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It has been 40 years since the first reported case of IgE-mediated natural rubber latex allergy, which was soon followed by a global epidemic of allergic and anaphylactic reactions.1,2 Resolution came through insightful work in the 1990s that led to the removal of cornstarch powder and a switch to nonpowdered latex and synthetic examination gloves.2 Also discovered during this period was the cross-reactivity of many patients to latex and various fruits.
Research substantiates reports
Blanco et al. conducted a prospective study in their outpatient clinic in 25 patients diagnosed with latex allergy, published in 1994.They used a clinical questionnaire, skin-prick tests, skin test with a latex extract, and identification of total and specific IgE to help ascertain clinical characteristics and cross-reactivity. Of the 23 women and 2 men in the study (mean age 33, plus or minus 9 years), 9 (36%) experienced latex-induced reactions characterized by systemic anaphylaxis. In 13 patients (52%), 42 food allergies were identified, and 23 included systemic anaphylaxis. Avocado (9), chestnut (9), banana (7), kiwi (5), and papaya (3) were the most common foods to cause hypersensitivities. The researchers concluded that their small study supported the reality of a “latex-fruit syndrome.”3
Another study aimed to characterize the cross-reactivity of latex and foods and evaluate clinical significance. Beezhold et al. examined 47 patients allergic to latex and 46 nonallergic controls. The investigators found immunologic reactivity to foods to be prevalent (33 latex-allergic patients and seven controls), with 27% of food skin-prick tests positive in the latex-allergic group. In addition, clinical symptoms were linked to 27% of positive skin-prick tests. Among the 17 patients who displayed clinical allergies to at least one food, 14 showed local sensitivity reactions, with anaphylaxis noted in 11. Avocado (53%), potato (40%), banana (38%), tomato (28%), chestnut (28%), and kiwi (17%) were the foods most frequently cited for provoking a skin test reaction. The authors observed extensive cross-reactivity between latex sensitivity and particular foods, with potatoes and tomatoes reported for the first time.4
In 1997, Brehler et al. studied serum samples from 136 patients whose immediate hypersensitivity to latex proteins was clinically observable and documented. The samples were assessed for IgE antibodies against several fruits, with fruit-specific IgE antibodies recorded in 69.1%. Radioallergosorbent (RAST) -inhibition tests yielded the recognition of cross-reacting IgE antibodies in latex and multiple fruit allergens: avocado, banana, chestnut, fig, kiwi, mango, melon, papaya, passion fruit, peach, pineapple, and tomato. The investigators recorded 112 intolerance reactions and noted that 42.5% of their patients reported allergic symptoms after consuming these fruits. Fruit-specific IgE antibodies were detected in only 32.1% of these patients, suggesting to the researchers that serologic tests were suboptimal in forecasting food hypersensitivities in patients who are allergic to latex.5
Cross-reactivity with banana
Mäkinen-Kiljunen studied 47 patients to investigate banana allergy in patients with latex allergy in 1994, measuring latex-, banana-, and pollen-specific (birch, timothy, and mugwort) IgE. Thirty-one patients were also given skin-prick tests with banana and were queried about reactions after consuming bananas. Of the 47 sera samples, latex RAST results were positive in 31 and banana RAST results in 26. RAST results from latex and banana were correlated (25 of the 31 latex RAST-positive samples were also banana RAST-positive), but not with pollen. Sixteen of the 31 patients who ate banana reported symptoms, and 11 of the 31 patients given the banana skin-prick test showed positive results. The author confirmed the cross-reactivity of IgE antibodies for latex and banana, identifying for the first time a structurally similar antigen/allergen as at least one antigen from banana fused with an antigen from latex in crossed-line immunoelectrophoresis.6
In 1998, Mikkola et al. investigated whether proteins similar to hevein, a major natural rubber latex allergen, are present in banana and account for cross-reactivity between these botanicals. Immunoblotting revealed that 9 of 15 sera from latex-allergic patients with IgE to hevein also bound to 32- and 33-kd banana proteins. Studies using ELISA [enzyme-linked immunosorbent assay] showed that the common presentation of hypersensitivity to banana among patients allergic to latex could be attributed to cross-reacting IgE antibodies binding to epitopes in hevein and in the then-newly identified hevein-like endochitinase found in banana.7
