Larval Tick Infestation: A Case Report and Review of Tick-Borne Disease

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Larval Tick Infestation: A Case Report and Review of Tick-Borne Disease

Tick-borne disease in the United States continues to be a threat as people interact with their natural surroundings. We present a case of an 8-year-old boy with a larval tick infestation. Ticks within the United States can carry Lyme disease, Rocky Mountain spotted fever (RMSF), ehrlichiosis, babesiosis, tularemia, tick-borne relapsing fever, and tick paralysis. These preventable diseases are treatable when accurately recognized and diagnosed; however, if left untreated, they can cause substantial morbidity and mortality. This article highlights the knowledge necessary to recognize, treat, and prevent tick-borne disease.

Case Report
An 8-year-old boy presented to a pediatrician's office. The patient's father was concerned that his son had crabs. Because of the sensitivity of such a diagnosis, the pediatrician immediately consulted the dermatology department for more expert identification of possible crab lice. The father reported that the family had spent the weekend at a farm. Approximately 24 hours after leaving the farm, the child started to complain of itching and bugs on his genitalia. The child and family members denied any sexual abuse or sexual contact. The child did not have a fever, rash, joint pain, headache, or other complaints or concerns. Overall, the child was feeling well. Physical examination of genitalia revealed one 2- to 3-mm tick near the glans penis and 40 to 50 ticks measuring 0.5 mm in diameter located on the shaft of the penis and scrotum (Figure). A single tick was plucked as it was running across the child's leg and was identified by the local public health department as a nymphal deer tick (Ixodes dammini).


Comment
Biology of Ticks—More than 800 species of ticks exist worldwide.1 The 2 large families of ticks include hard ticks (Ixodidae) and soft ticks (Argasidae). Ixodidae ticks are the main disease vectors of concern in the United States (Table). Ixodidae genera include Ixodes, Amblyomma, and Dermacentor, each with important disease vectors.3 Hard ticks inhabit both open grassy and wooded environments, though competing arthropods may limit their range.3,4 In the southern United States, Amblyomma ticks were common in grassy areas. However, the introduction of imported fire ants, which forage for tick eggs, has limited Amblyomma ticks to wooded areas. The 2-year life cycle of ticks consists of 4 stages: egg, larva, nymph, and adult. Larvae (sometimes referred to as seed ticks) measure from 0.5 to 0.8 mm in diameter and often are difficult to recognize because of their small size.4,5 Nymphs are approximately 1.5 mm in diameter and adults can be 5 mm in diameter. Both the nymphs and adults are 8 legged, while larvae have 6 legs.3,4 A blood meal is consumed during each stage of a tick's life cycle.6

Studies have reviewed the importance of the duration of tick attachment and its relationship to disease transmission.7,8 It has been shown that maximal transmission of Borrelia burgdorferi occurred following 48 to 72 hours of tick attachment. However, transmission of Ehrlichia phagocytophila from infected Ixodes scapularis nymphs occurred within 24 hours of tick attachment.7 Another study focused on the length of time I scapularis ticks fed on human hosts before being detected and removed, and compared the duration of attachment for nymphs and adult female ticks.8 Results showed the attachment time significantly increased with age of the host (P40°C) with an irregular pattern, chills, headache, myalgia, arthralgia, and fatigue. Additional associated symptoms are a macular rash at the end of a febrile episode, conjunctival injection, hepatosplenomegaly, epistaxis, and meningeal signs.6 The initial febrile period spontaneously resolves within 3 days and is followed by an afebrile period, after which the fever will relapse. Each relapse of the fever becomes progressively more mild than the preceding episode. The diagnosis of tick-borne relapsing fever can be made by visualizing the spirochetes on the peripheral blood smear with a Giemsa or Wright stain. Detection is most likely if the smear is taken during a febrile episode. Leukocytosis and thrombocytopenia may be observed on laboratory test results. The treatment of choice is oral doxycycline 100 mg twice daily for 5 to 10 days. As an alternative therapy, erythromycin 500 mg orally 4 times daily for 5 to 7 days can be used. Penicillin G also has been proven to be effective. A Jarisch-Herxheimer reaction has been noted in some patients following initiation of therapy. Administering acetaminophen before and after antibiotic therapy may help decrease the severity of this reaction.3,12 Tick Paralysis—Tick paralysis is a toxin-mediated illness that typically occurs in children and can cause substantial morbidity and mortality if not appropriately recognized.3 In the United States, most cases have been reported in the Rocky Mountains and northwestern states.21,22 In animals, tick paralysis is caused by 43 different species of ticks, though D variabilis and D andersoni are the only ticks substantially associated with human tick paralysis in the United States.3 Because these ticks tend to attach to the scalp, they often are not identified and are most commonly found postmortem. Paralysis occurs 4 to 7 days following tick attachment. It is characterized as an acute, ascending, flaccid paralysis that often is confused with neurologic disorders, Guillain-Barré syndrome, botulism, and myasthenia gravis. The paralysis is thought to be caused by a neurotoxin that is secreted in the tick saliva during the feeding process23 and causes a presynaptic neuromuscular blockade.22,23 If the tick is not removed, dysarthria, dysphagia, and death from respiratory failure in 10% of patients is possible.22 Prevention—Prevention of tick exposure is the optimal way to decrease the amount of tick-borne disease seen in the United States. By applying N,N-diethyl-m-toluamide (or DEET) to exposed skin, treating clothing with permethrin, and wearing protective clothing while walking through grassy vegetation, individuals can minimize their tick exposure. N,N-diethyl-m-toluamide often is found in over-the-counter insect repellents and can be applied to the skin. Sustained-release formulas are preferred; efficacy plateaus at a 30% concentration of these formulations. Permethrin is an acaricide that is available as a spray. It should be applied to clothing and remains stable through many cycles of laundry.24 Garments pretreated with permethrin also are available. Prompt removal of an attached tick is critical to the prevention of tick-borne disease. Vertical traction with blunt forceps near the site of attachment can be effective. Various tick removal devices are available that are slipped under the tick to allow traction without tearing the body of the tick. It is advised to discourage patients from removing ticks with isopropyl alcohol, fingernail polish, petroleum jelly, or hot matches, or in chlorine swimming pools.12,14,23


Conclusion
Tick-borne disease continues to be a problem commonly encountered in the United States. With many people regularly enjoying the outdoors and spending more time exploring their surroundings, it is important for practitioners to recognize the signs and symptoms of tick-borne disease. Tick-borne disease within the United States includes Lyme disease, RMSF, ehrlichiosis, babesiosis, tularemia, tick-borne relapsing fever, and tick paralysis. With prompt removal and treatment, disease prognosis is generally good.

References

  1. Steen CJ, Carbonaro PA, Schwartz RA. Arthropods in dermatology. J Am Acad Dermatol. 2004;50:816-842.
  2. Wormser GP, Dattwyler RJ, Shapiro ED, et al. The clinical assessment, treatment, and prevention of Lyme disease, human granulocytic anaplasmosis, and babesiosis: clinical practice guidelines by the Infectious Diseases Society of America. Clin Infect Dis. 2006;43:1089-1134.
  3. Singh-Behl D, La Rosa SP, Tomecki KJ. Tick-borne infections. Dermatol Clin. 2003;21:237-244.
  4. Wilson ME. Tick-borne disease. Med Clin N Am. 2002;86:219-238.
  5. Culp JS. Seed ticks. Am Fam Physician. 1987;36:121-123.
  6. Buckingham SC. Tick-borne infections in children: epidemiology, clinical manifestations, and optimal management strategies. Pediatr Drugs. 2005;7:163-176.
  7. des Vignes F, Piesman J, Heffernan R, et al. Effect of tick removal on transmission of Borrelia burgdorferi and Ehrlichia phagocytophila by Ixodes scapularis nymphs. J Infect Dis. 2001;183:773-778.
  8. Falco RC, Fish D, Piesman J. Duration of tick bites in a Lyme disease-endemic area. Am J Epidemiol. 1996;143:187-192.
  9. Smith-Fiola D; Rutgers New Jersey Agricultural Experiment Station. Protect yourself from ticks and Lyme disease. http://www.cdc.gov/nasd/docs/d000901-d001000 /d000961/d000961.pdf. Accessed June 4, 2008.
  10. Jones BE. Human 'seed tick' infestation. Amblyomma americanum larvae. Arch Dermatol. 1981;117:812-814.
  11. Wormser GP. Early Lyme disease. N Engl J Med. 2006;354:2794-2801.
  12. Bratton RL, Corey GR. Tick-borne disease. Am Fam Physician. 2005;71:2323-2332.
  13. Borgos W. Arthropod-borne illness in the United States. Clin Fam Pract. 2004;6:199-207.
  14. Wormser GP, Ramanathan R, Nowakowski J, et al. Duration of antibiotic therapy for early Lyme disease. a randomized, double-blind, placebo-controlled trial. Ann Intern Med. 2003;138:697-704.
  15. Paddock CD, Holman RC, Krebs JW, et al. Assessing the magnitude of fatal Rocky Mountain spotted fever in the United States: comparison of two national data sources. Am J Trop Med Hyg. 2002;67:349-354.
  16. Chapman AS, Bakken JS, Folk SM, et al. Diagnosis and management of tickborne rickettsial disease: Rocky Mountain spotted fever, ehrlichioses, and anaplasmosis—United States: a practical guide for physicians and other health-care and public health professionals. MMWR Recomm Rep. 2006;55:1-27.
  17. Holman RC, Paddock CD, Curns AT, et al. Analysis of risk factors for fatal Rocky Mountain spotted fever: evidence for superiority of tetracyclines for therapy. J Infect Dis. 2001;184:1437-1444.
  18. Drugs for parasitic infections. Med Lett Drugs Ther. 2004. http://www.medletter.com/freedocs/parasitic.pdf. Accessed October 14, 2006.
  19. Eliasson H, Broman T, Forsman M, et al. Tularemia: current epidemiology and disease management. Infect Dis Clin N Am. 2006;20:289-311.
  20. Dorman SE, Cannon ME, Telford SR 3rd, et al. Fulminant babesiosis treated with clindamycin, quinine, and whole-blood exchange transfusion. Transfusion. 2000;40:375-380.
  21. Centers for Disease Control and Prevention. Tick
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Drs. Fibeger, Erickson, Weintraub, and Elston report no conflict of interest. The authors report no discussion of off-label use. Dr. Fibeger is a dermatology resident, St. Joseph Mercy Health System, Ann Arbor, Michigan. Dr. Erickson is Chief of Dermatology and Dr. Weintraub is Medical Director of Pediatrics, both from Scott Air Force Base, Illinois. Dr. Elston is Director, Departments of Dermatology and Laboratory Medicine, Geisinger Medical Center, Danville, Pennsylvania. The views expressed are those of the authors and are not to be construed as official or as reflecting those of the Air Force Medical Department or the Department of Defense. Dr. Erickson is a full-time federal employee.

