrypsin level was 37.0 mg/dL (reference range, 84–218 mg/dL) with a ZZ phenotype. Results of a chest radiograph, liver function tests, and pulmonary function tests were normal. Given the clinical and pathologic findings and the results from the genetic α1 phenotyping, α1-antitrypsin deficiency was diagnosed. The patient, treated with dapsone, improved dramatically.

Comment
α1-Antitrypsin, a polypeptide glycoprotein synthesized by hepatocytes, inhibits collagenase, elastase, factor VIII, chymotrypsin, and kallikrein.1 α1-Antitrypsin is an acute-phase reactant that increases in serum concentration with stress from illness or trauma. Protease activation in the absence of α1-antitrypsin may trigger a cascade of inflammatory events that ultimately damage the tissues they are
meant to protect.2 Speculation is that absence of α1-antitrypsin allows inflammation to continue unabated and thus leads to panniculitis.

α1-Antitrypsin deficiency most frequently causes severe and rapidly progressive panacinar emphysema. This deficiency also is associated with hepatitis, cirrhosis,
vasculitis, acquired angioedema, Marshall syndrome, and severe psoriasis.4 Recently, α1-antitrypsin deficiency was used as a model for conformational
diseases (including liver cirrhosis) and neurodegenerative disorders (including Alzheimer disease and spongiform encephalopathies).5

Serum concentration of α1-antitrypsin is determined by inheritance of autosomal codominant alleles—M, S, and Z being the most common.6 Most cases of A1ADP occur in individuals with a severe homozygous deficiency (ZZ phenotype).3
Ninety-five percent of the US population shares the normal protease inhibitor MM phenotype designated type M. SZ heterozygotes have one third of the normal inhibitor level and a relatively low risk of developing emphysema.6 Prevalence of
the SZ phenotype ranges from 1 in 180 to 1 in 2500 individuals, depending on geographic location.7 Type Z, an α1-antitrypsin variant, differs from the M protein by a single amino acid substitution (lysine for glutamic acid).1 This substitution
results in a changed conformation leading to inhibition of α1-antitrypsin release from hepatocytes and decreased serum levels in patients with the protease inhibitor ZZ phenotype. Homozygous deficiency occurs in about 1 in 2500 individuals; heterozygous deficiency occurs in about 1 in 50.

The case reported here demonstrates many important features of A1ADP. First, our patient linked the onset of her symptoms to her fall down the stairs and her resulting injury of the right lower extremity. Another reviewer found that 6 of
18 cases of A1ADP were precipitated by trauma,8 and an investigator reported the case of a patient who had subclinical 1-antitrypsin deficiency and who developed panniculitis after trauma induced by cryosurgery.9

Second, our case demonstrates the typical clinical characteristics of A1ADP, including location on the proximal area of the lower extremities and axilla
and drainage of serous fluid. Lesions of this disease begin as tender, erythematous, indurated subcutaneous nodules that may be widely disseminated on the trunk or extremities. These lesions spontaneously ulcerate and drain oily, serosanguineous fluid.1 As reported in a review, 16 patients developed such lesions predominantly on the trunk and proximal area of the extremities.8

Third, our patient was diagnosed with a secondarily infected hematoma and cellulitis; repeated trials of antibiotics failed. Antibacterial treatment is completely ineffective in the management of A1ADP. Failure of multiple trials of oral antibiotics
and intravenous antibiotics exemplifies the difficulties encountered in making the diagnosis of A1ADP.

Integral to the diagnosis of our patient’s condition was the right axillary skin biopsy and laboratory evaluation of serum α1-antitrypsin level. Foci of fat necrosis adjacent to large areas of normal fat and acute lobular panniculitis with a large number of neutrophils are characteristic findings.

Other histologic findings should be addressed. Geller and Su3 described the earliest histopathologic findings of A1ADP as splaying of neutrophils between collagen bundles in the reticular dermis. Degeneration of collagen within the dermis, progressive dermal necrosis, and subsequent involvement of fibrous septa and subcutaneous fat are additional features of A1ADP. Therefore, histologic examination is an important diagnostic tool.

The cornerstone of the diagnosis in our patient’s case was the finding of a low level of α1-antitrypsin (37.0 mg/dL) and P1 typing of ZZ. Given the availability of the assay and the prolonged diagnostic challenge marked by multiple unsuccessful trials of antibiotics, running the assay earlier in the workup may be beneficial in cases with a high index of suspicion.