Cross-reactivity with avocado
In response to reports of an association between allergy to natural rubber latex and avocado, Ahlroth et al. investigated cross-reactive proteins between natural rubber latex and avocado in 1995 by using skin-prick tests with fresh avocado on 11 patients and the sera of 18 patients with known latex allergy for IgE antibodies. Fourteen of the 18 sera were found to have IgE antibodies binding to 17 distinct avocado proteins, with multiple immunoblot experiments and skin-prick test results (positive in 7 of 11 patients) revealing marked immunologic cross-reactivity between latex and avocado.8
In 1998, Chen et al. set out to identify the cross-sensitizing allergen between latex and avocado, with hevein suspected. The researchers looked at sera samples from 118 health care workers allergic to latex and 78 patients with spina bifida who were allergic to latex. They noted a robust correlation between the prevalence of seropositive IgE antibodies to avocado in the presence of hevein-specific IgE antibodies in both groups. All members in the spina bifida group and 91 (73%) of the health care workers had positive IgE antibodies to hevein and high IgE values to avocado. Additional results supported the conclusion that sensitization to avocado in the majority of people allergic to latex is engendered by IgE-binding epitopes found in hevein.9
A year later, Diaz-Perales et al. considered the potential relevance of chitinases and complex glycans as factors in the then newly described latex/food syndrome, particularly in avocado, banana, and chestnuts. The investigators culled extracts from 20 various plant foods as well as latex. In immunoblot inhibition assays, the primary allergen and class I chitinase in avocado, Prs a 1, and the latex extract potently or completely blocked IgE binding by these constituents. Polyclonal antibodies to chitinases and sera from patients with latex/fruit allergy responded to reactive proteins of about 30-45 kd (putative class I chitinases) in chestnut, cherimoya, kiwi, mango, papaya, passion fruit, tomato, and wheat flour extracts. The glycans complex was deemed to be irrelevant in latex/fruit cross-reactivity, but the researchers found the putative class I chitinases to be notable players in the latex/fruit syndrome.10
According to Wagner and Breitender, anywhere from 30%-50% of people with known latex allergy also evince a related hypersensitivity or allergy to various plant-derived foods, with avocado, banana, chestnut, kiwi, peach, tomato, potato, and bell pepper among the foods most frequently linked to latex/fruit syndrome. They summarize that several plant defense proteins have been shown to be involved in the syndrome, with the most prominent, class I chitinases with an N-terminal hevein-like domain, having been found to cross-react with hevein (Hev b 6.02), a major IgE-binding allergen for individuals allergic to latex. A beta-1,3-glucanase, a key latex allergen, has also shown cross-reactivity with proteins of bell pepper, and another significant latex allergen, Hev b 7, a patatin-like protein, cross-reacts with its analogous protein in potato.11
Conclusion
It is unknown whether latex allergy precedes or follows food allergy.11 The latex/food syndrome itself merits attention as a significant source of hypersensitivity to natural cosmeceutical ingredients. Dermatologists should be aware of the lengthy list of cross-reacting plant-derived products, particularly when it comes to reviewing topical product ingredients with susceptible or allergic patients. Latex-allergic patients may react to these natural ingredients in food or when topically applied to the skin.
Dr. Baumann is a private practice dermatologist, researcher, author, and entrepreneur who practices in Miami. She founded the Cosmetic Dermatology Center at the University of Miami in 1997. Dr. Baumann wrote two textbooks: “Cosmetic Dermatology: Principles and Practice” (New York: McGraw-Hill, 2002), and “Cosmeceuticals and Cosmetic Ingredients” (New York: McGraw-Hill, 2014), and a New York Times Best Sellers book for consumers, “The Skin Type Solution” (New York: Bantam Dell, 2006). Dr. Baumann has received funding for advisory boards and/or clinical research trials from Allergan, Evolus, Galderma, and Revance. She is the founder and CEO of Skin Type Solutions Franchise Systems LLC. Write to her at [email protected].