Emily A. Fibeger, DO; Quenby L. Erickson, DO; Benjamin D. Weintraub, MD; Dirk M. Elston, MD

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Author and Disclosure Information

Drs. Fibeger, Erickson, Weintraub, and Elston report no conflict of interest. The authors report no discussion of off-label use. Dr. Fibeger is a dermatology resident, St. Joseph Mercy Health System, Ann Arbor, Michigan. Dr. Erickson is Chief of Dermatology and Dr. Weintraub is Medical Director of Pediatrics, both from Scott Air Force Base, Illinois. Dr. Elston is Director, Departments of Dermatology and Laboratory Medicine, Geisinger Medical Center, Danville, Pennsylvania. The views expressed are those of the authors and are not to be construed as official or as reflecting those of the Air Force Medical Department or the Department of Defense. Dr. Erickson is a full-time federal employee.

Emily A. Fibeger, DO; Quenby L. Erickson, DO; Benjamin D. Weintraub, MD; Dirk M. Elston, MD

Author and Disclosure Information

Drs. Fibeger, Erickson, Weintraub, and Elston report no conflict of interest. The authors report no discussion of off-label use. Dr. Fibeger is a dermatology resident, St. Joseph Mercy Health System, Ann Arbor, Michigan. Dr. Erickson is Chief of Dermatology and Dr. Weintraub is Medical Director of Pediatrics, both from Scott Air Force Base, Illinois. Dr. Elston is Director, Departments of Dermatology and Laboratory Medicine, Geisinger Medical Center, Danville, Pennsylvania. The views expressed are those of the authors and are not to be construed as official or as reflecting those of the Air Force Medical Department or the Department of Defense. Dr. Erickson is a full-time federal employee.

Emily A. Fibeger, DO; Quenby L. Erickson, DO; Benjamin D. Weintraub, MD; Dirk M. Elston, MD

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Tick-borne disease in the United States continues to be a threat as people interact with their natural surroundings. We present a case of an 8-year-old boy with a larval tick infestation. Ticks within the United States can carry Lyme disease, Rocky Mountain spotted fever (RMSF), ehrlichiosis, babesiosis, tularemia, tick-borne relapsing fever, and tick paralysis. These preventable diseases are treatable when accurately recognized and diagnosed; however, if left untreated, they can cause substantial morbidity and mortality. This article highlights the knowledge necessary to recognize, treat, and prevent tick-borne disease.

Case Report
An 8-year-old boy presented to a pediatrician's office. The patient's father was concerned that his son had crabs. Because of the sensitivity of such a diagnosis, the pediatrician immediately consulted the dermatology department for more expert identification of possible crab lice. The father reported that the family had spent the weekend at a farm. Approximately 24 hours after leaving the farm, the child started to complain of itching and bugs on his genitalia. The child and family members denied any sexual abuse or sexual contact. The child did not have a fever, rash, joint pain, headache, or other complaints or concerns. Overall, the child was feeling well. Physical examination of genitalia revealed one 2- to 3-mm tick near the glans penis and 40 to 50 ticks measuring 0.5 mm in diameter located on the shaft of the penis and scrotum (Figure). A single tick was plucked as it was running across the child's leg and was identified by the local public health department as a nymphal deer tick (Ixodes dammini).


Comment
Biology of Ticks—More than 800 species of ticks exist worldwide.1 The 2 large families of ticks include hard ticks (Ixodidae) and soft ticks (Argasidae). Ixodidae ticks are the main disease vectors of concern in the United States (Table). Ixodidae genera include Ixodes, Amblyomma, and Dermacentor, each with important disease vectors.3 Hard ticks inhabit both open grassy and wooded environments, though competing arthropods may limit their range.3,4 In the southern United States, Amblyomma ticks were common in grassy areas. However, the introduction of imported fire ants, which forage for tick eggs, has limited Amblyomma ticks to wooded areas. The 2-year life cycle of ticks consists of 4 stages: egg, larva, nymph, and adult. Larvae (sometimes referred to as seed ticks) measure from 0.5 to 0.8 mm in diameter and often are difficult to recognize because of their small size.4,5 Nymphs are approximately 1.5 mm in diameter and adults can be 5 mm in diameter. Both the nymphs and adults are 8 legged, while larvae have 6 legs.3,4 A blood meal is consumed during each stage of a tick's life cycle.6

Studies have reviewed the importance of the duration of tick attachment and its relationship to disease transmission.7,8 It has been shown that maximal transmission of Borrelia burgdorferi occurred following 48 to 72 hours of tick attachment. However, transmission of Ehrlichia phagocytophila from infected Ixodes scapularis nymphs occurred within 24 hours of tick attachment.7 Another study focused on the length of time I scapularis ticks fed on human hosts before being detected and removed, and compared the duration of attachment for nymphs and adult female ticks.8 Results showed the attachment time significantly increased with age of the host (P40°C) with an irregular pattern, chills, headache, myalgia, arthralgia, and fatigue. Additional associated symptoms are a macular rash at the end of a febrile episode, conjunctival injection, hepatosplenomegaly, epistaxis, and meningeal signs.6 The initial febrile period spontaneously resolves within 3 days and is followed by an afebrile period, after which the fever will relapse. Each relapse of the fever becomes progressively more mild than the preceding episode. The diagnosis of tick-borne relapsing fever can be made by visualizing the spirochetes on the peripheral blood smear with a Giemsa or Wright stain. Detection is most likely if the smear is taken during a febrile episode. Leukocytosis and thrombocytopenia may be observed on laboratory test results. The treatment of choice is oral doxycycline 100 mg twice daily for 5 to 10 days. As an alternative therapy, erythromycin 500 mg orally 4 times daily for 5 to 7 days can be used. Penicillin G also has been proven to be effective. A Jarisch-Herxheimer reaction has been noted in some patients following initiation of therapy. Administering acetaminophen before and after antibiotic therapy may help decrease the severity of this reaction.3,12 Tick Paralysis—Tick paralysis is a toxin-mediated illness that typically occurs in children and can cause substantial morbidity and mortality if not appropriately recognized.3 In the United States, most cases have been reported in the Rocky Mountains and northwestern states.21,22 In animals, tick paralysis is caused by 43 different species of ticks, though D variabilis and D andersoni are the only ticks substantially associated with human tick paralysis in the United States.3 Because these ticks tend to attach to the scalp, they often are not identified and are most commonly found postmortem. Paralysis occurs 4 to 7 days following tick attachment. It is characterized as an acute, ascending, flaccid paralysis that often is confused with neurologic disorders, Guillain-Barré syndrome, botulism, and myasthenia gravis. The paralysis is thought to be caused by a neurotoxin that is secreted in the tick saliva during the feeding process23 and causes a presynaptic neuromuscular blockade.22,23 If the tick is not removed, dysarthria, dysphagia, and death from respiratory failure in 10% of patients is possible.22 Prevention—Prevention of tick exposure is the optimal way to decrease the amount of tick-borne disease seen in the United States. By applying N,N-diethyl-m-toluamide (or DEET) to exposed skin, treating clothing with permethrin, and wearing protective clothing while walking through grassy vegetation, individuals can minimize their tick exposure. N,N-diethyl-m-toluamide often is found in over-the-counter insect repellents and can be applied to the skin. Sustained-release formulas are preferred; efficacy plateaus at a 30% concentration of these formulations. Permethrin is an acaricide that is available as a spray. It should be applied to clothing and remains stable through many cycles of laundry.24 Garments pretreated with permethrin also are available. Prompt removal of an attached tick is critical to the prevention of tick-borne disease. Vertical traction with blunt forceps near the site of attachment can be effective. Various tick removal devices are available that are slipped under the tick to allow traction without tearing the body of the tick. It is advised to discourage patients from removing ticks with isopropyl alcohol, fingernail polish, petroleum jelly, or hot matches, or in chlorine swimming pools.12,14,23


Conclusion
Tick-borne disease continues to be a problem commonly encountered in the United States. With many people regularly enjoying the outdoors and spending more time exploring their surroundings, it is important for practitioners to recognize the signs and symptoms of tick-borne disease. Tick-borne disease within the United States includes Lyme disease, RMSF, ehrlichiosis, babesiosis, tularemia, tick-borne relapsing fever, and tick paralysis. With prompt removal and treatment, disease prognosis is generally good.

Tick-borne disease in the United States continues to be a threat as people interact with their natural surroundings. We present a case of an 8-year-old boy with a larval tick infestation. Ticks within the United States can carry Lyme disease, Rocky Mountain spotted fever (RMSF), ehrlichiosis, babesiosis, tularemia, tick-borne relapsing fever, and tick paralysis. These preventable diseases are treatable when accurately recognized and diagnosed; however, if left untreated, they can cause substantial morbidity and mortality. This article highlights the knowledge necessary to recognize, treat, and prevent tick-borne disease.

Case Report
An 8-year-old boy presented to a pediatrician's office. The patient's father was concerned that his son had crabs. Because of the sensitivity of such a diagnosis, the pediatrician immediately consulted the dermatology department for more expert identification of possible crab lice. The father reported that the family had spent the weekend at a farm. Approximately 24 hours after leaving the farm, the child started to complain of itching and bugs on his genitalia. The child and family members denied any sexual abuse or sexual contact. The child did not have a fever, rash, joint pain, headache, or other complaints or concerns. Overall, the child was feeling well. Physical examination of genitalia revealed one 2- to 3-mm tick near the glans penis and 40 to 50 ticks measuring 0.5 mm in diameter located on the shaft of the penis and scrotum (Figure). A single tick was plucked as it was running across the child's leg and was identified by the local public health department as a nymphal deer tick (Ixodes dammini).