Treatment of A1ADP should include avoidance of trauma and surgical debridements—frequent precipitating factors of panniculitis.10 Dapsone, seemingly the treatment of choice, has been anecdotally effective in a number of cases of A1ADP.
For homozygous patients who have severe forms of the disease and who present with severe emphysema and liver failure, supplemental infusion of exogenous α1 protease inhibitor concentrate has been suggested as the most important therapeutic possibility.9

A1ADP is difficult to diagnose but should be considered when a patient with recurrent painful indurated plaques presents after sustaining a localized trauma.

α1-Antitrypsin deficiency panniculitis (A1ADP) is a rare form of panniculitis that affects children and adults. Clinical and histologic features, precipitating actors, and treatments are discussed.

α1-Antitrypsin, a serine protease inhibitor synthesized in the liver, regulates the action of proteolytic enzymes including trypsin, collagenase, elastase, factor VIII, chymotrypsin, and kallikrein. A deficiency of this protein is hypothesized to lead to
inadequate inhibition of proteases released by neutrophils and monocytes, which in turn results in unchecked inflammation and tissue necrosis.1 The systemic sequelae of this phenomenon include panacinar emphysema, hepatitis, cirrhosis, hemorrhagic diathesis, and panniculitis.2 Panniculitis most commonly occurs in patients with the severe homozygous deficiency PiZZ phenotype, resulting in serum α1-antitrypsin levels that are 10% of normal. The lesions may mimic cellulitis and are most frequently found on the trunk and proximal extremities. Characteristic microscopic features include neutrophils between collagen bundles in
reticular dermis, septal panniculitis with liquefactive necrosis, and collagenolysis with large areas of normal fat lobules adjacent to necrotic fat.3

Case Report
After falling down the stairs at home, a previously healthy 40-year-old woman presented to the emergency department with a tender edematous 25-cm hematoma on the right lateral thigh. The patient was treated empirically for an infected hematoma; use of oral antibiotics resulted in partial improvement. Subsequently, atraumatic indurated plaques and nodules developed on the
extremities; these plaques and nodules were minimally responsive to oral and intravenous antibiotics. The hematoma was incised and drained. Culture results were negative for bacterial and fungal growth. Serous fluid drained from a left-buttock nodule that had spontaneously ulcerated. The patient was admitted to our hospital for further diagnosis and management.

The patient was comfortable and nontoxic. Her temperature was 99.8ºF, and her heart rate was 88 bpm. Distributed over the right axilla, the medial area of the left elbow, the left ankle, the distal area of the right tibia, and the lateral area of the right thigh were multiple, deep, red, tender, indurated, 4- to 25-cm nodules and plaques (Figure 1). On the left buttock was an ulcerated 5-cm nodule.

A biopsy of the right axillary lesion was performed. Results of histologic examination showed normal epidermis and dermis. Mixed lobular and septal panniculitis included normal fat lobules adjacent to necrotic fat lobules (Figure 2). The infiltrate was composed of lymphocytes, histiocytes, and pools of neutrophils with suppuration, liquefactive necrosis, and collagenolysis (Figure 3). Neutrophils were splayed between collagen bundles (Figure 4). Granulomata were not evident, and there was no evidence of vasculitis. Periodic acid–Schiff, Gram, and acid-fast bacillus stains were negative for microorganisms. Refractile material was not evident under polariscopic examination. The microscopic differential diagnosis included infections, factitial panniculitis, subcutaneous Sweet syndrome, pancreatic fat necrosis, and α1-antitrypsin deficiency panniculitis (A1ADP).

Levels of antineutrophil cytoplasmic antibodies (p-ANCA, c-ANCA), C3, C4, and CH50 were normal. Cryoglobulins were not detected. Complete blood cell count and amylase and lipase levels were normal. Erythrocyte sedimentation rate was
elevated (52 mm/h).

Serum α1-antitrypsin level was 37.0 mg/dL (reference range, 84–218 mg/dL) with a ZZ phenotype. Results of a chest radiograph, liver function tests, and pulmonary function tests were normal. Given the clinical and pathologic findings and the results from the genetic α1 phenotyping, α1-antitrypsin deficiency was diagnosed. The patient, treated with dapsone, improved dramatically.

