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Query: UMLS:C0034067 (emphysema)
 11,506 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The lung contains a host of extracellular matrix components that comprise the supporting and adhesive elements of conducting airways, alveoli and the vascular tree. While none of these components is unique to the lung, their peculiar distribution determines the architecture and function of this gas exchange organ. Cells and tissues of the lung interact with the matrix through a variety of surface receptors, especially the integrins and adhesive molecules, some of which may play important roles in lung injury and repair. Collagen type I is the predominant determinant of tensile strength, but as many as 11 other genetic types of collagen with specialized adhesive and connecting functions can be found in various lung structures, including cartilage and basement membranes. Excessive matrix accumulation in the lung is the result of a complex set of influences on gene regulation, part of which may be due to the presence of inflammatory cytokines that directly stimulate matrix synthesis. However, degradation and turnover of the matrix are also critical processes influenced by many of the same mediators. Collagenase and gelatinase (type IV collagenase) are tightly-regulated metalloenzymes that, together with a set of specific inhibitors of metalloproteinases, determine the net abundance and distribution of collagen. Elastases of several biochemical types are also under tight regulation by proteinase inhibitors. Elastin is essential to lung function at the level of alveolar wall resiliency and patency, and loss of elastin in emphysema appears to be due to uncontrolled degradation of the embryologically-established pattern of elastic fibres accompanied by nonfunctional replacement as a response to injury. Injury to the vascular endothelium of the lung, as well as other physiological insults that elevate pulmonary blood pressure, can lead to the excessive accumulation of collagen and elastin in the conductance and resistance arteries of the pulmonary circulation. Mechanical stress and endothelial injury may mediate the medial hypertrophy of these vessels. Extracellular matrix components are critically involved in every stage of lung biology: development, normal function and acute and chronic disease states. To date, only glucocorticoids, cross-linking inhibitors, and protease inhibitors have been used in a general attempt to suppress either excessive matrix accumulation or loss. More detailed understanding of the regulation and specific interactions of matrix components is central to the analysis of disease states and the development of appropriate therapeutic strategies.
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PMID:Biochemistry and turnover of lung interstitium. 228 53

Emphysema is produced by severe food restriction in rats and is postulated to result from depletion of lung connective tissue. We studied (1) whether total dietary protein depletion worsens nutritional emphysema, and (2) whether the reduced content of lung connective tissue in nutritional emphysema results from lack of accumulation caused by impaired lung growth or by a net loss from the lung. Lewis rats weighing 200 g were restricted to one third food intake with or without protein for 6 wk. Lungs were assessed by morphometry, pressure-volume (P-V) measurements, and content of collagen and elastin. Emphysema was found by morphometry (but not by P-V measurements) in food-restricted rats, and contrary to expectation, emphysema was less severe in those depleted of protein. Collagen and elastin content were reduced in emphysematous lungs; however, the levels were not below those found prior to nutritional intervention, suggesting that lack of growth, not depletion, accounts for the reduced content.
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PMID:Nutritional emphysema in the rat. Influence of protein depletion and impaired lung growth. 387 94

Collagen is the major structural protein of the lung. At least five genetically distinct collagen types have been identified in lung tissue. However, the precise role of collagen in nonrespiratory lung function is not well understood, in part because of the difficulties inherent in studying lung collagen, regardless of the type of assay used. A major problem is the insolubility of lung collagen; generally less than 20% of total lung collagen can be solubilized as intact chains, even with harsh extraction procedures. Since such collagen may not be representative of total lung collagen, errors in quantitating collagen types, for example, may arise from using such material. Measurement of total lung collagen content may also pose problems, unless appropriate parameters of normalization are chosen. Biopsy dry weight, protein content, and DNA content, for example, may all change in certain disease states. Despite these difficulties, a number of changes in lung collagen have been documented in experimental pulmonary fibrosis, including increased collagen content, increased collagen synthesis rates, and changes in collagen type ratios. Many questions remain. For example, why do diverse toxic substances appear to cause essentially the same fibrotic response, even though initial sites of damage may vary? Conversely, why do similar toxic substances, such as ozone and NO2, cause diverse responses (fibrosis and emphysema, respectively)? Much work remains to be done to elucidate the mechanisms underlying the lung's choice of response.
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PMID:Collagen biosynthesis. 642 77

