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.

Perhaps the most exciting recent advance in the cytokine signaling field has been the elucidation of the Jak/Stat pathway. The Janus kinase (Jak) family consists of four known enzymes (Jak1, Jak2, Jak3, and Tyk2), each of which associates specifically with the cytoplasmic tails of one or more cytokine receptor subunits. For example, IL-2R associates with both Jak1 and Jak3, which bind its α and γ subunits, respectively. Cytokine binding brings the receptor subunits together and allows the associated Jak proteins to phosphorylate and activate one another. The primary substrates of the activated Jaks are a family of transcription factors called the Stat (for signal transducers and activators of transcription) proteins. The Stat proteins contain SH2 domains and so are recruited to the vicinity of an activated receptor when its kinases become active. (more…)

The body’s innate resistance to many pathogens is provided by enzymes and other proteins in the blood and tissue fluids. These proteins are the effectors (ie, the active agents) of humoral innate immunity, and they have features in common with one another that are also characteristics of the innate immune system as a whole. First, these proteins are continually expressed throughout life, regardless of whether or not their protective effects are needed at a given moment. Second, although many of these proteins can be produced in higher quantities in times of need, their intrinsic properties (eg, substrate specificity and ige binding affinity) never change: The characteristics of these proteins have been shaped by evolution, are genetically determined, and are fixed at birth, so that they do not vary during an individual’s lifetime. (more…)

Hematopoietic progenitors depend on a variety of cytokines to control their growth and differentiation. These include several different types of colony-stimulating factor (CSFs) and interleukins that each act on specific cell types to promote or inhibit particular types of responses. Detailed discussions of individual cytokines are presented in Chapter 10; for the present, we focus on general principles of cytokine action as illustrated in their effects on hematopoiesis. (more…)

There are thousands of components to the immune system, and during the course of learning about some of these it can appear that the immune system is far more complex and complicated than necessary for achieving what is, on the surface, the simple task of eliminating an infectious organism. There are a number of reasons why the immune system is complex. The first of these is the desirability of eliminating pathogens without causing damage to the host. Getting rid of a pathogen is theoretically easy. If you had an infection in your liver you could produce a nasty toxin that would kill the pathogen; unfortunately it would also destroy your liver. Killing pathogens is not difficult, but getting rid of pathogens without damaging the host is much more complicated. (more…)

Systemic allergic reactions are a relatively common clinical emergency. In their mildest form, they may just manifest as systemic cutaneous reactions with pruritis, allergy urticaria and angioedema. In more severe cases there are cardiorespiratory symptoms such as stridor, wheeze, difficulty in breathing or hypotension. Anaphylaxis has been defined as a ‘severe, life-threatening generalized or systemic hypersensitivity reaction’. The prevalence of systemic allergic reactions is unclear because of the lack of a clear, consistent definition and large prospective population studies. (more…)

According to the National Survey of Children in the United States, the prevalence of asthma was 15% (last 12 months), that of hay fever was 12.4%, of skin allergy 9.8% and digestive/ food allergy 3.6%. Overall, every fourth child is affected (25.4%). Regarding the diagnosis of asthma in children, the prevalence, for instance in Germany, rose from 1.25% to 2.21% between 1951–1952 and 1964–1965. For the last 10 years there has been dispute about whether the increase in asthma and allergy has come to a halt. However, the observation period is too short to draw any conclusion. A study of adults went beyond this simple dispute and investigated age and cohort effects for immunoglobulin E (IgE) sensitization from 1992 to 1998–2002. (more…)

If you have a mold allergy, gluten allergy, or had any other type of allergy, then you need to learn natural allergy treatments. The treatment is needed to enhance natural immune system and adrenal system begins to get stronger. (more…)

The protective effect of breast-feeding on asthma and allergy has been debated for more than 60 years without any hope of a consensus. A major problem is the lack of randomized controlled trials. However, breast-feeding has a number of other benefits and should be recommended irrespective of any effect on asthma or allergy. This is why randomized trials are not considered ethical. Thus, we have to rely on observational studies, which have produced conflicting results. Mothers who do or do not breastfeed differ in several environmental exposures, including socio-economic class, smoking and area of living, which influence indoor and outdoor exposure to pollutants. Despite statistical adjustment for these confounding factors, the evidence is never as robust as it would be with an randomized controlled trial. (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…)