References
1. Nutter AF. Br J Dermatol 1979 Nov;101(5):597-8.
2. Kelly KJ et al. J Allergy Clin Immunol Pract. 2017 Sep-Oct;5(5):1212-16.
3. Blanco C et al. Ann Allergy. 1994 Oct;73(4):309-14.
4. Beezhold DH et al. Clin Exp Allergy. 1996 Apr;26(4):416-22.
5. Brehler R et al. Allergy. 1997 Apr;52(4):404-10.
6. Mäkinen-Kiljunen S. J Allergy Clin Immunol. 1994 Jun;93(6):990-6.
7. Mikkola JH et al. J Allergy Clin Immunol. 1998 Dec;102(6 Pt 1):1005-12.
8. Ahlroth M et al. J Allergy Clin Immunol. 1995 Aug;96(2):167-73.
9. Chen Z et al. J Allergy Clin Immunol. 1998 Sep;102(3):476-81.
10. Diaz-Perales A et al. J Allergy Clin Immunol. 1999 Sep;104(3 Pt 1):681-7.
11. Wagner S et al. Biochem Soc Trans. 2002 Nov;30(Pt 6):935-40.
It has been 40 years since the first reported case of IgE-mediated natural rubber latex allergy, which was soon followed by a global epidemic of allergic and anaphylactic reactions.1,2 Resolution came through insightful work in the 1990s that led to the removal of cornstarch powder and a switch to nonpowdered latex and synthetic examination gloves.2 Also discovered during this period was the cross-reactivity of many patients to latex and various fruits.
Research substantiates reports
Blanco et al. conducted a prospective study in their outpatient clinic in 25 patients diagnosed with latex allergy, published in 1994.They used a clinical questionnaire, skin-prick tests, skin test with a latex extract, and identification of total and specific IgE to help ascertain clinical characteristics and cross-reactivity. Of the 23 women and 2 men in the study (mean age 33, plus or minus 9 years), 9 (36%) experienced latex-induced reactions characterized by systemic anaphylaxis. In 13 patients (52%), 42 food allergies were identified, and 23 included systemic anaphylaxis. Avocado (9), chestnut (9), banana (7), kiwi (5), and papaya (3) were the most common foods to cause hypersensitivities. The researchers concluded that their small study supported the reality of a “latex-fruit syndrome.”3
Another study aimed to characterize the cross-reactivity of latex and foods and evaluate clinical significance. Beezhold et al. examined 47 patients allergic to latex and 46 nonallergic controls. The investigators found immunologic reactivity to foods to be prevalent (33 latex-allergic patients and seven controls), with 27% of food skin-prick tests positive in the latex-allergic group. In addition, clinical symptoms were linked to 27% of positive skin-prick tests. Among the 17 patients who displayed clinical allergies to at least one food, 14 showed local sensitivity reactions, with anaphylaxis noted in 11. Avocado (53%), potato (40%), banana (38%), tomato (28%), chestnut (28%), and kiwi (17%) were the foods most frequently cited for provoking a skin test reaction. The authors observed extensive cross-reactivity between latex sensitivity and particular foods, with potatoes and tomatoes reported for the first time.4
In 1997, Brehler et al. studied serum samples from 136 patients whose immediate hypersensitivity to latex proteins was clinically observable and documented. The samples were assessed for IgE antibodies against several fruits, with fruit-specific IgE antibodies recorded in 69.1%. Radioallergosorbent (RAST) -inhibition tests yielded the recognition of cross-reacting IgE antibodies in latex and multiple fruit allergens: avocado, banana, chestnut, fig, kiwi, mango, melon, papaya, passion fruit, peach, pineapple, and tomato. The investigators recorded 112 intolerance reactions and noted that 42.5% of their patients reported allergic symptoms after consuming these fruits. Fruit-specific IgE antibodies were detected in only 32.1% of these patients, suggesting to the researchers that serologic tests were suboptimal in forecasting food hypersensitivities in patients who are allergic to latex.5
Cross-reactivity with banana
Mäkinen-Kiljunen studied 47 patients to investigate banana allergy in patients with latex allergy in 1994, measuring latex-, banana-, and pollen-specific (birch, timothy, and mugwort) IgE. Thirty-one patients were also given skin-prick tests with banana and were queried about reactions after consuming bananas. Of the 47 sera samples, latex RAST results were positive in 31 and banana RAST results in 26. RAST results from latex and banana were correlated (25 of the 31 latex RAST-positive samples were also banana RAST-positive), but not with pollen. Sixteen of the 31 patients who ate banana reported symptoms, and 11 of the 31 patients given the banana skin-prick test showed positive results. The author confirmed the cross-reactivity of IgE antibodies for latex and banana, identifying for the first time a structurally similar antigen/allergen as at least one antigen from banana fused with an antigen from latex in crossed-line immunoelectrophoresis.6
