The genetic basis of asthma heritability has been extensively studied and the studies are yielding some understanding. There is, as yet, no set genetic pattern that predicts presence of asthma or defines it severity. There are usually reasons or risk of asthma factors that makes someone susceptible to asthma and respiratory allergy problems. Asthma doesn’t just happen randomly to anyone without asthma gene factors risk factors.

Let’s consider some asthma risk factors and see how they increase the chance that a individual will have the asthma signs or symptoms of cough, wheezing, as well as shortness of breathing associated with the disease. After determining your personal risk factors for asthma, decide on the ones you can control as well as try to make some lifestyle changes. Avoidance of the risk factors you can control is important in preventing asthma symptoms. While you cannot change your own gender to family history, you can avoid smoking with asthma, breathing polluted air, and obesity. Take control of your asthma by controlling the asthma risk factors. By understanding all of the risk factors, you are able to prevent to control your asthma.

Genetic factors cannot explain the rise in asthma prevalence, morbidity, or mortality. However, a small change in the prevalence of relevant environmental exposures could explain a significant rise in disease prevalence among genetically susceptible individuals. Gene-environment interaction, defined as the co-participation of genetic and environmental factors, is particularly relevant to the etiology of asthma morbidity, especially in individuals who experience a disproportionate burden of environmental exposures. Relevant exposures include smoking, stress, nutritional factors, infections, allergens, and occupational asthma exposures. In addition, racial/ethnic variability in the distribution of genetic polymorphisms can potentially modify the response to pharmacotherapeutic agents, such as the ß 2 -adrenergic receptor. A genetic polymorphism in the ß 2 -adrenergic receptor gene has been associated with asthma severity, as well as with the susceptibility to develop asthma among individuals who smoked.

Childhood asthma happens more frequently in boys than in girls. It is still not known precisely why this occurs even though some experts find a young male’s airway size is small compared to the female’s airway, that may contribute to increased risk of wheezing after a cold or perhaps other viral infection. Around age 20, the ratio of asthma between people is the same. At age 40, more females than men have adult asthma.

The inherited genetic makeup predisposes you to having asthma. In fact, it’s thought that three-fifths of all asthma cases are hereditary. Based on CDC report, if a person has a parent with asthma, there is 3 to 6 times more probably to develop asthma than someone who does definitely not have a parent with asthma.

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A general pattern of factors influencing development of asthma seems to be emerging, including family allergy history/ asthma genetics, smoking, diet, obesity, and inactivity, all of which seem to influence the development of asthma and disease outcomes (Table bellow).

Many clinical or area studies have reported substantially higher rates of asthma prevalence, hospitalization, and mortality among racial and ethnic minorities. However, asthma is also most common among low socioeconomic groups, regardless of race. While black children have higher rates of asthma than white children, most studies have found that black race is not a significant correlate of asthma after controlling for location of residence and socioeconomic status (SES). The basis for the effects of poverty and urban residence on asthma prevalence is not known. One potential asthma factor is allergen exposure and allergen sensitization are common in urban environments. Black children in inner city Atlanta are exposed to high levels of dust mites and cockroach allergen, and a high proportion of the children with asthma were sensitized to these allergens. Litonjua and colleagues also concluded that a large proportion of racial/ethnic differences in asthma prevalence can be explained by factors related to income, area of residence, and level of education.

Asthma Factors that Influence Disease Development and Severity

Income is a determinant of access to health care, and frequently, the quantity and quality of health care available. Persons who have low income, regardless of race or ethnicity, are more likely to be uninsured, to encounter delays or be denied care, to rely on hospital clinics in emergency departments for health services, and to receive substandard care. The usual socioeconomic indicators, education and personal or household income, serve only as surrogates for more complicated correlates of individuals within populations and multiple asthma factors that can impact both on prevalence of asthma and adverse outcomes from the disease.

Studies from Germany comparing the populations of East and West Germany have shown the prevalence of hay fever and asthma as significantly higher in West German children, suggesting that asthma environmental factors explain the difference in prevalence in these ethnically similar populations. Early exposure to infections (as with being in a day-care environment early in life) or exposure to endotoxin (as with growing up on a farm with close exposure to the farm animals) are associated with a decreased prevalence of asthma. In contrast, growing up in an urban environment or generally with an increased standard of living are associated with an increased prevalence of asthma. Such correlates are also present for atopic disorders other than asthma. In fact, Strachan, who noted that prevalence of hay fever was inversely related to family size, was the first to recognize the importance of early exposures on atopic disease. In the USA, asthma is more prevalent in African-Americans and Puerto Ricans. These findings are not explained by the observations on the role of social class in European studies. Given the ethnic differences between African-Americans and whites, these studies may represent gene-by-environment interaction producing varied phenotypic outcomes.