Comment
Biology of Ticks—More than 800 species of ticks exist worldwide.1 The 2 large families of ticks include hard ticks (Ixodidae) and soft ticks (Argasidae). Ixodidae ticks are the main disease vectors of concern in the United States (Table). Ixodidae genera include Ixodes, Amblyomma, and Dermacentor, each with important disease vectors.3 Hard ticks inhabit both open grassy and wooded environments, though competing arthropods may limit their range.3,4 In the southern United States, Amblyomma ticks were common in grassy areas. However, the introduction of imported fire ants, which forage for tick eggs, has limited Amblyomma ticks to wooded areas. The 2-year life cycle of ticks consists of 4 stages: egg, larva, nymph, and adult. Larvae (sometimes referred to as seed ticks) measure from 0.5 to 0.8 mm in diameter and often are difficult to recognize because of their small size.4,5 Nymphs are approximately 1.5 mm in diameter and adults can be 5 mm in diameter. Both the nymphs and adults are 8 legged, while larvae have 6 legs.3,4 A blood meal is consumed during each stage of a tick's life cycle.6

Studies have reviewed the importance of the duration of tick attachment and its relationship to disease transmission.7,8 It has been shown that maximal transmission of Borrelia burgdorferi occurred following 48 to 72 hours of tick attachment. However, transmission of Ehrlichia phagocytophila from infected Ixodes scapularis nymphs occurred within 24 hours of tick attachment.7 Another study focused on the length of time I scapularis ticks fed on human hosts before being detected and removed, and compared the duration of attachment for nymphs and adult female ticks.8 Results showed the attachment time significantly increased with age of the host (P40°C) with an irregular pattern, chills, headache, myalgia, arthralgia, and fatigue. Additional associated symptoms are a macular rash at the end of a febrile episode, conjunctival injection, hepatosplenomegaly, epistaxis, and meningeal signs.6 The initial febrile period spontaneously resolves within 3 days and is followed by an afebrile period, after which the fever will relapse. Each relapse of the fever becomes progressively more mild than the preceding episode. The diagnosis of tick-borne relapsing fever can be made by visualizing the spirochetes on the peripheral blood smear with a Giemsa or Wright stain. Detection is most likely if the smear is taken during a febrile episode. Leukocytosis and thrombocytopenia may be observed on laboratory test results. The treatment of choice is oral doxycycline 100 mg twice daily for 5 to 10 days. As an alternative therapy, erythromycin 500 mg orally 4 times daily for 5 to 7 days can be used. Penicillin G also has been proven to be effective. A Jarisch-Herxheimer reaction has been noted in some patients following initiation of therapy. Administering acetaminophen before and after antibiotic therapy may help decrease the severity of this reaction.3,12 Tick Paralysis—Tick paralysis is a toxin-mediated illness that typically occurs in children and can cause substantial morbidity and mortality if not appropriately recognized.3 In the United States, most cases have been reported in the Rocky Mountains and northwestern states.21,22 In animals, tick paralysis is caused by 43 different species of ticks, though D variabilis and D andersoni are the only ticks substantially associated with human tick paralysis in the United States.3 Because these ticks tend to attach to the scalp, they often are not identified and are most commonly found postmortem. Paralysis occurs 4 to 7 days following tick attachment. It is characterized as an acute, ascending, flaccid paralysis that often is confused with neurologic disorders, Guillain-Barré syndrome, botulism, and myasthenia gravis. The paralysis is thought to be caused by a neurotoxin that is secreted in the tick saliva during the feeding process23 and causes a presynaptic neuromuscular blockade.22,23 If the tick is not removed, dysarthria, dysphagia, and death from respiratory failure in 10% of patients is possible.22 Prevention—Prevention of tick exposure is the optimal way to decrease the amount of tick-borne disease seen in the United States. By applying N,N-diethyl-m-toluamide (or DEET) to exposed skin, treating clothing with permethrin, and wearing protective clothing while walking through grassy vegetation, individuals can minimize their tick exposure. N,N-diethyl-m-toluamide often is found in over-the-counter insect repellents and can be applied to the skin. Sustained-release formulas are preferred; efficacy plateaus at a 30% concentration of these formulations. Permethrin is an acaricide that is available as a spray. It should be applied to clothing and remains stable through many cycles of laundry.24 Garments pretreated with permethrin also are available. Prompt removal of an attached tick is critical to the prevention of tick-borne disease. Vertical traction with blunt forceps near the site of attachment can be effective. Various tick removal devices are available that are slipped under the tick to allow traction without tearing the body of the tick. It is advised to discourage patients from removing ticks with isopropyl alcohol, fingernail polish, petroleum jelly, or hot matches, or in chlorine swimming pools.12,14,23


Conclusion
Tick-borne disease continues to be a problem commonly encountered in the United States. With many people regularly enjoying the outdoors and spending more time exploring their surroundings, it is important for practitioners to recognize the signs and symptoms of tick-borne disease. Tick-borne disease within the United States includes Lyme disease, RMSF, ehrlichiosis, babesiosis, tularemia, tick-borne relapsing fever, and tick paralysis. With prompt removal and treatment, disease prognosis is generally good.

References

  1. Steen CJ, Carbonaro PA, Schwartz RA. Arthropods in dermatology. J Am Acad Dermatol. 2004;50:816-842.
  2. Wormser GP, Dattwyler RJ, Shapiro ED, et al. The clinical assessment, treatment, and prevention of Lyme disease, human granulocytic anaplasmosis, and babesiosis: clinical practice guidelines by the Infectious Diseases Society of America. Clin Infect Dis. 2006;43:1089-1134.
  3. Singh-Behl D, La Rosa SP, Tomecki KJ. Tick-borne infections. Dermatol Clin. 2003;21:237-244.
  4. Wilson ME. Tick-borne disease. Med Clin N Am. 2002;86:219-238.
  5. Culp JS. Seed ticks. Am Fam Physician. 1987;36:121-123.
  6. Buckingham SC. Tick-borne infections in children: epidemiology, clinical manifestations, and optimal management strategies. Pediatr Drugs. 2005;7:163-176.
  7. des Vignes F, Piesman J, Heffernan R, et al. Effect of tick removal on transmission of Borrelia burgdorferi and Ehrlichia phagocytophila by Ixodes scapularis nymphs. J Infect Dis. 2001;183:773-778.
  8. Falco RC, Fish D, Piesman J. Duration of tick bites in a Lyme disease-endemic area. Am J Epidemiol. 1996;143:187-192.
  9. Smith-Fiola D; Rutgers New Jersey Agricultural Experiment Station. Protect yourself from ticks and Lyme disease. http://www.cdc.gov/nasd/docs/d000901-d001000 /d000961/d000961.pdf. Accessed June 4, 2008.
  10. Jones BE. Human 'seed tick' infestation. Amblyomma americanum larvae. Arch Dermatol. 1981;117:812-814.
  11. Wormser GP. Early Lyme disease. N Engl J Med. 2006;354:2794-2801.
  12. Bratton RL, Corey GR. Tick-borne disease. Am Fam Physician. 2005;71:2323-2332.
  13. Borgos W. Arthropod-borne illness in the United States. Clin Fam Pract. 2004;6:199-207.
  14. Wormser GP, Ramanathan R, Nowakowski J, et al. Duration of antibiotic therapy for early Lyme disease. a randomized, double-blind, placebo-controlled trial. Ann Intern Med. 2003;138:697-704.
  15. Paddock CD, Holman RC, Krebs JW, et al. Assessing the magnitude of fatal Rocky Mountain spotted fever in the United States: comparison of two national data sources. Am J Trop Med Hyg. 2002;67:349-354.
  16. Chapman AS, Bakken JS, Folk SM, et al. Diagnosis and management of tickborne rickettsial disease: Rocky Mountain spotted fever, ehrlichioses, and anaplasmosis—United States: a practical guide for physicians and other health-care and public health professionals. MMWR Recomm Rep. 2006;55:1-27.
  17. Holman RC, Paddock CD, Curns AT, et al. Analysis of risk factors for fatal Rocky Mountain spotted fever: evidence for superiority of tetracyclines for therapy. J Infect Dis. 2001;184:1437-1444.
  18. Drugs for parasitic infections. Med Lett Drugs Ther. 2004. http://www.medletter.com/freedocs/parasitic.pdf. Accessed October 14, 2006.
  19. Eliasson H, Broman T, Forsman M, et al. Tularemia: current epidemiology and disease management. Infect Dis Clin N Am. 2006;20:289-311.
  20. Dorman SE, Cannon ME, Telford SR 3rd, et al. Fulminant babesiosis treated with clindamycin, quinine, and whole-blood exchange transfusion. Transfusion. 2000;40:375-380.
  21. Centers for Disease Control and Prevention. Tick
References

