Synopses & Reviews
There is a paradox in hypertension: whereas the pathophysiological mechanisms of the disease have been related principally to a constriction of small arteries, most of the complications refer to damage of the large arteries, particularly at the site of the brain, the kidney and the heart. In the past, large arteries were poorly investigated in hypertension mainly in terms of change in blood flow. Recent studies clearly show that the large arteries are largely involved in the mechanisms of hypertension not only through changes in mean blood flow, but rather through changes in stiffness of the arterial wall. This aspect may be a key-point for the development of hypertensive complications. Subsequently, the goal of treatment may be not only blood pressure reduction but also improvement of structural and functional abnormalities of the large vessels. These therapeutic aspects are analyzed in detail in the present book.
Synopsis
MICHEL E. SAFAR and MICHAEL F. O'ROURKE One of the principal problems of hypertension is the precise definition of blood pressure as a cardiovascular risk factor. Clinicians indicate peak systolic pressure and end diastolic pressure in the brachial artery as the principal criteria for blood pressure measurement. Consequently, these values are as indicators for clinical management and therapeutic adjustment. This used methodology, based on indirect blood pressure measurements at the site of the brachial artery relates only to the highest and lowest pressure in that vessel, and does not give any information of the blood pressure curve itself; this carries more information than peak systolic pressure and end diastolic pressure. As a first step in better analysis of the blood pressure curve, research workers in experimental hypertension defined in addition to peak systolic pressure and end diastolic, another blood pressure value, mean arterial pressure, i. e. the average pressure throughout the cardiac cycle, and about which pressure fluctuates. This is the pressure recorded by Hales 1] and by Poiseuille 2] in their pioneering studies. By application of Poiseuille's Law, this definition of mean arterial pressure led to the concept that increased mean arterial pressure (and therefore hypertension) was related, at any given value of cardiac output, to an increase in vascular resistance, i. e. to a reduc- tion in the caliber of the small arteries.
Table of Contents
Introduction;
M.E. Safar, M.F. O'Rourke. 1. Mechanical Stress of the Arterial Wall and Hypertension;
S. Laurent. 2. Hypertension and the Conduit and Cushioning Functions of the Arterial Tree;
M.F. O'Rourke. 3. Wave Reflections and the Pathophysiology of Hypertension;
R.D. Latham, D.M. Slife. 4. Structure of the Arterial System in Hypertension;
C.L. Berry, J.A. Sosa-Melgarejo. 5. Cyclic Quasonine Monophosphate, Smooth Muscle Tone and Mechanical Properties of Large Arteries;
M.C. Mourlon-Le Grand, B.I. Lévy. 6. Signals Regulating Arterial Contractile Function and Growth in Hypertension: Role of Angiotensin II and Nitric Oxide;
J.-B. Michel, J.-F. Arnal. 7. Large Arteries and Epidemiological Aspects of Hypertension;
W. McFate Smith. 8. Non-Invasive Study of the Local Mechanical Characteristics in Humans;
A.P.G. Hoeks. 9. Geometry and Stiffness of the Arterial Wall in Essential Hypertension;
M.E. Safar. 10. Arterial System, Left Ventricular Structure and Function;
R. Gourgon, A. Cohen-Solal. 11. Autonomic Nervous System and Large Conduit Arteries: Pathophysiological and Therapeutic Aspects;
G.M. London, M.E. Safar. 12. Large Arteries and Sodium in Hypertension: Pathophysiological and Therapeutic Aspects;
A. Benetos, M.E. Safar. 13. Large Arteries and Calcium in Hypertension: Pathophysiological and Therapeutic Aspects; G
.M. London, B.I. Lévy. 14. Wave Reflections: Clinical and Therapeutic Aspects;
G.M. London, T. Yaginuma. Index.