In 1998, Mikkola et al. investigated whether proteins similar to hevein, a major natural rubber latex allergen, are present in banana and account for cross-reactivity between these botanicals. Immunoblotting revealed that 9 of 15 sera from latex-allergic patients with IgE to hevein also bound to 32- and 33-kd banana proteins. Studies using ELISA [enzyme-linked immunosorbent assay] showed that the common presentation of hypersensitivity to banana among patients allergic to latex could be attributed to cross-reacting IgE antibodies binding to epitopes in hevein and in the then-newly identified hevein-like endochitinase found in banana.7
Cross-reactivity with avocado
In response to reports of an association between allergy to natural rubber latex and avocado, Ahlroth et al. investigated cross-reactive proteins between natural rubber latex and avocado in 1995 by using skin-prick tests with fresh avocado on 11 patients and the sera of 18 patients with known latex allergy for IgE antibodies. Fourteen of the 18 sera were found to have IgE antibodies binding to 17 distinct avocado proteins, with multiple immunoblot experiments and skin-prick test results (positive in 7 of 11 patients) revealing marked immunologic cross-reactivity between latex and avocado.8
In 1998, Chen et al. set out to identify the cross-sensitizing allergen between latex and avocado, with hevein suspected. The researchers looked at sera samples from 118 health care workers allergic to latex and 78 patients with spina bifida who were allergic to latex. They noted a robust correlation between the prevalence of seropositive IgE antibodies to avocado in the presence of hevein-specific IgE antibodies in both groups. All members in the spina bifida group and 91 (73%) of the health care workers had positive IgE antibodies to hevein and high IgE values to avocado. Additional results supported the conclusion that sensitization to avocado in the majority of people allergic to latex is engendered by IgE-binding epitopes found in hevein.9
A year later, Diaz-Perales et al. considered the potential relevance of chitinases and complex glycans as factors in the then newly described latex/food syndrome, particularly in avocado, banana, and chestnuts. The investigators culled extracts from 20 various plant foods as well as latex. In immunoblot inhibition assays, the primary allergen and class I chitinase in avocado, Prs a 1, and the latex extract potently or completely blocked IgE binding by these constituents. Polyclonal antibodies to chitinases and sera from patients with latex/fruit allergy responded to reactive proteins of about 30-45 kd (putative class I chitinases) in chestnut, cherimoya, kiwi, mango, papaya, passion fruit, tomato, and wheat flour extracts. The glycans complex was deemed to be irrelevant in latex/fruit cross-reactivity, but the researchers found the putative class I chitinases to be notable players in the latex/fruit syndrome.10
According to Wagner and Breitender, anywhere from 30%-50% of people with known latex allergy also evince a related hypersensitivity or allergy to various plant-derived foods, with avocado, banana, chestnut, kiwi, peach, tomato, potato, and bell pepper among the foods most frequently linked to latex/fruit syndrome. They summarize that several plant defense proteins have been shown to be involved in the syndrome, with the most prominent, class I chitinases with an N-terminal hevein-like domain, having been found to cross-react with hevein (Hev b 6.02), a major IgE-binding allergen for individuals allergic to latex. A beta-1,3-glucanase, a key latex allergen, has also shown cross-reactivity with proteins of bell pepper, and another significant latex allergen, Hev b 7, a patatin-like protein, cross-reacts with its analogous protein in potato.11
Conclusion
It is unknown whether latex allergy precedes or follows food allergy.11 The latex/food syndrome itself merits attention as a significant source of hypersensitivity to natural cosmeceutical ingredients. Dermatologists should be aware of the lengthy list of cross-reacting plant-derived products, particularly when it comes to reviewing topical product ingredients with susceptible or allergic patients. Latex-allergic patients may react to these natural ingredients in food or when topically applied to the skin.
