Silicosis pathophysiology

	Silicosis Microchapters
Home
Patient Information
Overview
Historical Perspective
Classification
Pathophysiology
Causes
Differentiating Silicosis from other Diseases
Epidemiology and Demographics
Risk Factors
Screening
Natural History, Complications and Prognosis
Diagnosis
Diagnostic Criteria
History and Symptoms
Physical Examination
Laboratory Findings
Chest X Ray
CT
MRI
Other Imaging Findings
Other Diagnostic Studies
Treatment
Medical Therapy
Surgery
Primary Prevention
Secondary Prevention
Cost-Effectiveness of Therapy
Future or Investigational Therapies
Case Studies
Case #1
Silicosis pathophysiology On the Web
Most recent articles
Most cited articles
Review articles
CME Programs
Powerpoint slides
Images
American Roentgen Ray Society Images of Silicosis pathophysiology All Images X-rays Echo & Ultrasound CT Images MRI
Ongoing Trials at Clinical Trials.gov
US National Guidelines Clearinghouse
NICE Guidance
FDA on Silicosis pathophysiology
CDC on Silicosis pathophysiology
Silicosis pathophysiology in the news
Blogs on Silicosis pathophysiology
Directions to Hospitals Treating Silicosis
Risk calculators and risk factors for Silicosis pathophysiology

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1] Associate Editor(s)-in-Chief: Aparna Vuppala, M.B.B.S. [2]

Overview

The toxicity of crystalline silica results from the ability of crystalline silica surfaces to interact with aqueous media, to generate oxygen radicals, and to injure target pulmonary cells such as alveolar macrophages. Generation of inflammatory cytokines (eg, interleukin-1 and tumor necrosis factor beta) by target cells results in cytokine networking between inflammatory cells and resident pulmonary cells, which in turn leads to inflammation and fibrosis.

Pathophysiology

Pathogenesis

The toxicity of crystalline silica appears to result from the ability of crystalline silica surfaces to interact with aqueous media, to generate oxygen radicals, and to injure target pulmonary cells such as alveolar macrophages.
Generation of inflammatory cytokines (eg, interleukin-1 and tumor necrosis factor beta) by target cells results in cytokine networking between inflammatory cells and resident pulmonary cells, which in turn leads to inflammation and fibrosis.^[1]
The alveolar macrophages are implicated as the major cell type in fibrogenesis^[2], but other immune cells, namely neutrophils^[3], T-lymphocytes, and mast cells are also involved.
Following the interaction between effector immune cells (such as alveolar macrophage) and target tissue (such as bronchiolar/alveolar epithelial cells, fibroblasts), the progression of the disease is poorly understand.
- Injury to the alveolar type I epithelial cell is regarded as an early event in fibrogenesis followed by hyperplasia and hypertrophy^[4] of type II epithelial cells.
- Silica-induced cell hyperproliferation of mesenchymal cells is also a hallmark of the fibrotic lesion.
- Proliferation may occur intially at sites of accumulation of inhaled minerals, but later at distal sites where particles or fibers are translocated over time.
- Alternatively, mitogenic cytokines may mediate signaling events, leading to cell replication at sites physically remote from fibers.
- The initiation of proliferation in epithelial cells and fibroblasts by silica may occur following the upregulation of the early response proto-oncogenes C-FOS, C-JUN, and C-MYC.^[5]
- Increased expression of early response genes and protein products is also linked to the development of apoptosis^[6]^[7]

Low Intensity Exposure vs. High Intensity Exposure

Lower intensity exposures to silica evoke reversible inflammatory changes characterized by focal aggregations of mineral-laden alveolar macrophages.^[8]
In contrast, higher exposures elicit intense and protracted inflammatory changes, cell proliferation in various compartments of the lung, and excessive deposition of collagen and other extracellular matrix components by mesenchymal cells.