Comment
α1-Antitrypsin, a polypeptide glycoprotein synthesized by hepatocytes, inhibits collagenase, elastase, factor VIII, chymotrypsin, and kallikrein.1 α1-Antitrypsin is an acute-phase reactant that increases in serum concentration with stress from illness or trauma. Protease activation in the absence of α1-antitrypsin may trigger a cascade of inflammatory events that ultimately damage the tissues they are
meant to protect.2 Speculation is that absence of α1-antitrypsin allows inflammation to continue unabated and thus leads to panniculitis.

α1-Antitrypsin deficiency most frequently causes severe and rapidly progressive panacinar emphysema. This deficiency also is associated with hepatitis, cirrhosis,
vasculitis, acquired angioedema, Marshall syndrome, and severe psoriasis.4 Recently, α1-antitrypsin deficiency was used as a model for conformational
diseases (including liver cirrhosis) and neurodegenerative disorders (including Alzheimer disease and spongiform encephalopathies).5

Serum concentration of α1-antitrypsin is determined by inheritance of autosomal codominant alleles—M, S, and Z being the most common.6 Most cases of A1ADP occur in individuals with a severe homozygous deficiency (ZZ phenotype).3
Ninety-five percent of the US population shares the normal protease inhibitor MM phenotype designated type M. SZ heterozygotes have one third of the normal inhibitor level and a relatively low risk of developing emphysema.6 Prevalence of
the SZ phenotype ranges from 1 in 180 to 1 in 2500 individuals, depending on geographic location.7 Type Z, an α1-antitrypsin variant, differs from the M protein by a single amino acid substitution (lysine for glutamic acid).1 This substitution
results in a changed conformation leading to inhibition of α1-antitrypsin release from hepatocytes and decreased serum levels in patients with the protease inhibitor ZZ phenotype. Homozygous deficiency occurs in about 1 in 2500 individuals; heterozygous deficiency occurs in about 1 in 50.

The case reported here demonstrates many important features of A1ADP. First, our patient linked the onset of her symptoms to her fall down the stairs and her resulting injury of the right lower extremity. Another reviewer found that 6 of
18 cases of A1ADP were precipitated by trauma,8 and an investigator reported the case of a patient who had subclinical 1-antitrypsin deficiency and who developed panniculitis after trauma induced by cryosurgery.9

Second, our case demonstrates the typical clinical characteristics of A1ADP, including location on the proximal area of the lower extremities and axilla
and drainage of serous fluid. Lesions of this disease begin as tender, erythematous, indurated subcutaneous nodules that may be widely disseminated on the trunk or extremities. These lesions spontaneously ulcerate and drain oily, serosanguineous fluid.1 As reported in a review, 16 patients developed such lesions predominantly on the trunk and proximal area of the extremities.8

Third, our patient was diagnosed with a secondarily infected hematoma and cellulitis; repeated trials of antibiotics failed. Antibacterial treatment is completely ineffective in the management of A1ADP. Failure of multiple trials of oral antibiotics
and intravenous antibiotics exemplifies the difficulties encountered in making the diagnosis of A1ADP.

Integral to the diagnosis of our patient’s condition was the right axillary skin biopsy and laboratory evaluation of serum α1-antitrypsin level. Foci of fat necrosis adjacent to large areas of normal fat and acute lobular panniculitis with a large number of neutrophils are characteristic findings.

Other histologic findings should be addressed. Geller and Su3 described the earliest histopathologic findings of A1ADP as splaying of neutrophils between collagen bundles in the reticular dermis. Degeneration of collagen within the dermis, progressive dermal necrosis, and subsequent involvement of fibrous septa and subcutaneous fat are additional features of A1ADP. Therefore, histologic examination is an important diagnostic tool.

The cornerstone of the diagnosis in our patient’s case was the finding of a low level of α1-antitrypsin (37.0 mg/dL) and P1 typing of ZZ. Given the availability of the assay and the prolonged diagnostic challenge marked by multiple unsuccessful trials of antibiotics, running the assay earlier in the workup may be beneficial in cases with a high index of suspicion.