  1. Steen CJ, Carbonaro PA, Schwartz RA. Arthropods in dermatology. J Am Acad Dermatol. 2004;50:816-842.
  2. Wormser GP, Dattwyler RJ, Shapiro ED, et al. The clinical assessment, treatment, and prevention of Lyme disease, human granulocytic anaplasmosis, and babesiosis: clinical practice guidelines by the Infectious Diseases Society of America. Clin Infect Dis. 2006;43:1089-1134.
  3. Singh-Behl D, La Rosa SP, Tomecki KJ. Tick-borne infections. Dermatol Clin. 2003;21:237-244.
  4. Wilson ME. Tick-borne disease. Med Clin N Am. 2002;86:219-238.
  5. Culp JS. Seed ticks. Am Fam Physician. 1987;36:121-123.
  6. Buckingham SC. Tick-borne infections in children: epidemiology, clinical manifestations, and optimal management strategies. Pediatr Drugs. 2005;7:163-176.
  7. des Vignes F, Piesman J, Heffernan R, et al. Effect of tick removal on transmission of Borrelia burgdorferi and Ehrlichia phagocytophila by Ixodes scapularis nymphs. J Infect Dis. 2001;183:773-778.
  8. Falco RC, Fish D, Piesman J. Duration of tick bites in a Lyme disease-endemic area. Am J Epidemiol. 1996;143:187-192.
  9. Smith-Fiola D; Rutgers New Jersey Agricultural Experiment Station. Protect yourself from ticks and Lyme disease. http://www.cdc.gov/nasd/docs/d000901-d001000 /d000961/d000961.pdf. Accessed June 4, 2008.
  10. Jones BE. Human 'seed tick' infestation. Amblyomma americanum larvae. Arch Dermatol. 1981;117:812-814.
  11. Wormser GP. Early Lyme disease. N Engl J Med. 2006;354:2794-2801.
  12. Bratton RL, Corey GR. Tick-borne disease. Am Fam Physician. 2005;71:2323-2332.
  13. Borgos W. Arthropod-borne illness in the United States. Clin Fam Pract. 2004;6:199-207.
  14. Wormser GP, Ramanathan R, Nowakowski J, et al. Duration of antibiotic therapy for early Lyme disease. a randomized, double-blind, placebo-controlled trial. Ann Intern Med. 2003;138:697-704.
  15. Paddock CD, Holman RC, Krebs JW, et al. Assessing the magnitude of fatal Rocky Mountain spotted fever in the United States: comparison of two national data sources. Am J Trop Med Hyg. 2002;67:349-354.
  16. Chapman AS, Bakken JS, Folk SM, et al. Diagnosis and management of tickborne rickettsial disease: Rocky Mountain spotted fever, ehrlichioses, and anaplasmosis—United States: a practical guide for physicians and other health-care and public health professionals. MMWR Recomm Rep. 2006;55:1-27.
  17. Holman RC, Paddock CD, Curns AT, et al. Analysis of risk factors for fatal Rocky Mountain spotted fever: evidence for superiority of tetracyclines for therapy. J Infect Dis. 2001;184:1437-1444.
  18. Drugs for parasitic infections. Med Lett Drugs Ther. 2004. http://www.medletter.com/freedocs/parasitic.pdf. Accessed October 14, 2006.
  19. Eliasson H, Broman T, Forsman M, et al. Tularemia: current epidemiology and disease management. Infect Dis Clin N Am. 2006;20:289-311.
  20. Dorman SE, Cannon ME, Telford SR 3rd, et al. Fulminant babesiosis treated with clindamycin, quinine, and whole-blood exchange transfusion. Transfusion. 2000;40:375-380.
  21. Centers for Disease Control and Prevention. Tick
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Bullous Eruption: A Manifestation of Lupus Erythematosus

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Bullous systemic lupus erythematosus (BSLE) is a rare subset of systemic lupus erythematosus (SLE) associated with autoimmunity to type VII collagen.1 BSLE is an autoimmune-mediated, chronic, widespread, nonscarring, subepidermal blistering skin disease occurring in patients with SLE. In 23% of patients with SLE, cutaneous involvement is the initial manifestation. Approximately 76% of patients with SLE will have skin changes at some stage during the course of their disease. Among these patients, fewer than 5% will have chronic vesicobullous lesions.2 Generally, patients with BSLE meet the criteria for SLE as defined by the American College of Rheumatology (ACR) and have a widespread vesicobullous eruption that is generally unrelated to the severity of the SLE.3 Some patients have bullous eruptions related to lupus erythematosus (LE) but do not meet ACR criteria for SLE. We present such a patient and discuss the spectrum of bullous disease in patients with LE.


Case Report

A 17-year-old African American adolescent girl presented with a 2-day history of a blistering eruption with an abrupt onset. Physical examination revealed photodistributed tense bullae. Innumerable beadlike vesicles coalescing into larger bullae were noted on her face, with dramatic involvement of her lips and ears (Figures 1 and 2). Larger bullae on urticarial bases were found on her upper torso. Initially, no mucosal involvement was noted; however, within days, the patient developed oral and vaginal erosions. In the preceding 5 months, she had occasionally experienced a few blisters on her face but had otherwise been healthy. The patient was feeling well at the time of presentation and was not taking any medication except for a methylprednisolone dose pack prescribed during her visit to the emergency department the previous evening.

Results of a shave biopsy of an intact bulla revealed a neutrophil-rich subepidermal bulla with neutrophils stuffing the dermal papillae and lined up along the dermal-epidermal junction (DEJ) (Figure 3).

There was no leukocytoclastic vasculitis and no eosinophils were noted. Results of direct immunofluorescence (DIF) revealed IgG 4+ granular/continuous granular staining at the DEJ, trace IgM with 1+ staining of colloid bodies at the DEJ, 2+ granular/continuous granular C3 staining at the DEJ, and 3+ granular/continuous granular C1q staining at the DEJ (Figure 4).

The specimen was negative for IgA. Laboratory investigation revealed an antinuclear antibody of 1:160; anti-DNA of 1:265 (negative is <200); and negative ribonuclear protein antigen, Smith antigen, Sjögren syndrome A and B antigens, and lupus anticoagulant and anticardiolipin antibodies. Results of complete blood cell count (CBC), blood chemistry, and urinalysis were within reference range. No type VII collagen antibodies were found.

Treatment with oral steroids had begun prior to the patient presenting to dermatology, and no improvement was noted during a 1-week period. In anticipation of starting dapsone, a glucose-6-phosphate dehydrogenase level was ordered, and colchicine was begun at a dose of 0.6 mg 2 times a day. The bullous lesions showed some response within 2 days. The patient was subsequently switched to dapsone; however, colchicine was reinstated after she developed symptoms consistent with dapsone hypersensitivity, including a diffuse pruritic morbilliform eruption, nausea, and abdominal pain, with elevated liver enzyme levels—aspartate aminotransferase was 304 U/L (reference range, 0—37 U/L) and alanine aminotransferase was 360 U/L (reference range, 0–40 U/L). The eruption was eventually controlled with 0.6 mg of colchicine 3 times a day and prednisone. After multiple failed attempts to taper prednisone, 400 mg of hydroxychloroquine once a day was added. After 2 months, the patient was able to tolerate the steroid taper without a rebound flare of bullous lesions.



Comment


BSLE typically presents in the second or third decade of life. Patients with BSLE seldom have discoid lesions or annular erythema.4 Lesions may form large blisters on the trunk that resemble the lesions of bullous pemphigoid. Bullous skin lesions also may appear on flexural and extensor surfaces with a preference for sun-exposed areas. Bullae may form on an erythematous base or on normal skin. Some skin lesions present as herpetiform vesicles with clusters of ulcers. Because of the herpetiform grouping and dermatitis herpetiformlike histology, dermatitis herpetiformis should be included in the differential diagnosis, but can easily be ruled out with DIF. Oral manifestations, such as small blisters on the vermilion border of the lips, are seen in approximately 30% of cases.4

Epidermolysis bullosa acquisita (EBA) appears to share a common antigen with BSLE and has been noted in patients with LE.5 The 2 conditions may represent variants of the same condition. EBA typically presents in a patient’s fourth or fifth decade of life, with acrally distributed mechanobullous lesions or widespread inflammatory vesiculobullous lesions appearing like bullous pemphigoid.5 EBA is more likely than BSLE to result in scarring. Furthermore, mechanical skin fragility is not a common feature of BSLE, though it is a feature of EBA. BSLE lesions generally last for many weeks to months, can undergo remissions and exacerbations, and respond favorably to treatment with dapsone. Conversely, EBA often lasts for many years and is frequently treatment resistant.

Some patients with LE and bullous lesions do not meet ACR criteria for either BSLE or EBA. Our patient had serologic evidence of connective tissue disease, as well as DIF findings typical for LE. Her clinical lesions and response to treatment were similar to that of BSLE. These findings suggest that her condition represents part of a spectrum of connective tissue disease-related bullous dermatosis.

The underlying pathophysiology of BSLE and EBA relates to the structure of the DEJ. Anchoring complexes, which are specialized focal attachment sites within the DEJ, are structurally weakened by the binding of autoantibodies to its components.6 The components of the anchoring complexes, which contain type VII collagen, react with the autoantibodies in BSLE, compromising the integrity of the DEJ. This may lead to the formation of subepidermal blisters.6

The criteria for the diagnosis of BSLE proposed by Camisa and Sharma7 include a diagnosis of SLE based on the criteria of the ACR, vesicles, and bullae located on but not limited to sun-exposed skin; histopathologic findings similar to dermatitis herpetiformis; and deposition of IgG and/or IgM and often IgA at the basement membrane zone by DIF. Gammon and Briggaman5 classified BSLE into 2 distinct subtypes: patients with circulating antibodies to type VII collagen are designated as cases of BSLE-1, while patients designated as cases of BSLE-2 do not have these antibodies.

Some authors have suggested the current classification of BSLE be revised because some patients have autoantibodies bound to the epidermal side of 1 mol/L NaCl-split skin, which indicates involvement of DEJ components other than type VII collagen in BSLE.2,8 Patients also may test falsely negative for antibodies to type VII collagen, possibly because of degradation of the antibody during shipping or because they may possess antibodies to a different antigen. Failure to detect antibodies to type VII collagen does not rule out the possibility of BSLE, but data suggest that patients with lupus and bullous disease may represent a spectrum of related immunobullous disorders.

Histologically, the vesiculobullous eruption is typically characterized by dermal-epidermal separation with neutrophil-predominant inflammation in the upper dermis.7 In cases where the infiltrate concentrates in the dermal papillae as papillary microabscesses, the histologic picture is suggestive of dermatitis herpetiformis.4 Eosinophils also may be present, but are fewer in number. DIF studies characteristically show deposition of IgG, C3, IgA, and IgM at the DEJ in 2 types of patterns—granular and continuous granular—with an occasional mixed configuration.4 Circulating IgG antibodies to the DEJ have been detected in some, but not all, patients.

Ultrastructurally, electron microscopy localizes the blisters in the lamina densa region in most cases. Immunoelectron microscopic examination identified the deposition of the anti-DEJ antibodies on and beneath the lamina densa as in EBA, not in the lamina lucida as in bullous pemphigoid.4 These autoantibodies typically recognized the 290-kd and 145-kd antigens at the DEJ, with type VII collagen as the target. IgG autoantibodies to type VII collagen are believed to be pathogenic and contribute to the separation and blister formation both in BSLE and EBA.4 The production of these autoantibodies is regulated by the class II major histocompatibility complex.4

Unlike patients with EBA, most patients with BSLE respond dramatically to dapsone.5 Although dapsone has both antibiotic and anti-inflammatory properties, the anti-inflammatory mechanisms mediate the therapeutic effect in BSLE. Dapsone directly impairs the myeloperoxidase-hydrogen peroxide-halide system of polymorphonuclear neutrophils (PMNs), which prevents generation of proinflammatory oxygen intermediates caused by activation of neutrophils. Inhibition of PMN chemotaxis and mitogen-stimulated transformation of lymphocytes is another mechanism by which dapsone interferes with inflammation.9 Furthermore, dapsone prevents cyclooxygenase-mediated production of prostaglandin E2, further decreasing inflammation.

