Hypersensitivity to Vitamins E-Book

BENTHAM SCIENCE PUBLISHERS LTD.

FOREWORD

Hypersensitivity to vitamins is rare - at least I have seen only very few cases in my life as an allergist (or did I miss some?). But now Gianfranco Calogiuri even writes a book about hypersensitivity to vitamins! It contains 13 chapters – one for each vitamin and two chapters on general and unusual aspects of hypersensitivity to vitamins. Isn`t this too much, a whole books on hypersensitivity reactions to vitamins? But as Gianfranco approached me, I was immediately fascinated and agreed to write a foreword: not because I am specialist on hypersensitivity reactions to vitamins, but because I am convinced that we, as medical community, can be happy to have someone ready to devote so much energy, passion and knowledge into a special topic. Such an enthusiasm can be immensely helpful for the medical community, as most of us do not have time or interest to become so specialised in such a topic, which we encounter only rarely, an where we need help, if we encounter it.

The book gives a comprehensive overview on function of each vitamin, its use, metabolism, pharmacological preparations, way of application and structure followed by Type I and/or Type IV hypersensitivity reactions. There are many interesting case descriptions included and referenced, and they are summarized in enough detail to allow comparison to the own case, which was probably the reason why ones looks for advise in this book. Of great help are the precise description which preparation was involved and how the hypersensitivity reaction was diagnosed. Since some vitamins are essential, desensitisations are important. The book provides much information on possible procedures and their outcome.

It is puzzling that hypersensitivity to vitamins exist at all, as we are consuming them in many foods. Various case reports illustrate quite clearly, that a slight modification of the usual substance or an abnormal way of uptake (e.g. parental) can be relevant. Indeed, quite many cases illustrate that the vitamin is tolerated, if applied orally, but is damaging if applied parenterally. All this information can be extremely helpful in the own case and how to help the patient.

I am happy and thankful that Gianfranco made this effort to collect all this information and to put it together. Writing a book is still the best way to spread the news to the medical community. It is a critical, highly informative review of all aspects of hypersensitivity to vitamins, and it will be the standard for this topic.

I hope the book finds its readers, and that we reader will find what he/she is looking for.

Werner J Pichler, Bern, February 2021.

PREFACE

COVID-19 infection was a frightful disgrace for all the mankind, however this book would not have been written without the SARS2 pandemic and the related lockdown and quarantine periods. When you have suddenly all the social life erased (no picnics with your family, no meals with your relatives, no parties with your friends, no travels, no meetings or congresses with your fellows, no gym, cinemas, theatres or concerts, just your work and the usual trip from home to the hospital and viceversa, day by day) you try to react. This book was the way I reacted to that situation. Previously, I have written an article “Hypersensitivity to vitamins with a focus on immediate type reactions: food or drug allergy?”, so why do not extend that issue from an article to a book? I had already read many articles and case reports; I just needed to read some further articles and organize the chapters.

Vitamins are essential substances for life and body wellness, but they are not produced by human organism, so they need to be introduced through diet. Their deficiency may induce severe diseases like rickets or scurvy which can be even lethal as well known by the sailormen of the last centuries. Every vitamin was identified and chemically obtained as ester, thus allowing their use like medications or for industrial purposes, but as well as any other drug, vitamins may induce hypersensitivity reactions, especially in their synthetic form. However, while for an antibiotic, an antihypertensive or a chemotherapeutic agent, it is possible to find an alternative molecule, stopping the culprit drug administration, that approach is not always possible with vitamins, which need to be assumed by the patient, despite his/her sensitization. Surely, and luckily, vitamin hypersensitivity is not so common as antibiotics allergy, but probably it is also undervalued, poorly diagnosed and certainly described anecdotally.

