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Query: UMLS:C0023890 (
cirrhosis
)
42,195
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Determination of the complement titer in the serum and plasm of 120 patients with chronic liver diseases showed that in eight (7%) patients with
cirrhosis of the liver
, chronic active or chronic inactive hepatitis complement in the serum was less than half in the plasma. The dissociation of complement serum and plasma was due to cold activation of the classical pathway of complement in vitro since serum drawn from these patients at 37 degrees C lost hemolytic activity in 4 hours when transferred to a cold environment. Neither HB antigen nor cryoglobulin participated in this phenomenon. The activation of complement in the cold could be prevented by increasing the ionic strength, or by adding vitamin E or, to a lesser extent its vehicle HCO-60, while heparin,
Trasylol
, soybean trypsin inhibitor, or hirudin had no effect. Trans-AMCHA prevented activation in one case. It is speculated that a factor appearing as a result of blood clotting is able to activate the classical pathway of complement in the cold; it is probably not related to Hageman factor (factor XII), factor VII, thrombin, kallikrein.
...
PMID:Cold activation of complement i. presence of coagulation-related activator. 5 81
The protease inhibitor aprotinin was given a) in experimental septic shock, and b) in patients with
hepatic cirrhosis
and ascites, since in both conditions, activation of the plasma kallikrein-kinin system is associated with pathological systemic vasodilatation, which may trigger reflex neuroendocrine activation and renal solute retention. Given early in experimental sepsis, aprotinin maintained the arterial pressure, systemic vascular resistance (SVR), creatinine clearance and sodium excretion, all of which fell in controls.
Aprotinin
also blocked increases in pulmonary artery pressure and plasma renin activity (PRA). Given late in sepsis, aprotinin caused a rapid rise in arterial pressure and SVR towards baseline levels. In
cirrhosis
, aprotinin increased SVR in patients with low baseline values, and improved glomerular filtration rate, renal plasma flow and sodium excretion in all subjects; PRA was suppressed by aprotinin.
Aprotinin
reverses pathological systemic vasodilatation in these two conditions, and this is associated with a reduction in renin release and improved renal function.
...
PMID:Vasoactive effects of aprotinin. 128 72
Aprotinin
has been reported to reduce blood loss in difficult cases requiring cardiopulmonary bypass surgery and more recently in liver transplantation. Over a 9-month period we compared the effects of an intra-operative infusion of aprotinin on transfusion requirements and coagulation profiles in 12 patients undergoing liver transplantation for end-stage
cirrhosis
with an equal number of consecutive transplants in patients with similar pathology who did not receive aprotinin. Transfusion of blood and blood products was reduced to one-third in the aprotinin-treated group. Operative time was also significantly reduced, as was ICU stay post-operatively.
Aprotinin
profoundly inhibits fibrinolysis and this is likely to be the major effect by which blood loss is reduced. Thromboelastography revealed severe fibrinolytic changes in the anhepatic stage in 4 of 6 controlled patients; this accelerated in 3 following reperfusion of the new graft. By contrast, only 1 patient of 12 in the aprotinin-treated group showed fibrinolytic activity in the anhepatic period, and none showed evidence of fibrinolysis following reperfusion of the new graft.
...
PMID:The intra-operative use of trasylol (aprotinin) in liver transplantation. 172 74
During hepatic resection, occlusion of the hepatoduodenal ligament has been frequently applied to prevent intraoperative bleeding. To reduce hepatocellular ischemic damage in this procedure, we pretreated animals with
Aprotinin
. Three hours after an intravenous injection of 40,000 KIU
Aprotinin
in SD rats, we occluded the afferent hepatic vessels for 50-min and 60-min periods. 92% of occluded animals could sustain life after 60 min. Without premedication only 17 of 25 animals (68%) survived the 50-min occlusion, and 18 of 32 (56%) the 60-min occlusion. Biochemical analysis of sera was carried out 12 hr after a 40- and 60-min occlusion of the hepatoduodenal ligament with
Aprotinin
pretreatment. Furthermore we induced compensatory
cirrhosis
by application of CCL4 and biochemical analysis of sera was carried out after a 30-min occlusion. The elevation of SGOT and SGPT values was drastically reduced in the animals with
Aprotinin
medication in comparison with those without treatment. These observations suggest the highly protective effect of
Aprotinin
in the case of warm ischemic hepatic damage, especially in the cirrhotic liver. After pretreatment of LEW rats with
Aprotinin
(40,000 KIU i.v.), we perfused the livers with chilled Ringer solution containing 40,000 KIU
Aprotinin
/20 ml. We transplanted the livers orthotopically into LEW rats. With the application of
Aprotinin
liver preservation time increased to 10-15 hr. However, without
Aprotinin
the livers could be successfully preserved for only 4-6 hr. Our results indicated that premedication with high doses of
Aprotinin
provided highly protective effects against warm and cold ischemic damage of the liver.