Dr. Baumann is a private practice dermatologist, researcher, author, and entrepreneur who practices in Miami. She founded the Cosmetic Dermatology Center at the University of Miami in 1997. Dr. Baumann wrote two textbooks: “Cosmetic Dermatology: Principles and Practice” (New York: McGraw-Hill, 2002), and “Cosmeceuticals and Cosmetic Ingredients” (New York: McGraw-Hill, 2014), and a New York Times Best Sellers book for consumers, “The Skin Type Solution” (New York: Bantam Dell, 2006). Dr. Baumann has received funding for advisory boards and/or clinical research trials from Allergan, Evolus, Galderma, and Revance. She is the founder and CEO of Skin Type Solutions Franchise Systems LLC. Write to her at [email protected].
References
1. Nutter AF. Br J Dermatol 1979 Nov;101(5):597-8.
2. Kelly KJ et al. J Allergy Clin Immunol Pract. 2017 Sep-Oct;5(5):1212-16.
3. Blanco C et al. Ann Allergy. 1994 Oct;73(4):309-14.
4. Beezhold DH et al. Clin Exp Allergy. 1996 Apr;26(4):416-22.
5. Brehler R et al. Allergy. 1997 Apr;52(4):404-10.
6. Mäkinen-Kiljunen S. J Allergy Clin Immunol. 1994 Jun;93(6):990-6.
7. Mikkola JH et al. J Allergy Clin Immunol. 1998 Dec;102(6 Pt 1):1005-12.
8. Ahlroth M et al. J Allergy Clin Immunol. 1995 Aug;96(2):167-73.
9. Chen Z et al. J Allergy Clin Immunol. 1998 Sep;102(3):476-81.
10. Diaz-Perales A et al. J Allergy Clin Immunol. 1999 Sep;104(3 Pt 1):681-7.
11. Wagner S et al. Biochem Soc Trans. 2002 Nov;30(Pt 6):935-40.
It has been 40 years since the first reported case of IgE-mediated natural rubber latex allergy, which was soon followed by a global epidemic of allergic and anaphylactic reactions.1,2 Resolution came through insightful work in the 1990s that led to the removal of cornstarch powder and a switch to nonpowdered latex and synthetic examination gloves.2 Also discovered during this period was the cross-reactivity of many patients to latex and various fruits.