The effort of this book has been to collect most of the case reports from literature thanks to a netsurfing research on Pubmed and Google Scholar and try to illustrate in an organic and systematic way, the mechanisms of vitamin sensitization, as understood or postulated by clinicians and researchers who have treated a vitamin sensitive patients “on the field”, with a focus on the clinical aspects, the diagnostic approach and the therapeutic managements, trying to highlight much more a minor topic of drug hypersensitivity.

For each vitamin, beyond a short introduction concerning the biological activity, its use, a sketch on its metabolism and potential chemical derivatives, the most interesting part is represented by the experiences from different authors and related discussions of their case reports or studies. I limited to do some considerations of mine on the basis of the vitamins metabolism, the comprehensive literature data and my little experience with drug allergy. In future, some speculative reflections I have illustrated in this book might not be confirmed or be contradicted even by other authors experiences or by different evidences from the forthcoming case reports. For that, I apologize in anticipation. However, it would mean also this book has stimulated the curiosity of a clinician or a researcher, surely smarter than me, enough to dedicate his/her time, attention, expertise and wit to treat, solve and describe a new case of vitamin hypersensitivity from an alternative point of view or with innovative proposals I did not consider in this book. For that reason, I do not think this book is the complete or ultimate version on this topic, and I hope that nutritionists, clinical pharmacologists or other clinicians may alert me about the possible weak sides of the book, even for a future, updated and improved edition, maybe. That is all makes medical research challenging: nothing is forever in medicine and sometimes, the answers to your questions belong to another researcher, who does not image the question even.

Then, I would like to thank a research team I have ever met, personally or on the social media: Prof. Janos Zempleni and all the editors and authors of his “Handbook of vitamins” (Taylor & Francis Publisher), whom I largely cited. It was my guide, because it elucidated vitamins metabolism to me and greatly helped me to write this book. Since any vitamin is potentially a hapten, which may turn in an allergen, it is important to know and describe its chemical formula; for that reason I hope Prof. Zempleni and his biochemical team of nutritionists may excuse me if I have reported some chemical structures of the vitamins as well as they did in their book: their way was the clearest..

Lastly, a grateful thought to my wife Maria Rita, for having supported me in this project.

ACKNOWLEDGEMENTS

In Italy, the SARS2 pandemic required special containment policies and restrictions, like lockdowns and prohibition to leave the town where one lives or works. For that reason, I deeply thank Professor Luigi Macchia and Professor Eustachio Nettis from the School of Allergology and Clinical Immunology, Department of Emergency and Organ Transplantation, University of Bari Aldo Moro, Bari, Italy. Professor Angelo Vacca from the Department of Biomedical Sciences and Human Oncology, University of Bari Aldo Moro Medical School, Bari, Italy. Professor Caterina Foti from Dermatological Clinic of the 2nd Department of Biomedical Science and Human Oncology, University of Bari Aldo Moro, Bari, Italy. Dr Maurizio Congedo from the Section of Dermatology of Vito Fazzi Hospital, Lecce, Italy for having helped me to collect the book bibliography, since I could not leave my town to consult the Bari University Library.

BIOGRAPHY

Gianfranco Calogiuri is born in Lecce (Italy) on March, 5th 1961. He was graduated in Medicine in November 1988 at the Chiet University Gabriele D’Annunzio (Italy) and on November 1992 and he has obtained the Board Certificate as Specialist in Allergy and Clinical Immunology at the Bari University Aldo Moro attending the Department of Allergy and Clinical Immunology directed by Professor Alfredo Tursi. In 1994 he took a master on Pediatric Allergy and Immunology at the Pediatric Department of Bari University, then he was appointed as assistant in different hospitals of the Azienda Sanitaria Lecce at First Aid Center firstly, then, in Internal Medicine, Infectious Diseases, Dermatology, Hematology, Clinical Pathology and Neurology. In 2005, he has been hired at the Pneumology Hospital in San Cesario di Lecce and in 2011 he has worked as consultant in Allergy and Pneumology at the Asthma Center of the Hospital “Ninetto Melli” in San Pietro Vernotico (Brindisi) up to 2016. In 2012, he obtained his PhD in Immunology and Infectivology at the Bari University with a thesis on the immunological status of the tracheotomy patients.