An extracellular connective tissue matrix, made up of components found in the pulmonary alveolar interstitium, was generated in vitro and used as a culture surface and substrate for proteolysis by human alveolar macrophages (AM) and neutrophil elastase (NE). The ability of human AM to modulate NE-mediated degradation of elastin and collagen in the surrounding matrix was studied to gain insights into the inflammatory process that accompanies the pathogenesis of emphysema in humans. Neutrophil elastase that had been internalized by AM showed a diminished but more prolonged time course of matrix proteolysis than did a similar amount of NE added to the matrix in the absence of AM. Collagen and elastin degradation were quantitated by release of hydroxylysine and desmosine, respectively, into the culture medium. Significantly more hydroxylysine and desmosine were released by AM that had internalized NE than by AM or by culture medium alone. When 14 X 10(6) AM were added to the extracellular matrix, followed 2 h later by addition of 2 micrograms of NE, collagen and elastin degradation measured at 24 h were not significantly different from that which occurred when matrix was incubated with NE in the absence of AM. Collagen degradation, determined in the same cultures during the period from 24 to 96 h, was significantly greater when matrix was incubated with both AM and NE. These findings suggest that AM can release previously internalized NE in an enzymatically active form and that AM may enhance collagen degradation in matrix that was also exposed to NE.
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PMID:Alveolar macrophage modulation of proteolysis by neutrophil elastase in extracellular matrix. 656 97

The tight-skin (Tsk) mouse is a genetic model of pulmonary emphysema. In this mouse, right ventricular hypertrophy (RVH) starts to develop at approximately 8 months of age, probably as a consequence of the emphysema. The aim of the present study was to investigate cardiac collagen synthesis, content, and types both before and during the development of RVH. Collagen synthesis, assessed by the [3H]proline incorporation method, was significantly increased in the right ventricle of 3-month-old Tsk mice. This was accompanied by a marked increase in right ventricle collagen content. Collagen typing showed no difference from controls. At 8 months of age collagen synthesis had returned to control values, right ventricular collagen content was elevated but held lower values than at 3 months, and collagen typing showed a prevalence of the more compliant type III. By 16 months of age, right ventricular collagen content had returned to control values and there was a shift in collagen types due to a relative increase of the more rigid type I. At 24 months of age right ventricular collagen content was increased again and collagen type I continued to predominate. These results suggest a dynamic role for collagen both before and during the development of RVH secondary to emphysema.
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PMID:Cardiac collagen changes during the development of right ventricular hypertrophy in tight-skin mice with emphysema. 807 May 38

We examined the expression of interstitial collagenase and its enzymatic activity in lung damage induced by tobacco smoke. Guinea pigs were exposed to the smoke of 20 cigarettes per day from 1-8 wk. Age-matched guinea pigs were used as controls. At 6 and 8 wk of smoke exposure, lungs exhibited interstitial and peribronchiolar inflammation and moderate emphysematous changes. In situ hybridization of injured lungs revealed patchy expression of collagenase mRNA mainly in macrophages but also in alveolar epithelial and interstitial cells. Immunoreactive protein was detected in alveolar macrophages and in the alveolar walls and interstitium. Collagenolytic activity increased beginning in the 4th wk of exposure (0.7 +/- 0.43 micrograms collagen degraded/mg collagen incubated relative to 0.23 +/- 0.14 in controls; P < 0.05). At 6 and 8 wk, values were 0.85 +/- 0.34 and 0.98 +/- 0.33 compared with 0.25 +/- 0.11 and 0.26 +/- 13 in controls (P < 0.005 and 0.001). Collagen concentration decreased from 50.7 +/- 8.5 mg/g dry wt in control lungs to 40.2 +/- 5.0 and 42.9 +/- 6.0 at 6 and 8 wk of exposure, respectively (P < 0.05). These results strongly suggest that increased interstitial collagen degradation plays a role in the development of lung emphysema.
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PMID:Tobacco smoke-induced lung emphysema in guinea pigs is associated with increased interstitial collagenase. 894 16

Treatment of hamster lungs with porcine pancreatic elastase (PPE) causes emphysema and a decrease in lung elastin content, which returns to control level by Day 30. To explore the mechanism of alveolar wall remodeling after elastolytic injury, we examined the expression of elastin and alpha1(I) collagen mRNAs by in situ hybridization at 1, 2, 3, 5, 7, and 30 d after intratracheal PPE. The lungs of control animals displayed weak signals for elastin and alpha1(I) collagen mRNA in pleura, large arteries, veins, and airways. There was little or no signal in respiratory air space walls. Increased expression of elastin and alpha1(I) collagen mRNA began by Day 1 after PPE and reached an asymptote by Day 3 that was maintained by elastin until Day 7; expression of alpha1(I) collagen mRNA waned earlier. Elastin and, to a lesser extent, alpha1(I) collagen mRNA were heavily expressed in pleura, blood vessels, and airways. Analysis of serial sections showed elastin message was minimal in the walls of respiratory air spaces and when present, at 3, 5, and 7 d, was primarily found at the free margins of alveolar septa. Collagen message was very sparse in respiratory air space walls. By 30 d, elastin mRNA expression was reduced but still above control levels and emphysema was widespread and severe. Rank score of elastin mRNA expression in individual subpleural air spaces showed a positive correlation with air space size. In conclusion, most expression of elastin and alpha1(I) collagen mRNA occurs in the pleura, airway, and vascular walls. In respiratory air space walls, expression of elastin mRNAs occurs in damaged tissue at free septal margins.
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PMID:Remodeling of alveolar walls after elastase treatment of hamsters. Results of elastin and collagen mRNA in situ hybridization. 970 Jan 35

