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Pathogenesis of asthma
- 2. Asthma is associated with a specific chronic inflammation of the mucosa of the lower airways.
- 3. PATHOLOGY • The airway mucosa is infiltrated with activated eosinophils and T lymphocytes, and there is activation of mucosal mast cells. • A characteristic finding is thickening of the basement membrane due to subepithelial collagen deposition. • In fatal asthma there will be thickened and edematous wall along with occlusion of lumen by mucus plug
- 4. • Mucous plug is formed by glycoproteins secreted from goblet cells and plasma proteins from leaky bronchial vessels. • There is also vasodilation and angiogenesis. • Pathologic changes are found in all airways,but do not extend to lung parenchyma.
- 6. INFLAMMATION • There is inflammation in the respiratory mucosa from the trachea to terminal bronchioles, but with a predominance in bronchi. • The specific pattern of airway inflammation is assosciated with airway hyperresponsiveness(AHR) • This physiological abnormality is assosciated with variable airflow obstruction. • Many inflammatory cells are know to be involved in asthma with no key cell that is predominant.
- 7. INFLAMMATORY CELLS • MAST CELLS • MACROPHAGES AND DENDRITIC CELLS • EOSINOPHILS • NEUTROPHILS • T-LYMPHOCYTES
- 8. MAST CELLS: Are activated by allergens through an IgE-dependent mechanism. • Mast cells release several bronchoconstrictor mediators like histamine,prostaglandin D2,and cysteinyl leukotrienses, but also several cytokines, chemokines,growth factors and neurotrophins. NEUTROPHILS:Increased in airways and sputum during acute exacerbations and in the presence of smoking • Determinant of lack of response to CS treatment
- 9. Macrophages and dendritic cells: • Macrophages initiate a type of inflammatory response via the release of certain cytokines. • Dendritic cells are the major antigen presenting cells. • Migrate to regional lymphnodes,interact with regulatory cells to stimulate TH₂ production.
- 10. Eosinophils: These infiltration is a characteristic feature of asthmatic airways. • These are linked to the development of AHR through the release of basic protiens and oxygen derived free radicals.
- 11. T-LYMPHOCYTES • Prominent source of cytokines • Increased no of activated T cells(CD₄) in airway • TH₁ - IL-12,IFN-ɣ • TH₂ - IL-4,IL-5,IL-9,IL-13 • TH₂ predominant in asthma • IgE production (IL-4,IL-13) • Eosinophilia (IL-5) • Mucus secretion(IL-13) • Airway hyper responsiveness (IL-13)
- 12. INFLAMMATORY MEDIATORS • CHEMOKINES • CYTOKINES • LEUKOTRIENES • PROSTANOIDS • IgE • NITRIC OXIDE
- 13. CHEMOKINES: • Recruitment or chemotaxis of inflammatory cells • Additional signalling function • Attractive target for therapy CYTOKINES: • Multiple cytokines regulate chronic inflammation of asthma • The TH2 cytokines IL-4,IL-5 and IL-13 mediate allergic reaction • TNF-α and IL-1β, amplify the inflammatory response • Thymic stromal lymphopoietin causes release of chemokines that attract TH2 cells.
- 14. Leukotrienes • Arachidonic acid metabolites • Rapidly synthesised within minutes,following activation • LT C4,D4,E4 potent bronchoconstrictors • Produced by several cell types including eosinophils,mast cells • Also increase mucus secretion • Facilitate plasma leak,generating airway edema
- 15. PROSTANOIDS: • Arachidonic acid metabolites via COX pathway • PGD₂,PGF₂,TXA₂ potent bronchoconstrictors • Produced by eosinophils,mast cells • PGD₂ predominant prostanoid involved.
