Cardiovascular & Hematological Agents in Medicinal Chemistry

ISSN: 1871-5257

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Contents


Clinical Profile of Eprosartan: A Different Angiotensin II Receptor Blocker, 2008, 6, 253-257
P.J. Blankestijn and H. Rupp
[Abstract] [Full Text Article]


Role of Cellular Elements in Thrombus Formation and Dissolution, 2008, 6, 224-228
N. Wohner
[Abstract] [Full Text Article]


The Involvement of Blood Coagulation Factor XIII in Fibrinolysis and Thrombosis, 2008, 6, 190-205
L. Muszbek, Z. Bagoly, Z. Bereczky and É. Katona
[Abstract] [Full Text Article]



Abstracts


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Clinical Profile of Eprosartan: A Different Angiotensin II Receptor Blocker
P.J. Blankestijn and H. Rupp

[Full Text Article]

The goal of antihypertensive treatment is to reduce risk of cardiovascular morbidity and mortality. Apart from blood pressure lowering per se, also reducing the activities of the renin-angiotensin system and sympathetic nervous system appears to be important. Angiotensin II receptor blocker drugs (ARBs) have provided a useful class of anti-hypertensive drugs. Eprosartan is a relatively new ARB which is chemically distinct (non-biphenyl, non-tetrazole) from all other ARBs (biphenyl tetrazoles). An analysis has been made on available experimental and clinical data on eprosartan which not only is an effective and well tolerated antihypertensive agent, but also lowers the activities of the renin-angiotensin system and sympathetic nervous system. Experimental and pharmacokinetic studies on eprosartan have shown differences with the other ARBs. The distinct properties of this non-biphenyl, non-tetrazole ARB might be relevant in the effort to reduce cardiovascular risk, also beyond its blood pressure lowering capacity.


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Role of Cellular Elements in Thrombus Formation and Dissolution
N. Wohner

[Full Text Article]

Although fibrin forms the core matrix of thrombi, their structure depends also on the cellular elements embedded in its meshwork. Platelets are essential in the initial stages of thrombus formation, because they adhere and aggregate at sites of blood vessel wall injury and then serve as a surface for coagulation reactions, the overall rate of which determines the final structure of fibrin. In addition, platelets affect fibrinolysis through their proteins and phospholipids, which modulate plasmin activity. Leukocytes form mixed aggregates with platelets and thus influence the structure of thrombi. After activation they secrete different proteases (elastase, cathepsin G, matrix metalloproteinases) that enhance the von Willebrand factor-dependent platelet adhesion. Leukocyte-derived enzymes, first of all elastase, effect fibrinolysis by direct digestion of fibrin or indirectly modulate it by partial degradation of zymogens and inhibitors of coagulation and fibrinolytic proteases.


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The Involvement of Blood Coagulation Factor XIII in Fibrinolysis and Thrombosis
L. Muszbek, Z. Bagoly, Z. Bereczky and É. Katona

[Full Text Article]

It has been known for a long time that blood coagulation factor XIII (FXIII) is essential for maintaining haemostasis, its deficiency leads to severe bleeding complication. Biochemical studies have revealed that FXIII is a key regulator of fibrinolysis and, in addition to its role in haemostasis, it has also been implicated in the pathology of arterial and venous thrombosis. Most recently, the polymorphisms in the FXIII subunit genes and their influence on the risk of thrombotic diseases have stirred a lot of interest. This review, besides including the basic biochemistry of FXIII, mainly concentrates on the biochemical and clinical aspects of the involvement of FXIII in fibrinolysis and thrombosis.

Biochemical aspects: Basics on the structure and activation of plasma and cellular FXIII. The enzymological features of activated FXIII and its main substrates. The interaction of FXIIIa with fibrinogen/fibrin and with components of the fibrinolytic system. The impact of cross-linked fibrin clot formation on the fibrinolytic processes. The down-regulation of FXIIIa within the fibrin clot. FXIII polymorphisms and their biochemical consequences.

Clinical Aspects: FXIII level and the risk of arterial thrombosis (coronary artery disease, peripheral artery disease, ischemic stroke). The effect of FXIII subunit polymorphisms on the risk of arterial thrombotic diseases. The interplay between FXIII polymorphisms and other factors influencing the risk of arterial thrombosis. FXIII and venous thromboembolism.