The fibrinolytic system is known to play an important role in the protection of lung architecture and function. This study investigated the effects on lungs of inhibiting the fibrinolytic system using tranexamic acid (TXA). Thirty cats were used, 15 experimental and 15 control. TXA was administered intravenously to the experimental animals for 3 h at 200 mg/kg (acute) and 7 days at 100 mg/kg (chronic). Blood samples were obtained from the carotid artery. The acute dose cats were sacrificed at 3 h and 24 h and the chronic dose cats at 8 days. Samples of inflated and fixed lung were examined morphologically and their collagen contents were determined. Fibrinolytic activity in blood samples was determined by fibrinogen degradation products levels, fibrin plate lytic area diameter, and the euglobulin lysis time. Hyperemia, lung interstitial oedema, haemorrhaging, inflammatory cell infiltration, pneumocyte type II cell proliferation, thrombosis and emphysema-related changes, characterized by enlargement of air spaces accompanied by destruction of alveolar walls, were observed in experimental cats group. None of these alterations except hyperemia and lung interstitial oedema were observed in two control animals. Electron microscopy results revealed oedema fluid in the interstitium, proliferation of pneumocyte type II cells, thickening of the alveolar septa and presence of marked amounts of collagen. Vacuoles were seen in the capillary endothelial cells. Elastic tissue was observed as elastic masses and partly disrupted, although elastic fibers were not prominent in all parts of the interstitium. Collagen content in the chronic dose experimental group was significantly higher than in all control and acute dose experimental groups. The inhibition of fibrinolytic system appears to have caused the emphysematous alterations, alveolar wall destruction and collagen accumulation possibly by causing microthromboses leading to mechanical blockage-ischemic changes, or by causing secondary fibrinolysis as a result of fibrin degradation products affecting local plasminogen activators and proteases. An injury-repair process also appears to have occurred.
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PMID:Biochemical and morphological alterations in lungs induced by experimental inhibition of fibrinolytic activity. 1248 20

Collagen and elastin fibers are the major components of the lung connective tissue, but their spatial organization has not been well documented. We have demonstrated the three-dimensional architecture of collagen and elastin fiber networks in the human and rat lung using scanning electron microscopy. These networks in their original forms were extracted by an alkali-water maceration technique and a formic acid treatment, respectively. The collagen fibers formed a continuum extending throughout the lung and pleura. They were condensed in the alveolar mouth and subdivided into smaller fibers in the alveolar septa, thus forming basket-like networks. Sizes of the alveolar pores in the collagen fiber network of the alveolar septa became larger with age. In the collapsed lung, collagen fibers in the alveolar mouths and septa took on wavelike configurations, while in the inflated lung they became straight. The elastin fibers also formed a continuum, rich in the alveolar mouths and poor in the alveolar septa, were quite straight without any wavelike configuration. Transmission electron microscopy showed that collagen and elastin fibers were intermingled, suggesting that both fiber systems may act as parallel mechanical elements to stress or strain applied. Our results suggest that at low levels of strain the wavy collagen fibers are easily extended to allow alveolar mouths and alveoli to expand, with most of the stress being borne by adjacent elastin fibers, while at higher levels collagen fibers become straight and limit any further distension of alveolar ducts and alveoli. The elastin fiber continuum appears to permit the lung to effectively recoil or retract. The present study has also shown that alveolar pores enlarge with age, suggesting that collagen remodeling may be related to the pathogenesis of emphysema.
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PMID:Three-dimensional architecture of elastin and collagen fiber networks in the human and rat lung. 1512 21

In this review, we examine how the extracellular matrix (ECM) of the lung contributes to the overall mechanical properties of the parenchyma, and how these properties change in disease. The connective tissues of the lung are composed of cells and ECM, which includes a variety of biological macromolecules and water. The macromolecules that are most important in determining the mechanical properties of the ECM are collagen, elastin, and proteoglycans. We first discuss the various components of the ECM and how their architectural organization gives rise to the mechanical properties of the parenchyma. Next, we examine how mechanical forces can affect the physiological functioning of the lung parenchyma. Collagen plays an especially important role in determining the homeostasis and cellular responses to injury because it is the most important load-bearing component of the parenchyma. We then demonstrate how the concept of percolation can be used to link microscopic pathologic alterations in the parenchyma to clinically measurable lung function during the progression of emphysema and fibrosis. Finally, we speculate about the possibility of using targeted tissue engineering to optimize treatment of these two major lung diseases.
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PMID:Extracellular matrix mechanics in lung parenchymal diseases. 1848 36


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