黑料网

ISSN: 2155-6105
Journal of Addiction Research & Therapy
Make the best use of Scientific Research and information from our 700+ peer reviewed, 黑料网 Journals that operates with the help of 50,000+ Editorial Board Members and esteemed reviewers and 1000+ Scientific associations in Medical, Clinical, Pharmaceutical, Engineering, Technology and Management Fields.
Meet Inspiring Speakers and Experts at our 3000+ Global Events with over 600+ Conferences, 1200+ Symposiums and 1200+ Workshops on Medical, Pharma, Engineering, Science, Technology and Business

In 250 Children, Is Wolly Genetic the Transmission of Allergy and Asthma I, Mainly If these Children are Asthmatic?

Arnaldo Cantanii*

Department of Pediatrics, Division of Allergy and Immunology, Roma University, Italy

Corresponding Author:
Professor Arnaldo Cantanii
Department of Pediatrics
Division of Allergy and Immunology
Roma University “La Sapienza”, Italy
Tel:009640556887
E-mail: acantani13@gmail.com

Received date: April 27, 2015 Accepted date: July 30, 2015 Published date: August 06, 2015

Citation: Cantanii A (2015) In 250 Children, Is Wolly Genetic the Transmission of Allergy and Asthma I, Mainly If these Children are Asthmatic? J Addict Res Ther 6:237. doi:10.4172/2155-6105.1000237

Copyright: © 2015 Cantanii A. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Visit for more related articles at Journal of Addiction Research & Therapy

Abstract

There seems to be no unanimity of opinion as to the mode of transmission of allergic disease. According to some, allergy is transmitted as a simple Mendelian dominant. In direct contrast, others maintain that the findings favor a recessive mechanism. Further- more, others suggest that the condition is inherited as a “partial dominant” disorder. An additional analysis of family studies as well as data already published, failed to support either the simple dominant or recessive theory. The dominant theory does not explain why in more than half of the pedigrees both parents are normal. The recessive theory is refuted by the existence of pedigrees in which both parents are affected, yet some of the children are normal. To put more order in this complex mess, we have decided to study the genetic risk of children with a family history (FH) of allergy, We have therefore formed this prospective study in 250 children that included: family (FH) and personal history, skin prick tests (SPTs) and specific IgE (RAST), who were admitted to the Pediatric Allergy and Immunology Division of Rome University since they were affected with respiratory allergy. We have prepared a sheet with questions and possible answers. Consequently, we have studied the FH of these children asking whether their parents and brothers/sisters had atopic diseases, and specifying whether such disorders were respiratory or food allergies (FA).

The parents of all children gave their informed consent. We analyzed data using the X2 method. 42.3% of their parents were atopic, as well as their 20 brothers/sisters. In total, 90.2% of fathers, 84% of mothers and 65% of brothers/ sisters had asthma or allergic rhinitis (AR). We add that some parents had urticarial, further there were mothers and brothers/sisters experiencing atopic dermatitis (AD), and some mothers with food allergy (FA). In 23 children from these parents most had AD and respiratory allergy. In 250 children comparable for age and sex with no respiratory disorder supplied from our outpatient clinic 40 parents, 14 mothers and 26 fathers and 9 brothers/sisters had asthma or AR (p = 0.0001), some fathers had also urticaria and two brothers AD. A major part of respiratory allergy is not transmitted by mothers: we stress that 42.3% of parents are atopic, and FH of their children was positive for respiratory allergy in 82-92% of cases.

Thus respiratory allergy can have an autosomal dominant mode of inheritance, but considering the other atopic diseases, the transmission can be polygenic. The impact of genetic factors in these children is stressed by the relevant quote of asthmatic brothers/sisters.