Research substantiates reports
Blanco et al. conducted a prospective study in their outpatient clinic in 25 patients diagnosed with latex allergy, published in 1994.They used a clinical questionnaire, skin-prick tests, skin test with a latex extract, and identification of total and specific IgE to help ascertain clinical characteristics and cross-reactivity. Of the 23 women and 2 men in the study (mean age 33, plus or minus 9 years), 9 (36%) experienced latex-induced reactions characterized by systemic anaphylaxis. In 13 patients (52%), 42 food allergies were identified, and 23 included systemic anaphylaxis. Avocado (9), chestnut (9), banana (7), kiwi (5), and papaya (3) were the most common foods to cause hypersensitivities. The researchers concluded that their small study supported the reality of a “latex-fruit syndrome.”3
Another study aimed to characterize the cross-reactivity of latex and foods and evaluate clinical significance. Beezhold et al. examined 47 patients allergic to latex and 46 nonallergic controls. The investigators found immunologic reactivity to foods to be prevalent (33 latex-allergic patients and seven controls), with 27% of food skin-prick tests positive in the latex-allergic group. In addition, clinical symptoms were linked to 27% of positive skin-prick tests. Among the 17 patients who displayed clinical allergies to at least one food, 14 showed local sensitivity reactions, with anaphylaxis noted in 11. Avocado (53%), potato (40%), banana (38%), tomato (28%), chestnut (28%), and kiwi (17%) were the foods most frequently cited for provoking a skin test reaction. The authors observed extensive cross-reactivity between latex sensitivity and particular foods, with potatoes and tomatoes reported for the first time.4
In 1997, Brehler et al. studied serum samples from 136 patients whose immediate hypersensitivity to latex proteins was clinically observable and documented. The samples were assessed for IgE antibodies against several fruits, with fruit-specific IgE antibodies recorded in 69.1%. Radioallergosorbent (RAST) -inhibition tests yielded the recognition of cross-reacting IgE antibodies in latex and multiple fruit allergens: avocado, banana, chestnut, fig, kiwi, mango, melon, papaya, passion fruit, peach, pineapple, and tomato. The investigators recorded 112 intolerance reactions and noted that 42.5% of their patients reported allergic symptoms after consuming these fruits. Fruit-specific IgE antibodies were detected in only 32.1% of these patients, suggesting to the researchers that serologic tests were suboptimal in forecasting food hypersensitivities in patients who are allergic to latex.5
Cross-reactivity with banana
Mäkinen-Kiljunen studied 47 patients to investigate banana allergy in patients with latex allergy in 1994, measuring latex-, banana-, and pollen-specific (birch, timothy, and mugwort) IgE. Thirty-one patients were also given skin-prick tests with banana and were queried about reactions after consuming bananas. Of the 47 sera samples, latex RAST results were positive in 31 and banana RAST results in 26. RAST results from latex and banana were correlated (25 of the 31 latex RAST-positive samples were also banana RAST-positive), but not with pollen. Sixteen of the 31 patients who ate banana reported symptoms, and 11 of the 31 patients given the banana skin-prick test showed positive results. The author confirmed the cross-reactivity of IgE antibodies for latex and banana, identifying for the first time a structurally similar antigen/allergen as at least one antigen from banana fused with an antigen from latex in crossed-line immunoelectrophoresis.6
In 1998, Mikkola et al. investigated whether proteins similar to hevein, a major natural rubber latex allergen, are present in banana and account for cross-reactivity between these botanicals. Immunoblotting revealed that 9 of 15 sera from latex-allergic patients with IgE to hevein also bound to 32- and 33-kd banana proteins. Studies using ELISA [enzyme-linked immunosorbent assay] showed that the common presentation of hypersensitivity to banana among patients allergic to latex could be attributed to cross-reacting IgE antibodies binding to epitopes in hevein and in the then-newly identified hevein-like endochitinase found in banana.7
Cross-reactivity with avocado
In response to reports of an association between allergy to natural rubber latex and avocado, Ahlroth et al. investigated cross-reactive proteins between natural rubber latex and avocado in 1995 by using skin-prick tests with fresh avocado on 11 patients and the sera of 18 patients with known latex allergy for IgE antibodies. Fourteen of the 18 sera were found to have IgE antibodies binding to 17 distinct avocado proteins, with multiple immunoblot experiments and skin-prick test results (positive in 7 of 11 patients) revealing marked immunologic cross-reactivity between latex and avocado.8
