Functional exploration and translational research

  • ECTS

    5 credits

  • Component

    Faculty of Science

Description

Neuromuscular physiology:

Striated skeletal muscle: The neuromuscular junction; Contraction/muscle release; Myotypology; Plasticity; Muscle metabolism.

Neuromuscular diseases:Causes; symptoms; clinical diagnosis (clinical examinations; laboratory tests): EMG, blood assays, functional tests, etc.; Muscular dystrophies: Duchenne myopathy; Becker's myopathy; facioscapiohumeral muscular dystrophy (FSHD).Facioscapiohumeral muscular dystrophy FSHD: zebrafish model; mouse model; cell models; clinical trials.

Respiratory physiology:

Respiratory physiology: Anatomy of the respiratory system; mechanism of respiration; gas exchange; transport of respiratory gases by the blood; regulation of respiration

Respiratory exploration in small animals: Why explore respiratory function in small animals? Plethysmography; in vitro contractile force.

Respiratory Functional Explorations: performance and interpretation of respiratory explorations in human pathology; spirometry: Level 1 and Level 2; pulmonary diffusion capacity; arterial blood gas; specific exploration of respiratory muscles; 6-minute walk test; exercise test; explorations with stay at altitude.

Cardiovascular physiology:

Reminder of the anatomy of the heart: size, location and orientation; envelope of the heart; tunics of the heart wall; chambers and large vessels of the heart; blood flow in the heart; heart valves; blood supply to the heart: coronary circulation; properties of the cardiac muscle tissue.

Reminder of the physiology of the heart: regulation of the basic rhythm; conduction system of the heart; modification of the basic rhythm: extrinsic innervation of the heart; electrocardiography; mechanical phenomena: cardiac revolution; cardiac output; regulation of the systolic volume; regulation of the heart rate.

Reminder of vascular physiology: anatomy of the circulatory system; lymphatic system; vascular wall structure; blood pressure; vascular smooth muscle and vasomotricity; endothelial function.

Vascular function and dysfunction; functional exploration: Arterial Distensibility Measurement; arterial wave velocity measurement; pharmacological exploration of endothelium-dependent vasomotricity; ultrasonographic exploration; echotracking; ultrasound and echodoppler.

How to evaluate vascular function experimentally?isolated artery ring model Cardiac Doppler: a fabulous tool in clinical and experimental research; Ultrasound: anatomical and functional analysis"; Doppler: flow analysis; Application to animal models.

Translational research: example myocardial ischemia-reperfusion (myocardial infarction); animal models; isolated perfused heart (Langendorf); isolated cardiomyocytes; cardioprotective techniques.

Endocrinology: weight balance

Description of eating behavior; Energy balance; Central structures regulating food intake; Mechanisms regulating food intake; Factors modulating appetite and food intake; Nutritional assessment; Eating disorders; Functional exploration: impedancemetry; DEXA (X-ray photon absorption); MRI; Assessment of expenditure: calorimetry.

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Objectives

The objective of the "Functional exploration and translational research" course is to provide students with a physiological basis and a methodology for the functional evaluation of the various major functions of the organism (cardiovascular, respiratory, neuromuscular, hormonal, etc.) both in animal models and in humans.

Thus, we want that at the end of this course, the student has a global vision of the physiological effects of a therapeutic principle as well as a methodological knowledge allowing the exploration of a function of the organism within the framework of a preclinical phase to a clinical trial in man.Thus, for each of the major cardiovascular, respiratory, neuromuscular and hormonal functions, we will address their exploration methods both in the preclinical phase (animal models, in vivo and in vitro exploration, etc.) and in humans, in a translational research logic.

During this course, we will also discuss the regulatory environment in animal and human experimentation, as well as the pathways that lead a therapeutic concept from a preclinical phase to a clinical trial.

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Necessary pre-requisites

Basics of physiology; basics of physiology of major functions.

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Knowledge control

Final writing: 100%.

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