Patients with a glucose-6-phosphate dehydrogenase deficiency may experience severe hemolysis when taking dapsone; therefore, patients should be screened for this trait. Additionally, a baseline CBC and liver function test should be obtained and repeated weekly during the initial treatment period since dose-dependent hemolysis is the most common side effect of dapsone.10 Most patients will develop a 1- to 2-g drop in hemoglobin levels after initiation of treatment, which may be partially ameliorated by the concomitant use of 400 IU of vitamin E once a day.10 Other adverse reactions include methemoglobinemia, motor neuropathy, exfoliative dermatitis, hepatitis, headache, gastrointestinal upset, and rarely agranulocytosis.10 Dapsone also may induce a hypersensitivity syndrome with findings similar to those of infectious mononucleosis.9 The syndrome generally begins 4 to 6 weeks after initiation of treatment. Morbilliform eruptions with pruritus, fever, malaise, hepatitis, elevated erythrocyte sedimentation rate, lymphadenopathy, and lymphocytosis are common signs and symptoms associated with this syndrome.9 Immediate discontinuation of dapsone is recommended if symptoms arise. A good response to dapsone in the clearing of vesiculobullous lesions correlates with a better prognosis in BSLE; however, discontinuation of dapsone may allow new lesions to develop.4

Colchicine is a therapeutic option for treatment of neutrophil-mediated bullous diseases. Colchicine is known to interfere with PMN chemotaxis and the release of lysozymal enzymes by PMNs.11 Our patient achieved resolution of lesions with 0.6 mg of colchicine 3 times a day. Administered in low doses, colchicine has relatively few side effects. The most common are transient diarrhea and abdominal discomfort11; therefore, the dose requires titration to tolerance of these side effects. Other side effects of colchicine, such as neuropathy and bone marrow depression, are rare with low-dose therapy.11

Bullous lesions in patients with LE often fail to respond to treatment with systemic corticosteroids alone, and long-term corticosteroid treatment is associated with adverse metabolic effects and bone demineralization. To limit corticosteroid toxicity, adjuvant therapy with azathioprine, antimalarials, and cyclophosphamide have been reported to be useful in cases unresponsive or intolerant to dapsone.12,13 Patients initiating steroid therapy should receive a baseline weight and blood pressure measures, as well as an ophthalmologic examination. Pretreatment laboratory studies should include tests for CBC, electrolyte count, calcium level, alkaline phosphatase level, creatinine level, human immunodeficiency virus, tuberculosis, and bone densitometry. Weight, blood pressure, and blood glucose should be followed monthly until a response is established. The side effects of prolonged therapy with systemic steroids include: psychiatric disorders, sleep disturbances, cataracts, gastrointestinal upset, weight gain, peptic ulcer disease, hypertension, atherosclerosis, infection, growth failure, suppression of the hypothalmic-pituitary-adrenal axis, secondary amenorrhea, hyperglycemia, glucose intolerance, inhibition of wound healing, subcutaneous atrophy, acne, hirsutism, osteoporosis, and aseptic necrosis of bone.10 The initiation of bisphosphonate therapy when corticosteroid therapy is begun will prevent a significant loss of bone mineral density. Bisphosphonate therapy also can improve bone mineral density in patients with established bone loss due to corticosteroid therapy.

Prystowsky et al14 reported successful use of azathioprine to treat BSLE. By metabolizing to 6-thioguanine, azathioprine is incorporated into DNA yielding strand breaks secondary to blockage of DNA synthesis. Because azathioprine is metabolized by thiopurine methyltransferase, patients should be screened for activity of this enzyme prior to initiation of therapy.10,15 Individuals who are homozygous for the allele conferring low activity of this enzyme (0.3%) are at risk for profound myelosuppression with azathioprine. More commonly, patients have high levels of the enzyme and are at risk for undertreatment of their disease with inadequate doses. Long-term risks of azathioprine therapy include an increased incidence of malignancy such as lymphoma, leukemia, and squamous cell carcinoma. The prognosis in patients with SLE and bullous lesions is determined largely by the visceral manifestations of the SLE,5 yet the activity of the systemic and skin disease may not be linked.3,5 Our patient presented with immunobullous disease and serologic evidence of connective tissue disease. Her DIF finding was characteristic of LE. This case adds further evidence that there is a spectrum of related bullous disorders in patients with connective tissue disease.

References

 

  1. Fujii K, Fujimoto W, Ueda M, et al. Detection of anti-type VII collagen antibody in Sjögren's syndrome/lupus erythematosus overlap syndrome with transient bullous systemic lupus erythematosus. Br J Dermatol. 1998;139:302-306.
  2. Yell JA, Allen J, Wojnarowska F, et al. Bullous systemic lupus erythematosus: revised criteria for diagnosis. Br J Dermatol. 1995;132:921-928.
  3. Cotell S, Robinson N, Lawrence C. Autoimmune blistering skin diseases. Am J Emerg Med. 2000;18:288-299.
  4. Weinberg MA, Insler MS, Campen RB. Mucocutaneous feature of autoimmune blistering diseases. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 1997;84:517-534.
  5. Gammon WR, Briggaman RA. Epidermolysis bullosa acquisita and bullous systemic lupus erythematosus diseases of autoimmunity to type VII collagen. Dermatol Clin. 1993;11:535-547.
  6. Schmidt E, Zillikens D. Autoimmune and inherited subepidermal blistering diseases: advances in the clinic and the laboratory. Adv Dermatol. 2000;16:113-157.
  7. Camisa C, Sharma HM. Vesicobullous systems lupus erythematosus. report of two cases and review of the literature. J Am Acad Dermatol. 1983;9:924-933.
  8. Chan LS, Lapiere JC, Chen M, et al. Bullous systemic lupus erythematosus with autoantibodies recognizing multiple skin basement membrane components, bullous pemphigoid antigen 1, laminin-5, laminin-6, and type VII collagen. Arch Dermatol. 1999;135:569-573.
  9. Paniker U, Levine N. Dapsone and sulfapyridine. Dermatol Clin. 2001;19:79-86.
  10. Gleid M, Rico J. Treatment of autoimmune blistering diseases. Dermatol Clin. 1999;17:431-440.
  11. Cunningham B, Kirchmann T, Woodley D. Colchicine for epidermolysis bullosa acquisita. J Am Acad Dermatol. 1996;34:781-784.
  12. Mascaro JM, Herrero C, Hausmann G. Uncommon cutaneous manifestations of lupus erythematosus. Lupus. 1997;6:122-131.
  13. Yung A, Oakley A. Bullous systemic lupus erythematosus. Australas J Dermatol. 2000;41:234-237.
  14. Prystowsky JH, Finkel L, Tar L, et al. Bullous eruption in a woman with lupus erythematosus. Arch Dermatol. 1988;124:571, 574-575.
  15. Korman N. New and emerging therapies in the treatment of blistering diseases. Dermatol Clin. 2000;18:127-137.
  16. Pedro SD, Dahl MC. Direct immunofluorescence of bullous systemic lupus erythematosus. Arch Dermatol. 1973;107:118-120.
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Drs. Harris-Stith, Erickson, Elston, and David-Bajar report no conflict of interest. The authors report no discussion of off-label use. Dr. Harris-Stith is from Goodfellow Air Force Base, Texas; Dr. Erickson is from Wilford Hall Medical Center, Lackland Air Force Base, San Antonio, Texas; Dr. Elston is from Geisinger Medical Center, Danville, Pennsylvania; Dr. David-Bajar is from Brooke Army Medical Center, San Antonio.

CPT Ronea Harris-Stith, USAF, MC; CPT Quenby L. Erickson, USAF, MC; Dirk M. Elston, MD; COL Kathleen David-Bajar, MC, USA

Accepted for publication May 28, 2003. Dr. Harris-Stith is from Goodfellow Air Force Base, Texas; Dr. Erickson is from Wilford Hall Medical Center, Lackland Air Force Base, San Antonio, Texas; Dr. Elston is from Geisinger Medical Center, Danville, Pennsylvania; Dr. David-Bajar is from Brooke Army Medical Center, San Antonio.

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Drs. Harris-Stith, Erickson, Elston, and David-Bajar report no conflict of interest. The authors report no discussion of off-label use. Dr. Harris-Stith is from Goodfellow Air Force Base, Texas; Dr. Erickson is from Wilford Hall Medical Center, Lackland Air Force Base, San Antonio, Texas; Dr. Elston is from Geisinger Medical Center, Danville, Pennsylvania; Dr. David-Bajar is from Brooke Army Medical Center, San Antonio.

CPT Ronea Harris-Stith, USAF, MC; CPT Quenby L. Erickson, USAF, MC; Dirk M. Elston, MD; COL Kathleen David-Bajar, MC, USA

Accepted for publication May 28, 2003. Dr. Harris-Stith is from Goodfellow Air Force Base, Texas; Dr. Erickson is from Wilford Hall Medical Center, Lackland Air Force Base, San Antonio, Texas; Dr. Elston is from Geisinger Medical Center, Danville, Pennsylvania; Dr. David-Bajar is from Brooke Army Medical Center, San Antonio.

Author and Disclosure Information

 

Drs. Harris-Stith, Erickson, Elston, and David-Bajar report no conflict of interest. The authors report no discussion of off-label use. Dr. Harris-Stith is from Goodfellow Air Force Base, Texas; Dr. Erickson is from Wilford Hall Medical Center, Lackland Air Force Base, San Antonio, Texas; Dr. Elston is from Geisinger Medical Center, Danville, Pennsylvania; Dr. David-Bajar is from Brooke Army Medical Center, San Antonio.

CPT Ronea Harris-Stith, USAF, MC; CPT Quenby L. Erickson, USAF, MC; Dirk M. Elston, MD; COL Kathleen David-Bajar, MC, USA

Accepted for publication May 28, 2003. Dr. Harris-Stith is from Goodfellow Air Force Base, Texas; Dr. Erickson is from Wilford Hall Medical Center, Lackland Air Force Base, San Antonio, Texas; Dr. Elston is from Geisinger Medical Center, Danville, Pennsylvania; Dr. David-Bajar is from Brooke Army Medical Center, San Antonio.

