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

The study examined how lung hyaluronic acid content influences airspace enlargement in elastase-induced emphysema. To determine the effect of a decrease in hyaluronic acid, hamsters received a single intratracheal instillment of hyaluronidase 24 h prior to administration of pancreatic elastase by the same route. One week later, these animals showed significantly greater airspace enlargement than controls sequentially instilled with saline and elastase (128 vs. 100 microns; p < .05). Conversely, intratracheal administration of hyaluronic acid immediately after elastase instillment resulted in a marked decrease in airspace enlargement at 1 week compared to controls receiving elastase followed by saline (82 vs. 122 microns; p = .005). Since hyaluronic acid has no elastase inhibitory capacity, its effect may involve extracellular matrix interactions not directly related to elastic fiber breakdown. This concept is supported by the finding that animals treated with hyaluronidase and elastase showed no greater loss of lung elastin than that observed in the saline/elastase control group, despite demonstrating a marked increase in airspace enlargement. Further work is needed to determine how hyaluronic acid influences airspace enlargement and to evaluate the potential use of this substance as a treatment for emphysema.
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PMID:Modulation of airspace enlargement in elastase-induced emphysema by intratracheal instillment of hyaluronidase and hyaluronic acid. 762 78

Although emphysema is generally characterized by damage to pulmonary elastic fibers, the causes of such injury appear to be complex and are not entirely explained by a singular imbalance between elastases and their inhibitors. Other factors could compromise elastic fiber integrity. To test the validity of this argument, hamsters were instilled intratracheally with a nonelastolytic enzyme, hyaluronidase (which reduces lung hexuronic acid content by 21% after 24 h), then exposed to an otherwise nontoxic concentration of oxygen (60%) for 4 days. Additional groups were given (1) hyaluronidase and room air, (2) saline and 60% oxygen, and (3) saline and room air. Treatment with both hyaluronidase and 60% oxygen resulted in a significant increase in air-space enlargement at 4 days (67.1 vs. 57.9 microns for saline/room air controls; p < .05), which was accompanied by only minimal inflammatory changes, as determined by both light microscopy and lavage cytology. Animals receiving either hyaluronidase or 60% oxygen alone showed no significant increases in air-space size compared to those given saline and exposed to room air. While the mechanisms responsible for these results are unclear, the marked increase in radiolabeling of lung elastin cross-links (desmosine and isodesmosine) in animals receiving both hyaluronidase and 60% oxygen (429 vs. 168 cpm/g dry lung for saline/room air controls; p < .05), as well as a significant decrease in total lung desmosine and isodesmosine (32.5 vs. 37.7 micrograms/lung for saline/room air controls; p < .05), suggests that elastic fiber damage is a potential factor. Moreover, only those animals receiving both hyaluronidase and 60% oxygen showed a significant rise in cell-free elastase activity in lavage fluids compared to saline/room air controls (83.3 vs. 48.3 ng; p < .05). On the basis of these findings, it is concluded that while elastic fiber damage may be a common pathway in emphysema, the factors that initiate the disease may be more varied than previously suspected and not always related to the balance between elastases and their inhibitors.
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PMID:Pulmonary air-space enlargement induced by intratracheal instillment of hyaluronidase and concomitant exposure to 60% oxygen. 846 61