Introduction

Asthma may be a severe genetic ancestral affection whose mode of inheritance is full of mystery. Previously done researches suggest that a gene could be possibly involved in such a disease, but several different genetic models have been obtained. Twins coming from family studies may be useful to spot both genetic and environmental factors. The genetic basis of atopy have involved different researchers to find a conclusive genetic effect on total serum IgE levels in twins: the total serum IgE level discrepancy is significantly lower in pollen sensitive monozygotic (MZ) than in dizygotic (DZ) twins (0,15 vs. 0,51) [1] and the heritage index (the part variability ascribed to genetic factors) is assess- ed to be 59% in adults and 79% in children [2]. The genetic agreement between atopic dermatitis (AD) and asthma was greater in genetically identical MZ twins [3]. MZ twins have a larger concordance ratio for atopy [1,4], while in DZ twins BHR (bronchial hyper- reactivity) and total and specific IgE [1] is preponderant. Therefore, the most reliable approach appears to be the actual accordance between MZ and DZ twins [5]. Twin studies have also revealed a positive evidence for environmental influences, where unshared environmental influences appeared to be important [6]. Most printed studies in this domain have ascertained that everywhere between 40% and 70% of asthma heredity is preferable to hereditary factors [7]. We stress that several studies on asthma genetics have been strengthen by diverse genomewide searches, that suceeded in establishing the linkage between asthma and genetic markers on 13 chromosome regions emboding chromosomes 5q31- 33 (the gene cluster of good many interleukins), 6p21.3, 11q13 and 12q14.3-24.1 [6,8-15]. In this prospective study on 500 children we have appraised the asthma genetics, by estimating the FH of atopy of their respective family, including parents and brothers and/or sisters.

Materials and Methods

In order to investigate the genetic risk of a child with a family history (FH) of allergy, we have enlisted in this perspective study 250 children, 137 males and 113 females ethnically Italian, aged between 3.5 and 6.5 years (median age 4.4 years), In particular we have studied the personal and FH of both parents and children Study children We reckoned whether the babies were “at risk” of atopic disease because of a positive FH of atopy since one or both parents and/or their siblings suffered from asthma, or AD, or AR. The diagnosis of atopic diseases in the children was done according the following criteria: clinical history, physical examination and positive skin tests and/or RAST to the most common inhalant and/or food allergens. Two hundred and fifty healthy children, and their parents supplied during the same period from our outpatient clinic with no history of atopy of liken age, sex, and Italian origin were matched with the study group [16-21].

Informed consent was obtained from parents of each child Skin prick test appropriate emergency equipment and medications were available on site. Antihistamine drugs and topical steroids were stopped at least 2 weeks before the application of the SPTs. Skin testing was done at baseline by the prick method on the volar surface of the forearm by a trained in allergy doctor with the cooperation of a qualified nurse. The skin was marked with a ballpoint pen for the allergens to be tested. The babies were then tested with: histamine hydrochloride (1 mg/ml) as a positive control and isotonic saline as a negative control. We continued with a battery of food and inhalant allergens, including whole CM protein, casein, lactalbumin, egg, fish, wheat, soy, Dermatophagoides pteronyssinus, Alternaria alternata, Lolium perenne, Olea europea and Parietaria officinalis (SARM, Roma, Italy). The diagnostic extract of each individual allergen was placed on the volar surface of the forearm as drops through which the skin was superficially pricked with a straight pin for one second. A new pin was used for each SPT and then discarded, and the drop of the extract was then wiped off about one minute after the prick [22] SPTs were read 20 minutes after the test was finished and considered positive as follows:

+ When the wheal was the half of the histamine wheal;

++ When the wheal was equal to the histamine wheal;

+++ When the wheal was two-fold the histamine wheal;

++++ When the wheal was more than two-fold the histamine wheal [16].

We took for positive only children with a +++ or ++++ reaction, that is a wheal ≥ 3 mm with an area about 7 mm2 (cut-off) so we considered as positive only the children with a mean wheal diameter of ≥ 3 mm than the negative (saline) control. A positive (histamine) control was performed to ensure the absence of any antihistamine drug interference [23].

Total IgE

The determination of the total serum IgE level was done by paper radioimmunosorbent test (PRIST, Pharmacia Diagnostics AB, Sweden), and results were expressed in International Units per ml.

Specific IgE antibodies and determination of specific IgE levels by radioallergosorbent test (Phadezym RAST, Pharmacia Diagnostics).

