Review of Feline Pancreatitis Part One: The Normal Feline Pancreas, the Pathophysiology, Classification, Prevalence and Aetiologies of Pancreatitis

Total-, free-, and acylcarnitine concentrations were determined in whole blood, plasma, and red blood cells of 88 women during pregnancy. Already in the 12th week of gestation the mean whole blood carnitine level was significantly (p < 0.01) lower than those of the controls. From the 12th gestational week up to parturition there was a further significant (p < 0.01) decrease. This reduction of total carnitine in whole bloods was mainly caused by a significant (p < 0.01) decrease of free carnitine levels, since no marked changes of short chain acylcarnitine values were found throughout pregnancy. The contribution of red blood cell L-carnitine to whole blood carnitine increased significantly (p < 0.05) to 61% at delivery versus 39% (controls). In umbilical cord blood free and total carnitine levels were significantly (p < 0.05) higher than the corresponding maternal levels. The contribution of red blood cell L-carnitine to whole blood carnitine was higher in cord blood than in maternal blood. The results of the present study demonstrate that during pregnancy whole blood and plasma carnitine levels decrease to those levels found in patients with carnitine deficiency. Also the percentage of acylcarnitine on total carnitine, found in the present study, is characteristic for a secondary carnitine deficiency. Thus L-carnitine substitution in pregnant women, especially in risk pregnancies, may be advantageous.

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Membrane transport of nucleobases: Interaction with inhibitors

Kraupp

März

1995

General Pharmacology: The Vascular System

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Thymidine transport in cultured mammalian cells. Kinetic analysis, temperature dependence and specificity of the transport system

Wohlhueter¹,

März²,

Plagemann³

1979

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Tuning research competences for Bologna three cycles in medicine: report of a MEDINE2 European consensus survey

et al. 2013

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Medical curricula, like healthcare systems and medical practice, have a strong cultural component and vary considerably between countries. Increasing mobility of medical graduates, and increasing pressure to ensure they are all fit for practice, have highlighted an urgent need to establish common ground in learning outcomes at all stages of training. A research-based approach, developed by the Tuning project, was used previously by the MEDINE Thematic Network to gain consensus on core learning outcomes/competences for primary medical degrees (www.tuning-medicine.com), but no consensus was reached for learning outcomes relating to research. As part of MEDINE2, a focussed Tuning project was undertaken to explore opinions on more detailed core learning outcomes in research for all three Bologna cycles (Bachelor, Master, and Doctor). Responses from 417 stakeholders, representing 29 European and 13 non-European countries, revealed a relatively high degree of consensus. The findings strongly suggest that these stakeholders think that learning outcomes related both to ‘using research’ and ‘doing research’ should be core components of medical curricula in Europe. The challenge now, however, is to promote further local and international discussion on these issues, and to find ways of achieving these competences within the context of already crowded medical curricula.

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Adenosine transport and metabolism in mouse leukemia cells and in canine thymocytes and peripheral blood leukocytes

Lum

März

Plagemann

et al. 1979

Journal Cellular Physiology

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The intracellular accumulation of free 13H1 adenosine was measured by rapid kinetic techniques in P388 murine leukemia cells in which adenosine metabolism (phosphorylation and deamination) was completely prevented by depletion of cellular ATP and by treatment with deoxycoformycin. Nonlinear regression of integrated rate equations on the data demonstrate that the time courses of labeled adenosine accumulation at various extracellular adenosine concentrations in zero-trans and equilibrium exchange protocols are well described by a simple, completely symmetrical, transport model with a carrier:substrate affinity constant of about 150 pM. Adenosine transport was not affected by 1 mM deoxycoformycin indicating that this analog has a low affinity for the nucleoside transport system. The transport capacity of dog thymocytes and peripheral leukocytes was similar to that of P388 cells. Transport was not inhibited by deoxycoformycin and remained constant during the first two hours after mitogenic stimulation with concanavalin A. In untreated, metabolizing P388 cells transport was found to be the major determinant of the rate of intracellular metabolism, regardless of the extracellular adenosine concentration (up to a t least 160 pM), but the long-term accumulation (longer than 30-60 seconds) of radioactivity from extracellular adenosine strictly reflected the rate of formation of nucleotides (mainly ATP). The metabolism of adenosine by whole cells was entirely consistent with the kinetic properties of the transport system and those of the metabolic enzymes.At low exogenous adenosine concentrations (1 pM and below) transport was slow enough to allow direct phosphorylation of most of the entering adenosine. The remainder was deaminated and rapidly converted to nucleotides via inosine, hypoxanthine, and IMP. At concentrations of 100 p M or higher, on the other hand, influx exceeded the maximum velocity of adenosine kinase about 100 times so that most of the entering adenosine was deaminated. But since the maximum velocity of adenosine deaminase exceeded those of nucleoside phosphorylase and hypoxanthinelguanine phosphoribosyltransferase about 5 and 100 times, respectively, hypoxanthine and inosine rapidly exited from the cells and accumulated in the medium. A 98% reduction of adenosine transport (at 100 pM), caused by the transport inhibitor Persantin, inhibited adenosine deamination by whole cells to about the same extent as transport, whereas adenosine phosphorylation was relatively little affected; thus in the presence of Persantin, transport and metabolism resembled that occurring at the low adenosine concentration. These and other results indicate that adenosine deamination is an event distinct from transport, which occurs only subsequent to adenosine's transport into the cell.

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Richard März

Computer literacy and attitudes towards e-learning among first year medical students

Team-based Learning in Intensive Course Format for First-year Medical Students

Chapter 16 A Rapid-Mixing Technique to Measure Transport in Suspended Animal Cells: Applications to Nucleoside Transport in Novikpff Rat Hepatoma Cells

Pregnancy-related changes of carnitine and acylcarnitine concentrations of plasma and erythrocytes

Membrane transport of nucleobases: Interaction with inhibitors

Thymidine transport in cultured mammalian cells. Kinetic analysis, temperature dependence and specificity of the transport system

Tuning research competences for Bologna three cycles in medicine: report of a MEDINE2 European consensus survey

Adenosine transport and metabolism in mouse leukemia cells and in canine thymocytes and peripheral blood leukocytes

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