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Bullous systemic lupus erythematosus (BSLE) is a rare subset of systemic lupus erythematosus (SLE) associated with autoimmunity to type VII collagen.1 BSLE is an autoimmune-mediated, chronic, widespread, nonscarring, subepidermal blistering skin disease occurring in patients with SLE. In 23% of patients with SLE, cutaneous involvement is the initial manifestation. Approximately 76% of patients with SLE will have skin changes at some stage during the course of their disease. Among these patients, fewer than 5% will have chronic vesicobullous lesions.2 Generally, patients with BSLE meet the criteria for SLE as defined by the American College of Rheumatology (ACR) and have a widespread vesicobullous eruption that is generally unrelated to the severity of the SLE.3 Some patients have bullous eruptions related to lupus erythematosus (LE) but do not meet ACR criteria for SLE. We present such a patient and discuss the spectrum of bullous disease in patients with LE.


Case Report

A 17-year-old African American adolescent girl presented with a 2-day history of a blistering eruption with an abrupt onset. Physical examination revealed photodistributed tense bullae. Innumerable beadlike vesicles coalescing into larger bullae were noted on her face, with dramatic involvement of her lips and ears (Figures 1 and 2). Larger bullae on urticarial bases were found on her upper torso. Initially, no mucosal involvement was noted; however, within days, the patient developed oral and vaginal erosions. In the preceding 5 months, she had occasionally experienced a few blisters on her face but had otherwise been healthy. The patient was feeling well at the time of presentation and was not taking any medication except for a methylprednisolone dose pack prescribed during her visit to the emergency department the previous evening.

Results of a shave biopsy of an intact bulla revealed a neutrophil-rich subepidermal bulla with neutrophils stuffing the dermal papillae and lined up along the dermal-epidermal junction (DEJ) (Figure 3).

There was no leukocytoclastic vasculitis and no eosinophils were noted. Results of direct immunofluorescence (DIF) revealed IgG 4+ granular/continuous granular staining at the DEJ, trace IgM with 1+ staining of colloid bodies at the DEJ, 2+ granular/continuous granular C3 staining at the DEJ, and 3+ granular/continuous granular C1q staining at the DEJ (Figure 4).

The specimen was negative for IgA. Laboratory investigation revealed an antinuclear antibody of 1:160; anti-DNA of 1:265 (negative is <200); and negative ribonuclear protein antigen, Smith antigen, Sjögren syndrome A and B antigens, and lupus anticoagulant and anticardiolipin antibodies. Results of complete blood cell count (CBC), blood chemistry, and urinalysis were within reference range. No type VII collagen antibodies were found.

Treatment with oral steroids had begun prior to the patient presenting to dermatology, and no improvement was noted during a 1-week period. In anticipation of starting dapsone, a glucose-6-phosphate dehydrogenase level was ordered, and colchicine was begun at a dose of 0.6 mg 2 times a day. The bullous lesions showed some response within 2 days. The patient was subsequently switched to dapsone; however, colchicine was reinstated after she developed symptoms consistent with dapsone hypersensitivity, including a diffuse pruritic morbilliform eruption, nausea, and abdominal pain, with elevated liver enzyme levels—aspartate aminotransferase was 304 U/L (reference range, 0—37 U/L) and alanine aminotransferase was 360 U/L (reference range, 0–40 U/L). The eruption was eventually controlled with 0.6 mg of colchicine 3 times a day and prednisone. After multiple failed attempts to taper prednisone, 400 mg of hydroxychloroquine once a day was added. After 2 months, the patient was able to tolerate the steroid taper without a rebound flare of bullous lesions.



Comment


BSLE typically presents in the second or third decade of life. Patients with BSLE seldom have discoid lesions or annular erythema.4 Lesions may form large blisters on the trunk that resemble the lesions of bullous pemphigoid. Bullous skin lesions also may appear on flexural and extensor surfaces with a preference for sun-exposed areas. Bullae may form on an erythematous base or on normal skin. Some skin lesions present as herpetiform vesicles with clusters of ulcers. Because of the herpetiform grouping and dermatitis herpetiformlike histology, dermatitis herpetiformis should be included in the differential diagnosis, but can easily be ruled out with DIF. Oral manifestations, such as small blisters on the vermilion border of the lips, are seen in approximately 30% of cases.4

Epidermolysis bullosa acquisita (EBA) appears to share a common antigen with BSLE and has been noted in patients with LE.5 The 2 conditions may represent variants of the same condition. EBA typically presents in a patient’s fourth or fifth decade of life, with acrally distributed mechanobullous lesions or widespread inflammatory vesiculobullous lesions appearing like bullous pemphigoid.5 EBA is more likely than BSLE to result in scarring. Furthermore, mechanical skin fragility is not a common feature of BSLE, though it is a feature of EBA. BSLE lesions generally last for many weeks to months, can undergo remissions and exacerbations, and respond favorably to treatment with dapsone. Conversely, EBA often lasts for many years and is frequently treatment resistant.

Some patients with LE and bullous lesions do not meet ACR criteria for either BSLE or EBA. Our patient had serologic evidence of connective tissue disease, as well as DIF findings typical for LE. Her clinical lesions and response to treatment were similar to that of BSLE. These findings suggest that her condition represents part of a spectrum of connective tissue disease-related bullous dermatosis.

The underlying pathophysiology of BSLE and EBA relates to the structure of the DEJ. Anchoring complexes, which are specialized focal attachment sites within the DEJ, are structurally weakened by the binding of autoantibodies to its components.6 The components of the anchoring complexes, which contain type VII collagen, react with the autoantibodies in BSLE, compromising the integrity of the DEJ. This may lead to the formation of subepidermal blisters.6

The criteria for the diagnosis of BSLE proposed by Camisa and Sharma7 include a diagnosis of SLE based on the criteria of the ACR, vesicles, and bullae located on but not limited to sun-exposed skin; histopathologic findings similar to dermatitis herpetiformis; and deposition of IgG and/or IgM and often IgA at the basement membrane zone by DIF. Gammon and Briggaman5 classified BSLE into 2 distinct subtypes: patients with circulating antibodies to type VII collagen are designated as cases of BSLE-1, while patients designated as cases of BSLE-2 do not have these antibodies.

Some authors have suggested the current classification of BSLE be revised because some patients have autoantibodies bound to the epidermal side of 1 mol/L NaCl-split skin, which indicates involvement of DEJ components other than type VII collagen in BSLE.2,8 Patients also may test falsely negative for antibodies to type VII collagen, possibly because of degradation of the antibody during shipping or because they may possess antibodies to a different antigen. Failure to detect antibodies to type VII collagen does not rule out the possibility of BSLE, but data suggest that patients with lupus and bullous disease may represent a spectrum of related immunobullous disorders.

Histologically, the vesiculobullous eruption is typically characterized by dermal-epidermal separation with neutrophil-predominant inflammation in the upper dermis.7 In cases where the infiltrate concentrates in the dermal papillae as papillary microabscesses, the histologic picture is suggestive of dermatitis herpetiformis.4 Eosinophils also may be present, but are fewer in number. DIF studies characteristically show deposition of IgG, C3, IgA, and IgM at the DEJ in 2 types of patterns—granular and continuous granular—with an occasional mixed configuration.4 Circulating IgG antibodies to the DEJ have been detected in some, but not all, patients.

Ultrastructurally, electron microscopy localizes the blisters in the lamina densa region in most cases. Immunoelectron microscopic examination identified the deposition of the anti-DEJ antibodies on and beneath the lamina densa as in EBA, not in the lamina lucida as in bullous pemphigoid.4 These autoantibodies typically recognized the 290-kd and 145-kd antigens at the DEJ, with type VII collagen as the target. IgG autoantibodies to type VII collagen are believed to be pathogenic and contribute to the separation and blister formation both in BSLE and EBA.4 The production of these autoantibodies is regulated by the class II major histocompatibility complex.4

Unlike patients with EBA, most patients with BSLE respond dramatically to dapsone.5 Although dapsone has both antibiotic and anti-inflammatory properties, the anti-inflammatory mechanisms mediate the therapeutic effect in BSLE. Dapsone directly impairs the myeloperoxidase-hydrogen peroxide-halide system of polymorphonuclear neutrophils (PMNs), which prevents generation of proinflammatory oxygen intermediates caused by activation of neutrophils. Inhibition of PMN chemotaxis and mitogen-stimulated transformation of lymphocytes is another mechanism by which dapsone interferes with inflammation.9 Furthermore, dapsone prevents cyclooxygenase-mediated production of prostaglandin E2, further decreasing inflammation.

Patients with a glucose-6-phosphate dehydrogenase deficiency may experience severe hemolysis when taking dapsone; therefore, patients should be screened for this trait. Additionally, a baseline CBC and liver function test should be obtained and repeated weekly during the initial treatment period since dose-dependent hemolysis is the most common side effect of dapsone.10 Most patients will develop a 1- to 2-g drop in hemoglobin levels after initiation of treatment, which may be partially ameliorated by the concomitant use of 400 IU of vitamin E once a day.10 Other adverse reactions include methemoglobinemia, motor neuropathy, exfoliative dermatitis, hepatitis, headache, gastrointestinal upset, and rarely agranulocytosis.10 Dapsone also may induce a hypersensitivity syndrome with findings similar to those of infectious mononucleosis.9 The syndrome generally begins 4 to 6 weeks after initiation of treatment. Morbilliform eruptions with pruritus, fever, malaise, hepatitis, elevated erythrocyte sedimentation rate, lymphadenopathy, and lymphocytosis are common signs and symptoms associated with this syndrome.9 Immediate discontinuation of dapsone is recommended if symptoms arise. A good response to dapsone in the clearing of vesiculobullous lesions correlates with a better prognosis in BSLE; however, discontinuation of dapsone may allow new lesions to develop.4

Colchicine is a therapeutic option for treatment of neutrophil-mediated bullous diseases. Colchicine is known to interfere with PMN chemotaxis and the release of lysozymal enzymes by PMNs.11 Our patient achieved resolution of lesions with 0.6 mg of colchicine 3 times a day. Administered in low doses, colchicine has relatively few side effects. The most common are transient diarrhea and abdominal discomfort11; therefore, the dose requires titration to tolerance of these side effects. Other side effects of colchicine, such as neuropathy and bone marrow depression, are rare with low-dose therapy.11

Bullous lesions in patients with LE often fail to respond to treatment with systemic corticosteroids alone, and long-term corticosteroid treatment is associated with adverse metabolic effects and bone demineralization. To limit corticosteroid toxicity, adjuvant therapy with azathioprine, antimalarials, and cyclophosphamide have been reported to be useful in cases unresponsive or intolerant to dapsone.12,13 Patients initiating steroid therapy should receive a baseline weight and blood pressure measures, as well as an ophthalmologic examination. Pretreatment laboratory studies should include tests for CBC, electrolyte count, calcium level, alkaline phosphatase level, creatinine level, human immunodeficiency virus, tuberculosis, and bone densitometry. Weight, blood pressure, and blood glucose should be followed monthly until a response is established. The side effects of prolonged therapy with systemic steroids include: psychiatric disorders, sleep disturbances, cataracts, gastrointestinal upset, weight gain, peptic ulcer disease, hypertension, atherosclerosis, infection, growth failure, suppression of the hypothalmic-pituitary-adrenal axis, secondary amenorrhea, hyperglycemia, glucose intolerance, inhibition of wound healing, subcutaneous atrophy, acne, hirsutism, osteoporosis, and aseptic necrosis of bone.10 The initiation of bisphosphonate therapy when corticosteroid therapy is begun will prevent a significant loss of bone mineral density. Bisphosphonate therapy also can improve bone mineral density in patients with established bone loss due to corticosteroid therapy.