RAST results are expressed in »RAST Units« (PRU = Phadebas Rast Unit) as follows:

1st class = IgE levels < 0,35 IU/ml,

2nd class = IgE levels > 0,35 IU/ml and lesser than 0,7 IU/ml, 3rd class = IgE levels between 0,7 IU/ml and 17 IU/ml, 4th class = IgE levels higher than 17 IU/ml.

Only RAST results > 0,35 IU/ml were considered as positive The diagnosis of AD was made according to Hanifin and Rajka criteria [24]. The severity score of AD was evaluated according to the SCORAD index [25].

For the diagnosis of asthma, 3 episodes of wheezing without fever were required. Provocation tests with inhalant allergens were not feasible due to the young age of the children studied.

For the diagnosis of rhinitis, nasal discharge and/or blockage occurring continuously for at least 4 weeks plus the typical pale aspect of allergic mucosa on rhinoscopy, without any sign of infective rhinitis in other relatives was required.

The statistical calculations were performed using the X2 test RESULTS As demonstrated by FH, SPTs and RAST, 127 parents of the study children were affected with atopic disease (42.3%), in particular 51 fathers and 76 mothers, in addition to 25 brothers and/or sisters. These parents all tested positive for inhalant allergens (both SPTs and RAST), with the exception of 3 mothers positive to CM allergens and two children with allergic migraine. We stress that 90.2% of fathers, 81.6% of mothers and 91.7% of brothers/sisters suffered from respiratory allergy. In detail, 41.2% of fathers, 40.8% of mothers and 72.2% of brothers/ sisters were asthmatic. In addition 49%, 40.8% and 19.4%, respectively, were affected with AR. Moreover 9.8% of fathers and 6.6% of mothers had urticaria, 2.9% of mothers and 10.5% of brothers/sisters had AD, and 4% of mothers had CMA (Table 1).

Atopic disease No. (%) F M (B/S)
Asthma 52 (40.9) 21 31 6
Allergic rhinitis 57 (44.8) 25 32 4
Atopic dermatitis 2 (1.6) 0 2 3
Urticaria 10 (7.8) 5 5 3
Oculorhinitis 3 (2.5) 1 2 1
Food allergy 3 (2.5) 0 3 2
  127 52 75 20

Table 1: Parents of children affected with atopic disease.

Twenty-five children were allergic, with a high proportion of cases of AD (52%), however the respiratory allergy affects 30.4% of these children (Table 2) who appear to have multiple sensitizations in 34.8% of cases (Table 3). Thirteen of these children had SPTs and RAST positive for food allergens (mostly CM and egg) and 10 for inhalant allergens.

Atopic disease No. (%)
Atopic dermatitis 12 (52.2)
Asthma 5 (21.7)
Urticaria 4 (17.3)
Allergic migraine 2  (8.6)
Oculorhinitis 1 (4.3)
Allergic rhinitis 1 (4.3)
  25

Table2: Children affected with atopic disease.

Degree of sensitization No. (%)
 Single sensitization 15 (65.2)
Multiple sensitization 8 (34.8)
  23

Table3: Degree of sensitization of the 23 children.

In the control group 61 parents were allergic, and 40 were affected with respiratory allergy. In detail, 14,7% of fathers and mothers and l8,2% of brothers/sisters had asthma. 6,6%, 13,1% and 4,9%, respectively had AR and 6,6% of fathers and mothers had 3,3% of brothers/sisters allergic oculorhinitis Further, 6,6% of fathers 13,1% of mothers and 1,6% of brothers had urticaria, 11,5% of mothers and 1,6% of fathers and brothers AD, in addition to 3,3% of fathers, 11,5% of mothers and 8,2% of brothers/sisters with FA.

In the control group, 11 children were sensitized who in 15,5% of cases had respiratory allergy Study children vs. controls (p = 0.0161).

We have ascertained that a high number of parents of the study and control children were active smokers (Table 4). The statistical analysis revealed high statistically differences between fathers and mothers of the study group versus the parents of the controls, p = 0.0196 and p = 0.0387, respectively.