Treatment of A1ADP should include avoidance of trauma and surgical debridements—frequent precipitating factors of panniculitis.10 Dapsone, seemingly the treatment of choice, has been anecdotally effective in a number of cases of A1ADP.
For homozygous patients who have severe forms of the disease and who present with severe emphysema and liver failure, supplemental infusion of exogenous α1 protease inhibitor concentrate has been suggested as the most important therapeutic possibility.9

A1ADP is difficult to diagnose but should be considered when a patient with recurrent painful indurated plaques presents after sustaining a localized trauma.

α1-Antitrypsin deficiency panniculitis (A1ADP) is a rare form of panniculitis that affects children and adults. Clinical and histologic features, precipitating actors, and treatments are discussed.

α1-Antitrypsin, a serine protease inhibitor synthesized in the liver, regulates the action of proteolytic enzymes including trypsin, collagenase, elastase, factor VIII, chymotrypsin, and kallikrein. A deficiency of this protein is hypothesized to lead to
inadequate inhibition of proteases released by neutrophils and monocytes, which in turn results in unchecked inflammation and tissue necrosis.1 The systemic sequelae of this phenomenon include panacinar emphysema, hepatitis, cirrhosis, hemorrhagic diathesis, and panniculitis.2 Panniculitis most commonly occurs in patients with the severe homozygous deficiency PiZZ phenotype, resulting in serum α1-antitrypsin levels that are 10% of normal. The lesions may mimic cellulitis and are most frequently found on the trunk and proximal extremities. Characteristic microscopic features include neutrophils between collagen bundles in
reticular dermis, septal panniculitis with liquefactive necrosis, and collagenolysis with large areas of normal fat lobules adjacent to necrotic fat.3

Case Report
After falling down the stairs at home, a previously healthy 40-year-old woman presented to the emergency department with a tender edematous 25-cm hematoma on the right lateral thigh. The patient was treated empirically for an infected hematoma; use of oral antibiotics resulted in partial improvement. Subsequently, atraumatic indurated plaques and nodules developed on the
extremities; these plaques and nodules were minimally responsive to oral and intravenous antibiotics. The hematoma was incised and drained. Culture results were negative for bacterial and fungal growth. Serous fluid drained from a left-buttock nodule that had spontaneously ulcerated. The patient was admitted to our hospital for further diagnosis and management.

The patient was comfortable and nontoxic. Her temperature was 99.8ºF, and her heart rate was 88 bpm. Distributed over the right axilla, the medial area of the left elbow, the left ankle, the distal area of the right tibia, and the lateral area of the right thigh were multiple, deep, red, tender, indurated, 4- to 25-cm nodules and plaques (Figure 1). On the left buttock was an ulcerated 5-cm nodule.

A biopsy of the right axillary lesion was performed. Results of histologic examination showed normal epidermis and dermis. Mixed lobular and septal panniculitis included normal fat lobules adjacent to necrotic fat lobules (Figure 2). The infiltrate was composed of lymphocytes, histiocytes, and pools of neutrophils with suppuration, liquefactive necrosis, and collagenolysis (Figure 3). Neutrophils were splayed between collagen bundles (Figure 4). Granulomata were not evident, and there was no evidence of vasculitis. Periodic acid–Schiff, Gram, and acid-fast bacillus stains were negative for microorganisms. Refractile material was not evident under polariscopic examination. The microscopic differential diagnosis included infections, factitial panniculitis, subcutaneous Sweet syndrome, pancreatic fat necrosis, and α1-antitrypsin deficiency panniculitis (A1ADP).

Levels of antineutrophil cytoplasmic antibodies (p-ANCA, c-ANCA), C3, C4, and CH50 were normal. Cryoglobulins were not detected. Complete blood cell count and amylase and lipase levels were normal. Erythrocyte sedimentation rate was
elevated (52 mm/h).

Serum α1-antitrypsin level was 37.0 mg/dL (reference range, 84–218 mg/dL) with a ZZ phenotype. Results of a chest radiograph, liver function tests, and pulmonary function tests were normal. Given the clinical and pathologic findings and the results from the genetic α1 phenotyping, α1-antitrypsin deficiency was diagnosed. The patient, treated with dapsone, improved dramatically.

Comment
α1-Antitrypsin, a polypeptide glycoprotein synthesized by hepatocytes, inhibits collagenase, elastase, factor VIII, chymotrypsin, and kallikrein.1 α1-Antitrypsin is an acute-phase reactant that increases in serum concentration with stress from illness or trauma. Protease activation in the absence of α1-antitrypsin may trigger a cascade of inflammatory events that ultimately damage the tissues they are
meant to protect.2 Speculation is that absence of α1-antitrypsin allows inflammation to continue unabated and thus leads to panniculitis.