In 1998, Chen et al. set out to identify the cross-sensitizing allergen between latex and avocado, with hevein suspected. The researchers looked at sera samples from 118 health care workers allergic to latex and 78 patients with spina bifida who were allergic to latex. They noted a robust correlation between the prevalence of seropositive IgE antibodies to avocado in the presence of hevein-specific IgE antibodies in both groups. All members in the spina bifida group and 91 (73%) of the health care workers had positive IgE antibodies to hevein and high IgE values to avocado. Additional results supported the conclusion that sensitization to avocado in the majority of people allergic to latex is engendered by IgE-binding epitopes found in hevein.9
A year later, Diaz-Perales et al. considered the potential relevance of chitinases and complex glycans as factors in the then newly described latex/food syndrome, particularly in avocado, banana, and chestnuts. The investigators culled extracts from 20 various plant foods as well as latex. In immunoblot inhibition assays, the primary allergen and class I chitinase in avocado, Prs a 1, and the latex extract potently or completely blocked IgE binding by these constituents. Polyclonal antibodies to chitinases and sera from patients with latex/fruit allergy responded to reactive proteins of about 30-45 kd (putative class I chitinases) in chestnut, cherimoya, kiwi, mango, papaya, passion fruit, tomato, and wheat flour extracts. The glycans complex was deemed to be irrelevant in latex/fruit cross-reactivity, but the researchers found the putative class I chitinases to be notable players in the latex/fruit syndrome.10
According to Wagner and Breitender, anywhere from 30%-50% of people with known latex allergy also evince a related hypersensitivity or allergy to various plant-derived foods, with avocado, banana, chestnut, kiwi, peach, tomato, potato, and bell pepper among the foods most frequently linked to latex/fruit syndrome. They summarize that several plant defense proteins have been shown to be involved in the syndrome, with the most prominent, class I chitinases with an N-terminal hevein-like domain, having been found to cross-react with hevein (Hev b 6.02), a major IgE-binding allergen for individuals allergic to latex. A beta-1,3-glucanase, a key latex allergen, has also shown cross-reactivity with proteins of bell pepper, and another significant latex allergen, Hev b 7, a patatin-like protein, cross-reacts with its analogous protein in potato.11
Conclusion
It is unknown whether latex allergy precedes or follows food allergy.11 The latex/food syndrome itself merits attention as a significant source of hypersensitivity to natural cosmeceutical ingredients. Dermatologists should be aware of the lengthy list of cross-reacting plant-derived products, particularly when it comes to reviewing topical product ingredients with susceptible or allergic patients. Latex-allergic patients may react to these natural ingredients in food or when topically applied to the skin.
Dr. Baumann is a private practice dermatologist, researcher, author, and entrepreneur who practices in Miami. She founded the Cosmetic Dermatology Center at the University of Miami in 1997. Dr. Baumann wrote two textbooks: “Cosmetic Dermatology: Principles and Practice” (New York: McGraw-Hill, 2002), and “Cosmeceuticals and Cosmetic Ingredients” (New York: McGraw-Hill, 2014), and a New York Times Best Sellers book for consumers, “The Skin Type Solution” (New York: Bantam Dell, 2006). Dr. Baumann has received funding for advisory boards and/or clinical research trials from Allergan, Evolus, Galderma, and Revance. She is the founder and CEO of Skin Type Solutions Franchise Systems LLC. Write to her at [email protected].
References
1. Nutter AF. Br J Dermatol 1979 Nov;101(5):597-8.
2. Kelly KJ et al. J Allergy Clin Immunol Pract. 2017 Sep-Oct;5(5):1212-16.
3. Blanco C et al. Ann Allergy. 1994 Oct;73(4):309-14.
4. Beezhold DH et al. Clin Exp Allergy. 1996 Apr;26(4):416-22.
5. Brehler R et al. Allergy. 1997 Apr;52(4):404-10.
6. Mäkinen-Kiljunen S. J Allergy Clin Immunol. 1994 Jun;93(6):990-6.
7. Mikkola JH et al. J Allergy Clin Immunol. 1998 Dec;102(6 Pt 1):1005-12.
8. Ahlroth M et al. J Allergy Clin Immunol. 1995 Aug;96(2):167-73.
9. Chen Z et al. J Allergy Clin Immunol. 1998 Sep;102(3):476-81.
10. Diaz-Perales A et al. J Allergy Clin Immunol. 1999 Sep;104(3 Pt 1):681-7.
11. Wagner S et al. Biochem Soc Trans. 2002 Nov;30(Pt 6):935-40.