Relative Children in study
Number %
Controls
Number  %
Fathers 125 60,6 153 51
Mothers 99 37.7 89 29.7
Others 15 5.2 25 8.3
Fathers and Mothers 93 32.2 73 24.3

Table 4: Number of people smoking in the home of 125 children and 125 controls.

The statistical analysis has demonstrated highly significant differences between the two samples (p = 0.0001).

Discussion

The results do not allow us to confirm that a significant proportion of respiratory allergy is transmitted by mothers. We underline that 42.3% of parents are atopic, with a FH positive for respiratory allergy in 82-92% of cases In the study sample 147 parents and brothers were affected with respiratory allergy (45.94%) versus 10,3% of controls who in 65.5% of cases had respiratory allergy. Therefore, asthma is a genetic disease, at least in 42.3% of cases. Respiratory allergy can have an autosomal dominant mode of inheritance, but by considering the whole atopic whole, the transmission can be polygenic. The high impact of the genetic factors in these children is stressed by the high proportion (85%) of asthmatic brothers/sisters. As regards the smoking parents it is very significant the number of couples smoking together. The low number of other relatives probably depends by the smaller apartments prevailing in Italy.

What our study evidently stresses is that a high number of parents, atopic parents, yet they themselves asthmatic, as we have ascertained, are smoking parents of asthmatic sons and daughters. Such data demonstrates in an unequivocal manner that cigarette smoke should be considered as a triggering factor of respiratory allergy. Therefore in babies at risk of atopy cigarette smoke should be regarded as an additional genetic factor, since asthma is more easily transmitted if an atopic parent smokes (even more if both parents smoke). However cigarette smoke is able to provoke asthma even in children of nonatopic parents, especially if the smokers are pregnant women: their children frequently suffer with Der p-induced asthma [16].

Allergic asthma and rhinitis, AD, urticaria and FA are genetic diseases of infants and children. Several investigators have provided evidence for a genetic localization for atopy. Babies of atopic parents are at high risk of developing atopic diseases, however the phenotypic expression of such disorders varies widely, being very mild in some infants and children, severe and frustrating in many, even lifethreatening in others, being also common, disabilitating, and chronic [17]. In particular we can now understand how strictly the genetic factors are linked with atopy: several cytokine genes are associated in the gene cluster of chromosome 5q23-q31, such as IL-3, IL-4, IL-5, IL-9, IL-12b, IL-13, and GM-CSF, together with the genes for the ß2- adrenergic receptor [18]. It is likely that plural loci in the chromosome 5q31-q33 region are synergistically related to asthma susceptibility.

We have frequently spoken of respiratory allergy. However, a large number of cross-sectional studies have reported that asthma and AR commonly occur in children and adolescents [19-21]. Studies have demonstrated that AR occurs in 28-78% of older children and adolescents [19-21], versus approximately 5-20% of the general population [22]. Conversely, asthma has also been shown to affect up to 38% of AR patients [19,21], a data significantly higher than the 3-5% prevalence noted in the general population [22]. In an unpublished study on 411 children aged 7-13 years, asthma had an incidence of 31.5% and AR of 25.8%. Asthma and AR can have an early onset. The asthma affair is a little more intricate: the onset within the first year is certain in 34.5% [23-26]-56.2% [24,27] of babies, but a higher level (82.4%) is evident between the 4th and the 7th year [24,27-29]. That within the 8th year the asthma onset is manifest in 90% of children [28] is confirmed by the 92% proportion reached in patients less than 20 years of age [30]. As regards AR, the onset may be in the first year in 35% of children and in 59% of those aged 2-5 years [24], who in other studies are affected in 13-19% of cases [23,31].

Once atopy develops, it is now possible to prevent the clinical manifestations in a great proportion of cases (secondary prevention) by the use of pharmacological agents such as cromones and ketotifen [32]. In addition as demonstrated by the ETAC study we can prevent the onset of respiratory allergy in 50% of babies with AD following an 18-month administration of cetirizine [33]. Since the commitment to the Th2 phenotype in atopics appears to occur at any time between the ages of 2 and 5 years [34], the net implication is that within the first years of life there is a window open for immunoprophylaxis [35].