α1-Antitrypsin deficiency most frequently causes severe and rapidly progressive panacinar emphysema. This deficiency also is associated with hepatitis, cirrhosis,
vasculitis, acquired angioedema, Marshall syndrome, and severe psoriasis.4 Recently, α1-antitrypsin deficiency was used as a model for conformational
diseases (including liver cirrhosis) and neurodegenerative disorders (including Alzheimer disease and spongiform encephalopathies).5

Serum concentration of α1-antitrypsin is determined by inheritance of autosomal codominant alleles—M, S, and Z being the most common.6 Most cases of A1ADP occur in individuals with a severe homozygous deficiency (ZZ phenotype).3
Ninety-five percent of the US population shares the normal protease inhibitor MM phenotype designated type M. SZ heterozygotes have one third of the normal inhibitor level and a relatively low risk of developing emphysema.6 Prevalence of
the SZ phenotype ranges from 1 in 180 to 1 in 2500 individuals, depending on geographic location.7 Type Z, an α1-antitrypsin variant, differs from the M protein by a single amino acid substitution (lysine for glutamic acid).1 This substitution
results in a changed conformation leading to inhibition of α1-antitrypsin release from hepatocytes and decreased serum levels in patients with the protease inhibitor ZZ phenotype. Homozygous deficiency occurs in about 1 in 2500 individuals; heterozygous deficiency occurs in about 1 in 50.

The case reported here demonstrates many important features of A1ADP. First, our patient linked the onset of her symptoms to her fall down the stairs and her resulting injury of the right lower extremity. Another reviewer found that 6 of
18 cases of A1ADP were precipitated by trauma,8 and an investigator reported the case of a patient who had subclinical 1-antitrypsin deficiency and who developed panniculitis after trauma induced by cryosurgery.9

Second, our case demonstrates the typical clinical characteristics of A1ADP, including location on the proximal area of the lower extremities and axilla
and drainage of serous fluid. Lesions of this disease begin as tender, erythematous, indurated subcutaneous nodules that may be widely disseminated on the trunk or extremities. These lesions spontaneously ulcerate and drain oily, serosanguineous fluid.1 As reported in a review, 16 patients developed such lesions predominantly on the trunk and proximal area of the extremities.8

Third, our patient was diagnosed with a secondarily infected hematoma and cellulitis; repeated trials of antibiotics failed. Antibacterial treatment is completely ineffective in the management of A1ADP. Failure of multiple trials of oral antibiotics
and intravenous antibiotics exemplifies the difficulties encountered in making the diagnosis of A1ADP.

Integral to the diagnosis of our patient’s condition was the right axillary skin biopsy and laboratory evaluation of serum α1-antitrypsin level. Foci of fat necrosis adjacent to large areas of normal fat and acute lobular panniculitis with a large number of neutrophils are characteristic findings.

Other histologic findings should be addressed. Geller and Su3 described the earliest histopathologic findings of A1ADP as splaying of neutrophils between collagen bundles in the reticular dermis. Degeneration of collagen within the dermis, progressive dermal necrosis, and subsequent involvement of fibrous septa and subcutaneous fat are additional features of A1ADP. Therefore, histologic examination is an important diagnostic tool.

The cornerstone of the diagnosis in our patient’s case was the finding of a low level of α1-antitrypsin (37.0 mg/dL) and P1 typing of ZZ. Given the availability of the assay and the prolonged diagnostic challenge marked by multiple unsuccessful trials of antibiotics, running the assay earlier in the workup may be beneficial in cases with a high index of suspicion.

Treatment of A1ADP should include avoidance of trauma and surgical debridements—frequent precipitating factors of panniculitis.10 Dapsone, seemingly the treatment of choice, has been anecdotally effective in a number of cases of A1ADP.
For homozygous patients who have severe forms of the disease and who present with severe emphysema and liver failure, supplemental infusion of exogenous α1 protease inhibitor concentrate has been suggested as the most important therapeutic possibility.9

A1ADP is difficult to diagnose but should be considered when a patient with recurrent painful indurated plaques presents after sustaining a localized trauma.