Prystowsky et al14 reported successful use of azathioprine to treat BSLE. By metabolizing to 6-thioguanine, azathioprine is incorporated into DNA yielding strand breaks secondary to blockage of DNA synthesis. Because azathioprine is metabolized by thiopurine methyltransferase, patients should be screened for activity of this enzyme prior to initiation of therapy.10,15 Individuals who are homozygous for the allele conferring low activity of this enzyme (0.3%) are at risk for profound myelosuppression with azathioprine. More commonly, patients have high levels of the enzyme and are at risk for undertreatment of their disease with inadequate doses. Long-term risks of azathioprine therapy include an increased incidence of malignancy such as lymphoma, leukemia, and squamous cell carcinoma. The prognosis in patients with SLE and bullous lesions is determined largely by the visceral manifestations of the SLE,5 yet the activity of the systemic and skin disease may not be linked.3,5 Our patient presented with immunobullous disease and serologic evidence of connective tissue disease. Her DIF finding was characteristic of LE. This case adds further evidence that there is a spectrum of related bullous disorders in patients with connective tissue disease.

Bullous systemic lupus erythematosus (BSLE) is a rare subset of systemic lupus erythematosus (SLE) associated with autoimmunity to type VII collagen.1 BSLE is an autoimmune-mediated, chronic, widespread, nonscarring, subepidermal blistering skin disease occurring in patients with SLE. In 23% of patients with SLE, cutaneous involvement is the initial manifestation. Approximately 76% of patients with SLE will have skin changes at some stage during the course of their disease. Among these patients, fewer than 5% will have chronic vesicobullous lesions.2 Generally, patients with BSLE meet the criteria for SLE as defined by the American College of Rheumatology (ACR) and have a widespread vesicobullous eruption that is generally unrelated to the severity of the SLE.3 Some patients have bullous eruptions related to lupus erythematosus (LE) but do not meet ACR criteria for SLE. We present such a patient and discuss the spectrum of bullous disease in patients with LE.


Case Report

A 17-year-old African American adolescent girl presented with a 2-day history of a blistering eruption with an abrupt onset. Physical examination revealed photodistributed tense bullae. Innumerable beadlike vesicles coalescing into larger bullae were noted on her face, with dramatic involvement of her lips and ears (Figures 1 and 2). Larger bullae on urticarial bases were found on her upper torso. Initially, no mucosal involvement was noted; however, within days, the patient developed oral and vaginal erosions. In the preceding 5 months, she had occasionally experienced a few blisters on her face but had otherwise been healthy. The patient was feeling well at the time of presentation and was not taking any medication except for a methylprednisolone dose pack prescribed during her visit to the emergency department the previous evening.

Results of a shave biopsy of an intact bulla revealed a neutrophil-rich subepidermal bulla with neutrophils stuffing the dermal papillae and lined up along the dermal-epidermal junction (DEJ) (Figure 3).

There was no leukocytoclastic vasculitis and no eosinophils were noted. Results of direct immunofluorescence (DIF) revealed IgG 4+ granular/continuous granular staining at the DEJ, trace IgM with 1+ staining of colloid bodies at the DEJ, 2+ granular/continuous granular C3 staining at the DEJ, and 3+ granular/continuous granular C1q staining at the DEJ (Figure 4).

The specimen was negative for IgA. Laboratory investigation revealed an antinuclear antibody of 1:160; anti-DNA of 1:265 (negative is <200); and negative ribonuclear protein antigen, Smith antigen, Sjögren syndrome A and B antigens, and lupus anticoagulant and anticardiolipin antibodies. Results of complete blood cell count (CBC), blood chemistry, and urinalysis were within reference range. No type VII collagen antibodies were found.

Treatment with oral steroids had begun prior to the patient presenting to dermatology, and no improvement was noted during a 1-week period. In anticipation of starting dapsone, a glucose-6-phosphate dehydrogenase level was ordered, and colchicine was begun at a dose of 0.6 mg 2 times a day. The bullous lesions showed some response within 2 days. The patient was subsequently switched to dapsone; however, colchicine was reinstated after she developed symptoms consistent with dapsone hypersensitivity, including a diffuse pruritic morbilliform eruption, nausea, and abdominal pain, with elevated liver enzyme levels—aspartate aminotransferase was 304 U/L (reference range, 0—37 U/L) and alanine aminotransferase was 360 U/L (reference range, 0–40 U/L). The eruption was eventually controlled with 0.6 mg of colchicine 3 times a day and prednisone. After multiple failed attempts to taper prednisone, 400 mg of hydroxychloroquine once a day was added. After 2 months, the patient was able to tolerate the steroid taper without a rebound flare of bullous lesions.



Comment


BSLE typically presents in the second or third decade of life. Patients with BSLE seldom have discoid lesions or annular erythema.4 Lesions may form large blisters on the trunk that resemble the lesions of bullous pemphigoid. Bullous skin lesions also may appear on flexural and extensor surfaces with a preference for sun-exposed areas. Bullae may form on an erythematous base or on normal skin. Some skin lesions present as herpetiform vesicles with clusters of ulcers. Because of the herpetiform grouping and dermatitis herpetiformlike histology, dermatitis herpetiformis should be included in the differential diagnosis, but can easily be ruled out with DIF. Oral manifestations, such as small blisters on the vermilion border of the lips, are seen in approximately 30% of cases.4

Epidermolysis bullosa acquisita (EBA) appears to share a common antigen with BSLE and has been noted in patients with LE.5 The 2 conditions may represent variants of the same condition. EBA typically presents in a patient’s fourth or fifth decade of life, with acrally distributed mechanobullous lesions or widespread inflammatory vesiculobullous lesions appearing like bullous pemphigoid.5 EBA is more likely than BSLE to result in scarring. Furthermore, mechanical skin fragility is not a common feature of BSLE, though it is a feature of EBA. BSLE lesions generally last for many weeks to months, can undergo remissions and exacerbations, and respond favorably to treatment with dapsone. Conversely, EBA often lasts for many years and is frequently treatment resistant.

Some patients with LE and bullous lesions do not meet ACR criteria for either BSLE or EBA. Our patient had serologic evidence of connective tissue disease, as well as DIF findings typical for LE. Her clinical lesions and response to treatment were similar to that of BSLE. These findings suggest that her condition represents part of a spectrum of connective tissue disease-related bullous dermatosis.

The underlying pathophysiology of BSLE and EBA relates to the structure of the DEJ. Anchoring complexes, which are specialized focal attachment sites within the DEJ, are structurally weakened by the binding of autoantibodies to its components.6 The components of the anchoring complexes, which contain type VII collagen, react with the autoantibodies in BSLE, compromising the integrity of the DEJ. This may lead to the formation of subepidermal blisters.6

The criteria for the diagnosis of BSLE proposed by Camisa and Sharma7 include a diagnosis of SLE based on the criteria of the ACR, vesicles, and bullae located on but not limited to sun-exposed skin; histopathologic findings similar to dermatitis herpetiformis; and deposition of IgG and/or IgM and often IgA at the basement membrane zone by DIF. Gammon and Briggaman5 classified BSLE into 2 distinct subtypes: patients with circulating antibodies to type VII collagen are designated as cases of BSLE-1, while patients designated as cases of BSLE-2 do not have these antibodies.

Some authors have suggested the current classification of BSLE be revised because some patients have autoantibodies bound to the epidermal side of 1 mol/L NaCl-split skin, which indicates involvement of DEJ components other than type VII collagen in BSLE.2,8 Patients also may test falsely negative for antibodies to type VII collagen, possibly because of degradation of the antibody during shipping or because they may possess antibodies to a different antigen. Failure to detect antibodies to type VII collagen does not rule out the possibility of BSLE, but data suggest that patients with lupus and bullous disease may represent a spectrum of related immunobullous disorders.

Histologically, the vesiculobullous eruption is typically characterized by dermal-epidermal separation with neutrophil-predominant inflammation in the upper dermis.7 In cases where the infiltrate concentrates in the dermal papillae as papillary microabscesses, the histologic picture is suggestive of dermatitis herpetiformis.4 Eosinophils also may be present, but are fewer in number. DIF studies characteristically show deposition of IgG, C3, IgA, and IgM at the DEJ in 2 types of patterns—granular and continuous granular—with an occasional mixed configuration.4 Circulating IgG antibodies to the DEJ have been detected in some, but not all, patients.

Ultrastructurally, electron microscopy localizes the blisters in the lamina densa region in most cases. Immunoelectron microscopic examination identified the deposition of the anti-DEJ antibodies on and beneath the lamina densa as in EBA, not in the lamina lucida as in bullous pemphigoid.4 These autoantibodies typically recognized the 290-kd and 145-kd antigens at the DEJ, with type VII collagen as the target. IgG autoantibodies to type VII collagen are believed to be pathogenic and contribute to the separation and blister formation both in BSLE and EBA.4 The production of these autoantibodies is regulated by the class II major histocompatibility complex.4

Unlike patients with EBA, most patients with BSLE respond dramatically to dapsone.5 Although dapsone has both antibiotic and anti-inflammatory properties, the anti-inflammatory mechanisms mediate the therapeutic effect in BSLE. Dapsone directly impairs the myeloperoxidase-hydrogen peroxide-halide system of polymorphonuclear neutrophils (PMNs), which prevents generation of proinflammatory oxygen intermediates caused by activation of neutrophils. Inhibition of PMN chemotaxis and mitogen-stimulated transformation of lymphocytes is another mechanism by which dapsone interferes with inflammation.9 Furthermore, dapsone prevents cyclooxygenase-mediated production of prostaglandin E2, further decreasing inflammation.