...
PMID:Protective effect of aprotinin on ischemic hepatocellular damage. 169 21
1. Previous studies have documented activation of protease enzymes, such as the plasma kallikrein-kinin system, in
hepatic cirrhosis
. Increased plasma kinin generation could contribute to pathological systemic vasodilatation in
cirrhosis
, and reduced systemic vascular resistance has been suggested as a trigger to renal sodium retention in this disease. We investigated the effect of aprotinin, a protease inhibitor which binds to plasma kallikrein, on systemic haemodynamics and renal function in patients with
hepatic cirrhosis
and ascites. 2.
Aprotinin
was infused intravenously in high dosage (2 x 10(6) kallikrein inhibitory units loading, 1 x 10(6) kallikrein inhibitory units/h). 3. Of 13 patients, 10 had a low systemic vascular resistance (< 1200 dyn s cm-5) at baseline. In this group, eight showed an increase in systemic vascular resistance during aprotinin infusion. Overall, the increase in systemic vascular resistance was significant, and there was a small but significant increase in mean arterial pressure. In all patients, there were increases in renal plasma flow, glomerular filtration rate, and absolute and fractional urinary sodium excretion during aprotinin infusion. 4. Plasma renin activity, plasma angiotensin II and plasma aldosterone fell significantly during aprotinin infusion. Plasma prekallikrein, plasma noradrenaline and plasma atrial natriuretic peptide did not change. Plasma aprotinin concentration was 209 +/- 11 kallikrein inhibitory units/ml at the end of the infusion. 5. Before and during the infusion, there was a significant negative correlation between systematic vascular resistance and plasma renin activity. There was a positive correlation between the change in systemic vascular resistance and the change in renal plasma flow during aprotinin infusion.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Effect of the serine protease inhibitor, aprotinin, on systemic haemodynamics and renal function in patients with hepatic cirrhosis and ascites. 752 42
The origin of blood loss during liver surgery is multifactorial. Surgical skill, technique, anesthesiological care, but also hyperfibrinolysis have been shown to play a role in the origin of bleeding during partial hepatectomy and liver transplantation. The latter has provided the scientific basis for the prophylactic use of antifibrinolytic drugs, such as aprotinin and nafamostat mesilate in liver surgery. Recently however, concern has been voiced about potential risks associated with aprotinin, including renal failure and thromboembolic events. In this review we discuss the efficacy and safety issues of aprotinin and nafamostat mesilate in liver surgery. We identified a total of 19 studies on the use of either aprotinin or nafamostat mesilate in liver surgery reported in the time period between 1966 and July 2006. The use of aprotinin or nafamostat mesilate in partial hepatectomies was studied in three studies. In 16 studies the use of aprotinin in liver transplantation was investigated. With respect to partial hepatectomy, improvements in surgical technique and anesthesiological care seem to be more important in reducing blood loss than the use of the antifibrinolytic drugs.
Aprotinin
may be indicated in a selected group of patients with
cirrhosis
undergoing liver resection, but further studies in this specific group of patients will be needed. In liver transplantation, the use of aprotinin is associated with a significant reduction in blood loss and transfusion requirements of around 30-40%. Results of prospective studies do not provide support for safety concerns as no increased risk for thromboembolic events or renal dysfunction has been observed in liver transplant patients treated with aprotinin. In conclusion, there is currently no scientific support for the routine use of aprotinin or nafamostat mesilate in patients undergoing partial hepatectomy, whereas the efficacy of aprotinin in liver transplantation is well established. More studies will be needed to address the safety aspects of aprotinin in patients undergoing liver surgery in more detail.
...
PMID:Aprotinin and nafamostat mesilate in liver surgery: effect on blood loss. 1765 53