From 2016 up to 2020 he worked in the Department of Pneumology and Allergy of Hospital Sacro Cuore in Gallipoli (Lecce-Italy). For the needing of well-trained doctors because of the COVID 19 pandemic, at the beginning of 2020 he was temporarily assigned at the Pneumology Department of Civil Hospital Vito Fazzi in Lecce. He is a member of European Academy of Allergy and Clinical Immunology (EAACI) from 2003 and a member of ENDA (European Network for Drug Allergy). Besides the articles published on Italian scientific journals, he has published more than 50 articles on international scientific journals as author and co-author and a book contribution. Actually he actively collaborates with the Department of Allergy and Clinical Immunology at Bari University to investigate the pathomechanisms of drug allergy. His main fields of interest are the drug induced hypersensitivity reactions, either IgE mediated or T cell mediated, their diagnosis, management and therapy.

Hypersensitivity to Vitamins: General Considerations

Introduction

With the name of vitamins, a heterogeneous group of biologically active organic substances are indicated. They are essential compounds playing an active role in numerous enzymatic pathways of the human organism [1, 2]. The name derives from the Italian amine [because they were reputed to be amines] della vita [of the life]. However, humans cannot produce vitamins de-novo, so they must absorb vitamins through the diet [1, 2], thus, under the name vitamins there is an highly differentiated family of compounds with various biochemical properties and

chemical structures exhibiting antioxidant, co-enzymatic and hormonal activity, even [1, 2]. Vitamins are essentially divided into two groups [1, 2]:

Further substances have been indicated like the missing vitamins, such as vitamin B4 (also known as adenine), vitamin B8 (also known as inositol), vitamin B10 (paraamino benzoic acid – PABA), vitamin B11 (carnitine), but not all the nutritionists accept these compounds may be included in the group of the hydrosoluble vitamins because they are not so essential or alternatively they are so widespread and common in nature, thus their deficiency is extremely rare. Moreover, PABA, for instance, is included in the chemical structure of folic acid, so it can be absorbed with folates too. (see: Chapter 8: Vitamin B9). Vitamin deficiency may be caused by the inadequate absorption of one or more of these compounds as a consequence of both insufficient dietary intake and malnutrition [1, 2]. In Table 1, the main diseases associated with each vitamin deficiency are reported. Vitamins act as cofactors in several cellular enzymatic pathways [1, 2], and it has been suggested that, due to their antioxidant properties, an increased daily consumption of vitamins, taken as megadoses, might protect against ageing and degenerative diseases [1, 2]. For every vitamin, nutritionists have tried to establish the dietary reference intakes (DRIs), which are a set of reference values including the estimated average requirement [EAR], recommended dietary allowance [RDA], adequate intake [AI], and tolerable upper intake level [UL]. These values are changing according to the age and health status of the patient [1]. Then, in 1988, in an eight-month double-blind clinical trial, both multivitamin and multimineral supplements were reported to improve the performance of 30 school children in Wrexham [UK] who were administered non-verbal intelligence tests as part of an 8-month double-blind clinical trial [3]. Although the British nutrition establishment found many weaknesses in the trial, and some attempts to confirm the results failed, the myth of unnecessary intake of vitamins at high doses had started; thus, nowadays, it has become increasingly popular to consume vitamins either as multivitamin formulations or vitamin megadoses. For instance, the “Myers cocktail,” which is often intravenously injected to treat or prevent various chronic diseases, contains high doses of hydroxycobalamin, pyridoxine, dexpanthenol, ascorbic acid, magnesium, and calcium gluconate [4]. Unfortunately, such empirical “do-it-yourself” multivitamin treatments may cause serious adverse effects, including accidental intoxication and hypervitaminosis [5, 6], rather than supposed benefits to the body. Moreover, vitamins and multivitamin consumption has turned to represent a business. It has been estimated that more than 90,000 dietary supplementation products, containing vitamins and minerals available on the USA market, foster an industry of about 30 bilion USD, although the real beneficial effects on the patients' health status induced by vitamins megadoses are doubtfully demonstrated [7]. From a National Health and Nutrition Examination Survey [NHANES] data survey, it has been recorded that from 2003 to 2006, 53% of the United States population aged 1 year and older took a multivitamin supplement in a given month in front of a previous survey [1988-1994] reporting consumption of only about 44% of general population [8] while in 2009, 56% of USA consumers said they comsumed vitamins or other supplements, and 44% of them told to take such compounds daily [8]. In Europe and Latin America, vitamin and supplement usage is lower with a 30% and 28%, and France, Italy and Spain bringing up the bottom with only 13-17 percent and of consumers saying that they take vitamins and supplements. The primary reason for not taking vitamins was that their diets were already balanced, so there was no need to take them [8], while 90% of the American population do not follow vitamin E intake recommendations because of the scarce consumption of green leafy vegetables in the country [9]. For that reason, in 1995, vitamin E supplements have been taken daily by more than 35 million people only in the United States [9], although 10 years later, many clinicians alerted about the potential adverse effects of vitamin E excessive consumption [10]. A report published in 2005 found no clear evidence that men and women who had vascular disease or diabetes and who took 400 I.U. of vitamin E daily for seven years reduced their risk of cancer compared to others with these conditions who took a placebo [10]. However, vitamins and multivitamin supplements are perceived as beneficial and natural substances required by the human body, but commercial vitamins rarely are “natural” products. Firstly, it is necessary to distinguish between vitamins, which naturally occur in foodstuffs, and their semi-synthetic analogues, obtained by chemical procedures, as in the case of thiamine. Naturally occurring vitamin B1 or thiamine, is a water-soluble vitamin found in plants and animals usually bound to phosphates. However, synthetic vitamin B1 (i.e., thiamine hydrochloride) is obtained from coal tar, ammonia, acetone, and hydrochloric acid [11]. For that reason, it is necessary to consider that the refined vitamin is usually a compound not completely identical to the naturally occurring form, because often it is an ester or a salt unconjugated instead of the original phosphate moiety [11]. Then most of the substances known as vitamins (A, D, E, K, B6 and others) are constituted by groups of minor molecules named vitamers with a variable biological activity that can be influenced by their isomeric shape, so the efforts of researchers were made to identify among them, the most biologically active component performing properly its biochemical and nutritional effects on the organism, viz the vitamer whose lack generates severe hypovitaminosis. Vitamin E, for instance, is a mixture of compounds derived by plants designated as tocotrienols and tocopherols. Among the latter group, it is possible to distinguish alpha-,beta-, gamma- and delta-tocopherols, but only alpha-tocopherol was identified as the form that greatly fits with vitamin E requirements by human beings (see: Vitamin E chapter). Yet, some vitamins are present in foodstuff as provitamin, such as vitamin A or vitamin D, needing to be processed by hydrolysis or other metabolic pathways for their conversion in a biologically active form, such as the beta-carotene [pro-vitaminA] needs to be converted in vitamin A [retinol] or calcitriol or vitamin D (see: Vitamin A – Vitamin D chapters), whereas the ultimate active metabolite may be produced synthetically with biochemical procedures. Anyway, synthetic vitamins show many advantages compared with the naturally occurring vitamins because they can be administered not only orally, but also intramuscularly or intravenously, thus to achieve quickly a therapeutic dosage for the treatment of a severe vitamin deficiency as in Wernicke Korsakoff syndrome (see: Vitamin B1 chapter), or when they are used as an antidote, such as vitamin K given to contrast a coumarin overdose or hydoxy-cobalamin, a vitamin B12, whose high doses are administered in cyanide intoxication (see: Vitamin B12 chapter). Furthermore, synthetically obtained vitamins can be easily stored for long periods, and they are not conditioned by food deterioration, although light and temperature may influence certain vitamins storage, causing a decline in their biological strength. On the other hand, clinical practitioners and nutritionists have emphasized the importance of vitamins in specific groups of people at risk for vitamin deficiency, such as newborns and infants who specifically need vitamin K, and pregnant women who are recommended to take folic acid, to avoid neural tube defects to the newborn [12, 13]. Moreover, vitamin D may be essential for children living in northern European countries during the winter, while alcohol-addicted patients are recommended to take supplemental thiamine [12]. Multivitamin supplements may also be useful in treating patients with low caloric intake caused by an inappropriate diet or decreased appetite, as well as emotionally disturbed patients, i.e. anorexics, and patients receiving total parental nutrition preparations. In developing countries, there is increasing evidence that vitamin deficiencies are associated with individual increased susceptibility to infections and with a higher incidence of mortality [13]. The identification and synthesis of each vitamin has allowed to pursue a procedure to increase vitamin consumption in general population, represented by food fortification. Food fortification is the process of adding micronutrients like vitamins or minerals to foods to increase its overall nutritional content, thus preventing vitamin deficiency [14]. Food fortification has been safely and effectively employed in developed countries for well over a century. Food fortification has been recognized by many national governments and world agencies like the World Health Organization [WHO] and Food Agriculture Organization [FAO] as an important strategy to help and improve the health and nutrition status of millions of people because it does not require either change in the customary diet of a population or in individual compliance [14]. For example, vitamin A-fortified margarine was introduced in Denmark in 1918; and in the 1930s, vitamin A-fortified milk and flour supplemented with iron and vitamin B complex was introduced in several developed countries [15]. A wide variety of foods have been fortified with different nutritional ingredients, and vitamin enriched foods may be grouped into three broad categories:

