Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0341503 (bacterial peritonitis)
 1,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The quantitative and qualitative characteristics of cells in the peritoneal dialysate from 12 patients were examined. The number of cells in each subsequent fraction of dialysate decreased, while the differential cell count remained relatively constant for each individual patient. Macrophages, lymphocytes, granulocytes and occasionally mesothelial cells were observed. In 1 patient, plasmocytes were also found. Evident differences in cellularity and cell composition were noticed in dialysate obtained from different patients, especially in 2 patients with bacterial peritonitis there was a rise in cellularity with neutrophilia. Cytochemical (peroxidase, nonspecific esterase activity) and functional (phagocytosis, receptor expression) tests revealed that macrophages form a heterogeneous population of cells.
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PMID:Output of peritoneal cells into peritoneal dialysate. Cytochemical and functional studies. 663 57

Neutrophil (PMN) influx into the peritoneal cavity in response to bacterial peritonitis is an indispensable aspect of host defense. PMNs also are responsible for the remote organ injury observed after major abdominal infection. The aim of this study was to examine the effect of selectin blockade on PMN migration into the peritoneum and on PMN sequestration in the lungs, early in the course of peritonitis. Cecal ligation and puncture (CLP) was performed on P-selectin-deficient (P-def) mice and their genetic controls (C57). Both groups were treated with anti-E-selectin antibody, anti-L-selectin, or isotypic control immunoglobulin G at the time of CLP. 6 h after CLP, mice were sacrificed. Peritoneal PMN migration decreased in P-def mice compared with C57 controls after CLP. Blockade of E- or L-selectin alone in controls did not alter peritoneal PMN influx or circulating PMNs after CLP. In the P-def mice, treatment with anti-E-antibody or anti-L-antibody nearly eliminated PMN influx into the peritoneum. In contrast, circulating PMNs markedly increased after CLP in P-def mice when compared with baseline values. Lung myeloperoxidase increased in all groups of mice following CLP. Blockade of P-selectin with anti-P-selectin antibody elicited a response similar to that observed in the P-def mice. In conclusion, P-selectin mediates PMN influx into the peritoneal cavity, while E- and L-selectins do not appear to play any significant role in the 6 h time period following CLP. Lung PMN sequestration, after CLP, occurred independent of P-, E-, or L-selectin expression. Blockade of P-selectin during peritonitis appears to be potentially deleterious by preventing early PMN influx into the compartment containing the septic focus.
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PMID:Neutrophil migration into the peritoneum is P-selectin dependent, but sequestration in lungs is selectin independent during peritonitis. 978 58

Leukocyte apoptosis is an energy-dependent process that facilitates resolution of the cellular inflammatory response. Levels of apoptosis can be accelerated or inhibited after exposure to various stimuli. To compare apoptosis in transmigrated leukocytes, two models of peritonitis in mice were used that both cause leukocyte influx into the peritoneal cavity: (1) intraperitoneal thioglycollate administration producing a sterile peritonitis and (2) cecal ligation and puncture (CLP) producing a polymicrobial bacterial peritonitis. Samples of blood and peritoneal exudate cells (PEC) were collected at multiple time points after induction of peritonitis. Leukocytes were either fixed immediately to determine an immediate apoptosis level or cultured for 24 h to determine a delayed apoptosis level. Apoptosis was assessed using terminal uridine-triphosphate nick-end labeling (TUNEL) assay, flow cytometry, and confocal microscopy. Leukocyte influx into the peritoneal cavity was confirmed in both models. At all time points, and in both models, there was increased immediate apoptosis in PEC compared with unmanipulated controls and this increase was maximal in CLP after 18 h, although it appeared to remain at a stable level in the sterile peritonitis model by 3 h. There was also an increase in PEC delayed apoptosis at early time points in both models, again maximal at 18 h for CLP, with the levels being significantly higher than the thioglycollate model at 6 h and 18 h. The mice had a relative peripheral neutropenia at 6 h after CLP, but not post thioglycollate injection, and this persisted until 42 h. Lung and liver MPO levels were elevated in CLP but did not increase after thioglycollate. There was no increase in immediate peripheral leukocyte apoptosis in either model, but an increase in delayed peripheral leukocyte apoptosis was observed by 18 h in both models. Peripheral leukocyte CD1lb expression, which is a marker of activation, was also persistently elevated in the CLP model, but not in sterile peritonitis. In conclusion, CLP is a more potent stimulus for apoptosis of leukocytes than their migration to the site of inflammation alone, as occurs in the thioglycollate model. Blood leukocyte apoptosis also appears not to be dependent on CD11b expression, and therefore activation status.
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PMID:Immediate and delayed leukocyte apoptosis in two models of peritonitis. 1183 42