Conclusion

In conclusion, we have proven that asthma is a genetic disorder and that the transmission of allergy and asthma is fully genetic in children, mainly if asthmatic.

References

  1. Bonini S, Rasi G, Celestino D (1983) Genetic aspects of allergic asthma. Twin studies. Proc XII Congr EAACI, Rome 109-122.
  2. Bazaral M, Orgel HA, Hamburger RN (1974)
  3. Edfors-Lubs ML (1971)
  4. Hopkin JM (1995)
  5. Skadhauge LR, Christensen K, Kyvik KO, Sigsgaard T (1999)
  6. Los H, Koppelman GH, Postma DS (1999)
  7. Duffy DL, Martin NG, Battistutta D, Hopper JL, Mathews JD (1990)
  8. Daniels SE, Bhattacharrya S, James A, Leaves NI, Young A, et al. (1996)
  9. Xu J, Meyers DA, Ober C, Blumenthal MN, Mellen B, et al. (2001)
  10. (1997)
  11. Dizier MH, Besse-Schmittler C, Guilloud-Bataille M, Annesi-Maesano I, Boussaha M, et al. (2000)
  12. Ober C, Tsalenko A, Parry R, Cox NJ (2000)
  13. Wjst M, Fischer G, Immervoll T, Jung M, Saar K, et al. (1999)
  14. Koppelman GH, Stine OC, Xu J, Howard TD, Zheng SL, et al. (2002)
  15. Renz H, mutiusEv, Illi S, Wolkers F, Hirsch T, et al. (2002)
  16. Cantani A, Jovanidis N, Gagliesi D. Ilfumomaternodurante e dopo la gravidanzaassociatoallosviluppo di asma da Der p nel bambino. AggiornPediatr 1998; 1: 5-10
  17. Cantani A (1999)
  18. Anderson GG1, Morrison JF (1998)
  19. Blair H (1977)
  20. Smith JM (1983) Epidemiology and natural history of asthma, allergic rhinitis and atopic dermatitis. In Middleton E Jr, Reed CE, Ellis EE ed (2nd ed). Allergy: Principles and Practice, St Louis: CV Mosby 771-803.
  21. Pedersen PA, Weeke ER (1983)
  22. Settipane RJ1, Hagy GW, Settipane GA (1994)
  23. Blair H(1974) The incidence of asthma, hay fever and infantile eczema in an East London group practice of 9145 patients. Clin Allergy 4: 389-399
  24. Koivikko A (1974)
  25. Croner S, Kjellman NI (1992)
  26. Businco L, Falconieri P, Zannino L, Cantani A (1993) Presentazione Dei Risultati di uno studio policentrico epidemiologico delle malattie allergiche in etàevolutiva in Italia. Notiz Allergol12: 275-278
  27. Gergen PJ, Turkeltaub PC, Kramer RA (1992)
  28. Bergmann RL, Bergmann KE, Lau-Schadensdorf S, Luck W, Dannemann A, et al. (1994)
  29. Linna O, Kokkonen J, Lahtela P, Tammela O (1992)
  30. Jenkins MA, Hopper JL, Bowes G, Carlin JB, Flander LB, et al. (1994)
  31. Rich SS, Roitman-Johnson B, Greenberg B, Roberts S, Blumenthal MN (1992)
  32. Cantani A (2008)Pediatric allergy, asthma and immunology. Springer, Heidelberg.
  33. Warner JO (1997)
  34. Yabuhara A, Macaubas C, Prescott SL, Venaille TJ, Holt BJ, et al. (1997)
  35. Holt PG (1994)
--
Post your comment

Share This Article

Article Tools

Article Usage

  • Total views: 13454
  • [From(publication date):
    September-2015 - Nov 25, 2024]
  • Breakdown by view type
  • HTML page views : 9122
  • PDF downloads : 4332
International Conferences 2024-25
 
Meet Inspiring Speakers and Experts at our 3000+ Global

Conferences by Country

Medical & Clinical Conferences

Conferences By Subject

Top