These categories of products have been proposed because they meet three food fortification policies: mass fortification involving widely consumed foods, targeted approaches allowing the fortification of foods consumed by specific age groups like infant complementary foods; and lastly, market-driven approach occurs when a food manufacturer fortifies a specific brand for a particular consumer area. Although actually most nutritional interventions are focused on enriching foodstuff with vitamins like folic acid, vitamin D and vitamin A [15], there is a growing interest to enrich the first group of foods with other vitamins as shown in Table 2.

Furthermore, it has been observed that certain vitamins may be used as therapeutic agents to attenuate the toxic effects or to improve the clinical efficacy of some chemotherapeutic alkylates used to treat cancer patients. Folinic acid or leucovorin is the reduced form of folic acid: it can be administered as an antidote for folic acid antagonists such as methotrexate or given intravenously with 5-fluorouracil [5-FU] to enhances the cytotoxic effects of chemotherapy in resected colon cancer patients [16]. Using vitamins as drugs has increased the attention towards the development of vitamin-derived drugs, starting from the first anti-folate agent like methotrexate [see: Vitamin B9 chapter], or vitamin A whose derivatives such as isotretinoin, acitretin, etretinate are used to treat recalcitrant acne [see: vitamin A chapter] and lastly, some vitamin D derivatives like calcitriol and calcipotriol are applied topically to treat severe psoriasis [see: Vitamin D chapter]. Some vitamins like vitamin A, E, B3, B6 and C and their derivatives, are used for their antioxidant and anti-aging properties in cosmetics [17] but also as excipients, conservants or dyes in foods, juices and drinks. Riboflavin [vitamin B2], and carotenoids [provitamin A] are permitted as colorants by USA and European authorities as well as vitamin C esters like sodium and calcium ascorbate and vitamin E are allowed as antioxidants in foods, and industrial beverages, including alcoholic drinks [18]. For that reason, the widespread and undervalued presence of vitamins in many dairy consumer products may represent an occult source of exposure to these substances, able to induce a sensitization or to elicit hypersensitivity symptoms, beyond the voluntary intake of multivitamins.