Patients with a glucose-6-phosphate dehydrogenase deficiency may experience severe hemolysis when taking dapsone; therefore, patients should be screened for this trait. Additionally, a baseline CBC and liver function test should be obtained and repeated weekly during the initial treatment period since dose-dependent hemolysis is the most common side effect of dapsone.10 Most patients will develop a 1- to 2-g drop in hemoglobin levels after initiation of treatment, which may be partially ameliorated by the concomitant use of 400 IU of vitamin E once a day.10 Other adverse reactions include methemoglobinemia, motor neuropathy, exfoliative dermatitis, hepatitis, headache, gastrointestinal upset, and rarely agranulocytosis.10 Dapsone also may induce a hypersensitivity syndrome with findings similar to those of infectious mononucleosis.9 The syndrome generally begins 4 to 6 weeks after initiation of treatment. Morbilliform eruptions with pruritus, fever, malaise, hepatitis, elevated erythrocyte sedimentation rate, lymphadenopathy, and lymphocytosis are common signs and symptoms associated with this syndrome.9 Immediate discontinuation of dapsone is recommended if symptoms arise. A good response to dapsone in the clearing of vesiculobullous lesions correlates with a better prognosis in BSLE; however, discontinuation of dapsone may allow new lesions to develop.4

Colchicine is a therapeutic option for treatment of neutrophil-mediated bullous diseases. Colchicine is known to interfere with PMN chemotaxis and the release of lysozymal enzymes by PMNs.11 Our patient achieved resolution of lesions with 0.6 mg of colchicine 3 times a day. Administered in low doses, colchicine has relatively few side effects. The most common are transient diarrhea and abdominal discomfort11; therefore, the dose requires titration to tolerance of these side effects. Other side effects of colchicine, such as neuropathy and bone marrow depression, are rare with low-dose therapy.11

Bullous lesions in patients with LE often fail to respond to treatment with systemic corticosteroids alone, and long-term corticosteroid treatment is associated with adverse metabolic effects and bone demineralization. To limit corticosteroid toxicity, adjuvant therapy with azathioprine, antimalarials, and cyclophosphamide have been reported to be useful in cases unresponsive or intolerant to dapsone.12,13 Patients initiating steroid therapy should receive a baseline weight and blood pressure measures, as well as an ophthalmologic examination. Pretreatment laboratory studies should include tests for CBC, electrolyte count, calcium level, alkaline phosphatase level, creatinine level, human immunodeficiency virus, tuberculosis, and bone densitometry. Weight, blood pressure, and blood glucose should be followed monthly until a response is established. The side effects of prolonged therapy with systemic steroids include: psychiatric disorders, sleep disturbances, cataracts, gastrointestinal upset, weight gain, peptic ulcer disease, hypertension, atherosclerosis, infection, growth failure, suppression of the hypothalmic-pituitary-adrenal axis, secondary amenorrhea, hyperglycemia, glucose intolerance, inhibition of wound healing, subcutaneous atrophy, acne, hirsutism, osteoporosis, and aseptic necrosis of bone.10 The initiation of bisphosphonate therapy when corticosteroid therapy is begun will prevent a significant loss of bone mineral density. Bisphosphonate therapy also can improve bone mineral density in patients with established bone loss due to corticosteroid therapy.

Prystowsky et al14 reported successful use of azathioprine to treat BSLE. By metabolizing to 6-thioguanine, azathioprine is incorporated into DNA yielding strand breaks secondary to blockage of DNA synthesis. Because azathioprine is metabolized by thiopurine methyltransferase, patients should be screened for activity of this enzyme prior to initiation of therapy.10,15 Individuals who are homozygous for the allele conferring low activity of this enzyme (0.3%) are at risk for profound myelosuppression with azathioprine. More commonly, patients have high levels of the enzyme and are at risk for undertreatment of their disease with inadequate doses. Long-term risks of azathioprine therapy include an increased incidence of malignancy such as lymphoma, leukemia, and squamous cell carcinoma. The prognosis in patients with SLE and bullous lesions is determined largely by the visceral manifestations of the SLE,5 yet the activity of the systemic and skin disease may not be linked.3,5 Our patient presented with immunobullous disease and serologic evidence of connective tissue disease. Her DIF finding was characteristic of LE. This case adds further evidence that there is a spectrum of related bullous disorders in patients with connective tissue disease.

References

 

  1. Fujii K, Fujimoto W, Ueda M, et al. Detection of anti-type VII collagen antibody in Sjögren's syndrome/lupus erythematosus overlap syndrome with transient bullous systemic lupus erythematosus. Br J Dermatol. 1998;139:302-306.
  2. Yell JA, Allen J, Wojnarowska F, et al. Bullous systemic lupus erythematosus: revised criteria for diagnosis. Br J Dermatol. 1995;132:921-928.
  3. Cotell S, Robinson N, Lawrence C. Autoimmune blistering skin diseases. Am J Emerg Med. 2000;18:288-299.
  4. Weinberg MA, Insler MS, Campen RB. Mucocutaneous feature of autoimmune blistering diseases. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 1997;84:517-534.
  5. Gammon WR, Briggaman RA. Epidermolysis bullosa acquisita and bullous systemic lupus erythematosus diseases of autoimmunity to type VII collagen. Dermatol Clin. 1993;11:535-547.
  6. Schmidt E, Zillikens D. Autoimmune and inherited subepidermal blistering diseases: advances in the clinic and the laboratory. Adv Dermatol. 2000;16:113-157.
  7. Camisa C, Sharma HM. Vesicobullous systems lupus erythematosus. report of two cases and review of the literature. J Am Acad Dermatol. 1983;9:924-933.
  8. Chan LS, Lapiere JC, Chen M, et al. Bullous systemic lupus erythematosus with autoantibodies recognizing multiple skin basement membrane components, bullous pemphigoid antigen 1, laminin-5, laminin-6, and type VII collagen. Arch Dermatol. 1999;135:569-573.
  9. Paniker U, Levine N. Dapsone and sulfapyridine. Dermatol Clin. 2001;19:79-86.
  10. Gleid M, Rico J. Treatment of autoimmune blistering diseases. Dermatol Clin. 1999;17:431-440.
  11. Cunningham B, Kirchmann T, Woodley D. Colchicine for epidermolysis bullosa acquisita. J Am Acad Dermatol. 1996;34:781-784.
  12. Mascaro JM, Herrero C, Hausmann G. Uncommon cutaneous manifestations of lupus erythematosus. Lupus. 1997;6:122-131.
  13. Yung A, Oakley A. Bullous systemic lupus erythematosus. Australas J Dermatol. 2000;41:234-237.
  14. Prystowsky JH, Finkel L, Tar L, et al. Bullous eruption in a woman with lupus erythematosus. Arch Dermatol. 1988;124:571, 574-575.
  15. Korman N. New and emerging therapies in the treatment of blistering diseases. Dermatol Clin. 2000;18:127-137.
  16. Pedro SD, Dahl MC. Direct immunofluorescence of bullous systemic lupus erythematosus. Arch Dermatol. 1973;107:118-120.
References

 

  1. Fujii K, Fujimoto W, Ueda M, et al. Detection of anti-type VII collagen antibody in Sjögren's syndrome/lupus erythematosus overlap syndrome with transient bullous systemic lupus erythematosus. Br J Dermatol. 1998;139:302-306.
  2. Yell JA, Allen J, Wojnarowska F, et al. Bullous systemic lupus erythematosus: revised criteria for diagnosis. Br J Dermatol. 1995;132:921-928.
  3. Cotell S, Robinson N, Lawrence C. Autoimmune blistering skin diseases. Am J Emerg Med. 2000;18:288-299.
  4. Weinberg MA, Insler MS, Campen RB. Mucocutaneous feature of autoimmune blistering diseases. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 1997;84:517-534.
  5. Gammon WR, Briggaman RA. Epidermolysis bullosa acquisita and bullous systemic lupus erythematosus diseases of autoimmunity to type VII collagen. Dermatol Clin. 1993;11:535-547.
  6. Schmidt E, Zillikens D. Autoimmune and inherited subepidermal blistering diseases: advances in the clinic and the laboratory. Adv Dermatol. 2000;16:113-157.
  7. Camisa C, Sharma HM. Vesicobullous systems lupus erythematosus. report of two cases and review of the literature. J Am Acad Dermatol. 1983;9:924-933.
  8. Chan LS, Lapiere JC, Chen M, et al. Bullous systemic lupus erythematosus with autoantibodies recognizing multiple skin basement membrane components, bullous pemphigoid antigen 1, laminin-5, laminin-6, and type VII collagen. Arch Dermatol. 1999;135:569-573.
  9. Paniker U, Levine N. Dapsone and sulfapyridine. Dermatol Clin. 2001;19:79-86.
  10. Gleid M, Rico J. Treatment of autoimmune blistering diseases. Dermatol Clin. 1999;17:431-440.
  11. Cunningham B, Kirchmann T, Woodley D. Colchicine for epidermolysis bullosa acquisita. J Am Acad Dermatol. 1996;34:781-784.
  12. Mascaro JM, Herrero C, Hausmann G. Uncommon cutaneous manifestations of lupus erythematosus. Lupus. 1997;6:122-131.
  13. Yung A, Oakley A. Bullous systemic lupus erythematosus. Australas J Dermatol. 2000;41:234-237.
  14. Prystowsky JH, Finkel L, Tar L, et al. Bullous eruption in a woman with lupus erythematosus. Arch Dermatol. 1988;124:571, 574-575.
  15. Korman N. New and emerging therapies in the treatment of blistering diseases. Dermatol Clin. 2000;18:127-137.
  16. Pedro SD, Dahl MC. Direct immunofluorescence of bullous systemic lupus erythematosus. Arch Dermatol. 1973;107:118-120.
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