CD14 is part of the receptor complex for endotoxin, which is a component of tobacco smoke. The CD14 gene is located on chromosome 5q, a region previously demonstrated to be linked to asthma when stratified for smoke exposure. This study was designed to extend these findings by determining whether polymorphisms in the CD14 gene are related to this gene–environment interaction on asthma. Puerto Rican (n = 362 trios) and Mexican (n = 259 trios) families ascertained through a child with asthma were studied. (more…)

Allergic rhinitis and asthma are common comorbidities. Like asthma, the presence of a genetic component in allergic rhinitis has been well established. To identify genetic linkage regions unique to allergic rhinitis, as well as those shared by allergic rhinitis and asthma, a genome screen study was conducted. A total of 295 families in the French Epidemiological Study on the Genetics and Environment of Asthma (EGEA) containing 1317 subjects were genotyped for 396 microsatellite markers. The families included had two siblings with DNA available and at least one asthmatic subject. Three definitions of allergic rhinitis were used, two binary and one categorical. To investigate linkages specific to allergic rhinitis (without asthma), linkage analyses were also conducted in 185 families with at most one asthmatic sib. (more…)

This study examined the genetic basis of sensitization to house dust mite allergy allergens. A genome scan was conducted using 603 microsatellite markers in 82 nuclear families (366 individuals) of German, British and Portuguese origin with at least two affected siblings. Sensitization to Dermatophagoides pteronyssinus was assessed by determining specific IgE antibody levels detected by immunochemiluminometric assay and immunosorbent assay and categorized as positive or negative relative to a predetermined cut-off point. (more…)

The Tcell Ig domain and mucin domain (TIM) proteins, the genes for which are located on chromosome 5q, have been suggested to be involved in allergic disease. This study examined allergies genetic association of sequence variants of the TIM1 and TIM3 genes in an African-American population. Case–control and family based association analyses were performed for three SNPs each in the TIM1 and TIM3 genes, and an insertion/deletion polymorphism in Tcell Ig domain and mucin domain 1. (more…)

Asthma and allergic diseases are common in both children and adults. Their development depends on an interaction between asthma genetic and asthma environmental risk factors. Genetic manipulation in multi factorial diseases such as asthma is not feasible in the foreseeable future. However, theoretically, environmental exposures can be controlled in an attempt to stem the rising prevalence of these diseases (primary prevention). Environmental exposures may also influence the frequency of symptoms and the requirement for medication in those with established disease. (more…)

The most crucial element in the assessment process of a possible allergic problem is patient’s allergy history. An allergy history is made up of a chief problem, resolve of seasonality or diurnal variation of symptoms, detection of triggers, occupational asthma exposure, and reaction to medicines, family history, and some other relevant medical history. An allergy history looks for to define the patient’s chief complaint(s) and concentrates on the details with regards to those complaints. There is a lexicon typical to patients with allergy complaints. Sinus dizziness strain and headaches are often cited as symptoms. The history taker should be attuned to the patient’s viewpoint as a possible allergy sufferer. Exactly where and when does the symptom happen? Or is it happened during sleep? (more…)

The two strongest risk factors for asthma in childhood are a family history and immediate hypersensitivity to common allergens. This immune response includes both IgE antibodies and helper T cells type 2 (Th2), both of which are thought to contribute to the inflammation in the respiratory tract. Children with asthma who mount an immune response to inhalant allergens have an increased risk of developing asthma because of this combination of genetics and exposure. However, it is sensitization to indoor allergens (e.g. dust mites, cats, dogs, and cockroaches) that is strongly associated with asthma. (more…)

Epidemiological studies of farm children are of international interest because farm children are less often atopic disorders, have less allergic disease, and often have less asthma pain than do non-farm children—findings consistent with the hygiene hypothesis. The investigators studied a cohort of rural Iowa children to determine the association between farm and other environmental risk factors with four asthma outcomes: (more…)