References

↑ Rimal B, Greenberg AK, Rom WN (2005). "Basic pathogenetic mechanisms in silicosis: current understanding". Curr Opin Pulm Med. 11 (2): 169–73. PMID 15699791.
↑ Oberdörster G (1994). ; "Macrophage-associated responses to chrysotile" Check |url= value (help). Ann Occup Hyg. 38 (4): 601–15, 421–2. PMID 7978983.
↑ Quinlan TR, BéruBé KA, Marsh JP, Janssen YM, Taishi P, Leslie KO; et al. (1995). ; "Patterns of inflammation, cell proliferation, and related gene expression in lung after inhalation of chrysotile asbestos" Check |url= value (help). Am J Pathol. 147 (3): 728–39. PMC 1870980. PMID 7677184.
↑ Lesur O, Bouhadiba T, Melloni B, Cantin A, Whitsett JA, Bégin R (1995). ; "Alterations of surfactant lipid turnover in silicosis: evidence of a role for surfactant-associated protein A (SP-A)" Check |url= value (help). Int J Exp Pathol. 76 (4): 287–98. PMC 1997178. PMID 7547443.
↑ Janssen YM, Heintz NH, Marsh JP, Borm PJ, Mossman BT (1994). ; "Induction of c-fos and c-jun proto-oncogenes in target cells of the lung and pleura by carcinogenic fibers" Check |url= value (help). Am J Respir Cell Mol Biol. 11 (5): 522–30. doi:10.1165/ajrcmb.11.5.7946382. PMID 7946382.
↑ BéruBé KA, Quinlan TR, Fung H, Magae J, Vacek P, Taatjes DJ; et al. (1996). ; "Apoptosis is observed in mesothelial cells after exposure to crocidolite asbestos" Check |url= value (help). Am J Respir Cell Mol Biol. 15 (1): 141–7. doi:10.1165/ajrcmb.15.1.8679218. PMID 8679218.
↑ Mossman BT, Churg A (1998). "Mechanisms in the pathogenesis of asbestosis and silicosis". Am J Respir Crit Care Med. 157 (5 Pt 1): 1666–80. doi:10.1164/ajrccm.157.5.9707141. PMID 9603153.
↑ Velan GM, Kumar RK, Cohen DD (1993). "Pulmonary inflammation and fibrosis following subacute inhalational exposure to silica: determinants of progression". Pathology. 25 (3): 282–90. PMID 8265248.

Template:WikiDoc Sources

[pmid15699791-1] Rimal B, Greenberg AK, Rom WN (2005). "Basic pathogenetic mechanisms in silicosis: current understanding". Curr Opin Pulm Med. 11 (2): 169–73. PMID 15699791.

[pmid7978983-2] Oberdörster G (1994). ; "Macrophage-associated responses to chrysotile" Check |url= value (help). Ann Occup Hyg. 38 (4): 601–15, 421–2. PMID 7978983.

[pmid7677184-3] Quinlan TR, BéruBé KA, Marsh JP, Janssen YM, Taishi P, Leslie KO; et al. (1995). ; "Patterns of inflammation, cell proliferation, and related gene expression in lung after inhalation of chrysotile asbestos" Check |url= value (help). Am J Pathol. 147 (3): 728–39. PMC 1870980. PMID 7677184.

[pmid7547443-4] Lesur O, Bouhadiba T, Melloni B, Cantin A, Whitsett JA, Bégin R (1995). ; "Alterations of surfactant lipid turnover in silicosis: evidence of a role for surfactant-associated protein A (SP-A)" Check |url= value (help). Int J Exp Pathol. 76 (4): 287–98. PMC 1997178. PMID 7547443.

[pmid7946382-5] Janssen YM, Heintz NH, Marsh JP, Borm PJ, Mossman BT (1994). ; "Induction of c-fos and c-jun proto-oncogenes in target cells of the lung and pleura by carcinogenic fibers" Check |url= value (help). Am J Respir Cell Mol Biol. 11 (5): 522–30. doi:10.1165/ajrcmb.11.5.7946382. PMID 7946382.

[pmid8679218-6] BéruBé KA, Quinlan TR, Fung H, Magae J, Vacek P, Taatjes DJ; et al. (1996). ; "Apoptosis is observed in mesothelial cells after exposure to crocidolite asbestos" Check |url= value (help). Am J Respir Cell Mol Biol. 15 (1): 141–7. doi:10.1165/ajrcmb.15.1.8679218. PMID 8679218.

[pmid9603153-7] Mossman BT, Churg A (1998). "Mechanisms in the pathogenesis of asbestosis and silicosis". Am J Respir Crit Care Med. 157 (5 Pt 1): 1666–80. doi:10.1164/ajrccm.157.5.9707141. PMID 9603153.

[pmid8265248-8] Velan GM, Kumar RK, Cohen DD (1993). "Pulmonary inflammation and fibrosis following subacute inhalational exposure to silica: determinants of progression". Pathology. 25 (3): 282–90. PMID 8265248.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]