Results 251 to 260 of about 600,025 (282)
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Aspirin resistance and diabetic angiopathy: back to the future
Thrombosis Research, 2004Human platelet concentrates stored at 22 jC for transfusion purposes, although functionally useful in vivo, progressively lose their aggregation potential in vitro in response to high concentrations of aggregating agents employed singly. In contrast, they retain full aggregation potential and thromboxane B2 biosynthesis in response to low ...
Giovanni Di Minno, VIOLI, Francesco
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Non-invasive characterisation of angiopathy in the diabetic foot
European Journal of Vascular Surgery, 1988A comparison between 19 consecutive insulin dependent diabetic patients with a history of or current foot ulcers, gangrene or infection, with 14 arteriosclerotic patients with advanced lower limb ischaemia was performed using measurements of ankle and great toe systolic blood pressure, forefoot skin perfusion pressure and pulse volume assessment ...
Mauri Lepäntalo +4 more
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Fragmentation Haemolysis in Patients with Severe Diabetic Angiopathy
British Journal of Haematology, 1976Haemolytic anaemia associated with prominent red cell fragmentation is described in seven patients with long‐standing diabetes mellitus. A common feature in the patients was severe microangiopathy as detected by retinal examination and microscopic examination of the kidneys. Renal or pancreatic islet malfunction per se is not involved in the haemolytic
Richard D. Brunning +4 more
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Diabetic capillary angiopathy in human skeletal muscles
The American Journal of Medicine, 1966Abstract Skeletal muscle biopsy specimens from diabetic and nondiabetic subjects were examined by light and electron microscopy. Distinctive lesions in the capillaries were found in twelve of sixteen specimens from diabetic subjects but in only three of nineteen from nondiabetic subjects.
D. Laurence Wilson +3 more
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On Some Factors Related to the Pathogenesis of Diabetic Angiopathy
Acta Medica Scandinavica, 1982ABSTRACT. The deterioration of the circulation in small and large vessels in diabetes seems to be related to abnormalities of the function of the endothelial cells and of the platelets. The endothelial factor VIII R:Ag, enhancing platelet adhesion, is increased, while fibrinolysis is decreased.
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Angiopathy and Neuropathy in Mild Juvenile Diabetes
1973Publisher Summary This chapter describes the angiopathy and neuropathy in mild juvenile diabetes. The chapter presents the plasma insulin response patterns to glucose and tolbutamide in patients with mild juvenile diabetes. In an experiment described in the chapter, these patterns were compared with those of 14 classic juvenile diabetics and 12 young
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Diabetic angiopathy—its lessons in vascular physiology
American Heart Journal, 1978Progress in our understanding diabetic angiopathy has been slow, but we are now learning a number of lessons of interest to the cardiologist. Diabetic angiopathy is a collective term for conditions specific to the diabetic state and related to its duration more than to patient age.
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Possible pathophysiological mechanisms for diabetic angiopathy in type 2 diabetes
Journal of Diabetes and its Complications, 2000The expression of large and small vessel disease in type 2 diabetes differs from that observed in type 1, with a higher prevalence of atherosclerosis and hypertension, maculopathy rather than proliferative retinopathy, and nephropathy of a more complex nature.
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Large Vessel Disease in Diabetics — A Specific Diabetic Angiopathy?
1978Diabetic small vessel disease, or diabetic microangiopathy, is known to be a specific vascular abnormality, caused in some way by the metabolic and endocrine aberrations characterizing diabetes mellitus. It is not present at the acute onset of classical juvenile diabetes, but develops slowly in the course of many years.
N. J. Christensen +3 more
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MicroRNA-216b actively modulates diabetic angiopathy through inverse regulation on FZD5.
Gene, 2018Yuxiang Dai +11 more
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