- 17. NITRIC OXIDE: • Role unclear • Low levels,a bronchodilator & vasodilator • Higher levels of NO in asthma • NO react with superoxide anion in inflamed tissue to produce biologic oxidants • Level of severity of airway inflammation • Exhaled NO tool to reflect airway inflammation
- 18. AIRWAY EPITHELIUM is central to pathogenesis of ASTHMA • Epithelial stimulation to epithelial shedding,even extensive areas of denudation • Injured & stimulated epithelial cells secrete GM-CSF,IL-1,IL-8,RANTES. • Significant denudation of epithelium itself result in variety of secondary effects
- 19. • Loss of barrier function permit direct access of allergens on tissue cells (eg; mast cells) • Loss of epithelial cells reduces ability to degrade peptide and kinin mediators and to secrete EDRF(which maintain dilatation) • Sensory nerve exposure promote inflammation and bronchoconstriction • Provoke proliferation of myofibroblasts,secretion of extracellular matrix protein(collagen) leading to thickened basement membrane
- 21. EXTRACELLULAR MATRIX • Prominent structural feature in Asthma • Thickening of lamina reticularis • Denuded epithelium expose BM to airspace • Subepithelium is enlarged and dense by deposition of collagen,fibronectin,laminin…. • Epithelial cells and myofibroblasts contribute to thickening • GF:TGF B,PDGF,FGF,endothelin
- 22. FIBROBLASTS AND MYOFIBROBLASTS • Abnormal mesenchymal cell proliferation & no of Fibroblasts,Myofibroblasts ↑ed. • MFB- tissue remodelling by releasing ECM components elastin,fibronectin,laminin. • Allergen challenge ↑no of MFB • Role : contractile response,mitogenesis,synthetic and secretory. • Release RANTES
- 23. SMOOTH MUSCLE CELLS • Excess accumulation of bronchial smooth muscle cells prominent feature of airway wall remodeling • pro-activating signals for converting airway smooth muscle cells into a proliferative and secretory cell in asthma are unknown, but may include viruses and IgE • Another mechanism regulating smooth muscle proliferation is through production of metalloproteinase (MMP)-2 • Nonspecific BHR is a basic mechanism underlying the excessive smooth muscle contraction and airway narrowing
- 24. NERVES • Dysfunction of the airway innervation in asthma contributes to its pathophysiology. • β-Adrenergic blockers and cholinergic agonists are known to induce bronchoconstriction and produce symptoms of asthma. • Nonadrenergic noncholinergic (NANC) neural pathways involving new neuromediators, such as bradykinin, neurokinin, vasoactive intestinal peptide (VIP), and substance P. • These neuromediators produce in vitro and in vivo features of clinical asthma involving bronchoconstriction, vasodilation, and inflammation. • The NANC system has been proposed as an explanation for bronchial hyperreactivity .
- 25. BLOOD VESSELS • Airway wall remodeling in asthma involves a number of changes including increased vascularity, vasodilation, and microvascular leakage. • number and size of bronchial vessels is moderately increased. • neovascularization or angiogenesis is still unclear. • Vascular endothelial growth factor (VEGF) levels are variable in asthmatic airways suggesting a low degree of angiogenesis in patients with controlled asthma.
- 26. GLANDS • Bronchial hypersecretion is the consequence of hypertrophy and hyperplasia of submucosal glands and epithelial goblet cells. • Increased mucus will certainly result in sputum production and contribute to excessive airway narrowing. • The replacement of ciliated cells by goblet cells contributes to airway remodeling in asthma. • Impaired clearance of mucus is present during exacerbations and is a potential important contributor to fatal asthma.
- 27. AIRWAY HYPERRESPONSIVENESS • Increased smooth muscle sensitivity and contracture • Dysfunctional neuroregulation • Increased maximal contraction of bronchial muscle as consequence of reduction/uncoupling of opposing forces (elastic recoil) • Airway wall edema result in functional detachment of alveolar walls • Thickening of airway wall due to chronic inflammation ,result in increased resistance to airflow
- 28. AIRWAY REMODELLING • Inflammation- thickening of sub BM • Mucus hypersecretion (Gland hyperplasia) • Subepithelial fibrosis • Airway smooth muscle hypertrophy • Angiogenesis
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