9 research outputs found
Effect of derivatives of trapidil on the expression of LDL receptors
The influence of trapidil and some of its derivatives (AR 12456, AR 12463, AR 12465) on the LDL receptor mediated uptake and degradation of 125 I-LDL by human skin fibroblasts (HSF) and human hepatic cells (HEP G2) was investigated. AR 12456 enhanced the uptake and degradation of 125 I-LDL in HEP G2, but inhibited this pathway in HSF. When this drug was preincubated with HEP G2 cells, and then the incubation medium was transferred to HSF, a stimulation of specific LDL pathway occurred also in this cell line. Trapidil, AR 12463 and AR 12465 were inactive under the same experimental conditions. These findings suggest that a metabolite of AR 12456 might be responsible for the enhanced expression of LDL receptors in human cells
Trapidil derivatives and low density lipoprotein metabolism by human skin fibroblasts and by human hepatoma cell line Hep G2
The effect of trapidil (RocornalR) and some of its newly developed derivatives (AR 12456, AR 12463, AR 12465, AR 12464) on the receptor-mediated low density lipoprotein (LDL) binding, uptake and degradation was studied in human skin fibroblasts (HSF) and in human hepatoma cell line Hep G2. Compound AR 12456 influenced this pathway in a selective way: it enhanced the uptake and degradation of 125I-LDL by Hep G2 cells in a dose-dependent manner, but inhibited it in HSF. Scatchard analysis of the saturable LDL binding in Hep G2 indicates that the effect of compound AR 12456 is the result of an increased number of LDL binding sites. Compound AR 12465 was less effective on LDL catabolism. Trapidil and the other derivatives were inactive under the same experimental conditions. When Ar 12456 was preincubated with Hep G2 cells and then the incubation medium was transferred to HSF, a stimulation of specific LDL pathway occurred also in this cell line. These findings suggest that a metabolite(s) of AR 12456 might be responsible for the enhanced expression of LDL receptors in cultured human cells
Die Nutzung hepatischer Funktionen fuer in vitro-Verfahren zur Pruefung von Stoffen mit dem Ziel der Einsparung von Tierversuchen Abschlussbericht
SIGLEAvailable from TIB Hannover: DtF QN1(77,15) / FIZ - Fachinformationszzentrum Karlsruhe / TIB - Technische InformationsbibliothekBundesministerium fuer Bildung und Forschung (BMBF), Bonn (Germany)DEGerman
What is the role of a-linolenic acid for mammals?
This review examines the data pertaining to an important and often underrated EFA, α-linolenic acid (ALA). It examines its sources, metabolism, and biological effects in various population studies, in vitro, animal, and human intervention studies. The main role of ALA was assumed to be as a precursor to the longer-chain n-3 PUFA, EPA and DHA, and particularly for supplying DHA for neural tissue. This paper reveals that the major metabolic route of ALA metabolism is β-oxidation. Furthermore, ALA accumulates in specific sites in the body of mammals (carcass, adipose, and skin), and only a small proportion of the fed ALA is converted to DHA. There is some evidence that ALA may be involved with skin and fur function. There is continuing debate regarding whether ALA has actions of its own in relation to the cardiovascular system and neural function. Cardiovascular disease and cancer are two of the major burdens of disease in the 21st century, and emerging evidence suggests that diets containing ALA are associated with reductions in total deaths and sudden cardiac death. There may be aspects of the action and, more importantly, the metabolism of ALA that need to be elucidated, and these will help us understand the biological effects of this compound better. Additionally, we must not forget that ALA is part of the whole diet and should be seen in this context, not in isolation.<br /