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Query: UMLS:C0149871 (
deep vein thrombosis
)
12,364
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Low molecular weight heparins (LMWHs) are considered to be the agent of choice for the prophylaxis of
DVT
in medical and surgical patients. Conventionally, these agents have been produced by fractionation of or by chemical or enzymatic depolymerization of native heparin. The fractionated heparin retains many of its biological properties such as AT III affinity and sulfate content gamma-irradiation (60Co) has been used to depolymerize GAGs (De Ambrosi et al. In: biomedical and Biotechnological Advances in Industrial Polysaccharides, pp. 45-53). This procedures has now been used for the preparation of LMWH derivatives of varying molecular weight. The current studies examine the biochemical and pharmacologic profile of one such gamma-irradiated depolymerized heparin. In standard clotting and amidolytic antiprotease assays (PT, APTT, AXa, Alla), gamma-irradiated depolymerized heparin produced equal or stronger activity when compared to a LMWH produced by
nitrous acid
depolymerization and retained the ability to active AT III and HCHII. Initial results indicate that LMWHs produced by gamma-irradiation exhibit comparable antithrombotic actions to those produced by chemical depolymerization when measured in animal models of thrombosis. gamma-Irradiation may be a useful method for the production of LMWHs.
...
PMID:Pharmacologic profile of a low-molecular-weight heparin depolymerized by gamma-irradiation. 766 Jan 43
Reviparin is a low-molecular-weight heparin (LMWH) prepared by controlled
nitrous acid
digestion of porcine mucosal heparin. The trade name designation for this agent is Clivarin. This agent has been released in Germany and France for the prophylaxis of
deep venous thrombosis
(
DVT
) in surgical patients. This agent is developed utilizing optimized procedures and exhibits a uniform, narrow-molecular-weight distribution in comparison to the other commercially available LMWHs. The specific activity in the anticoagulant assays is approximated to be 32 U/mg whereas the specific activity in terms of anti-Xa units is designated 120 aXa U/mg. Reviparin is capable of producing a dose- and time-dependent antithrombotic effect in animal models of thrombosis. While the ex vivo effects are initially presented at antithrombotically active dosages, this agent has been found to produce antithrombotic effects without any detectable ex vivo actions. This agent is also known to release tissue factor pathway inhibitor (TFPI) after both intravenous (IV) and subcutaneous (SC) administration. Repeated administration of Reviparin produces progressively stronger antithrombotic effects. Similarly, the bleeding as measured by rabbit ear blood loss is also progressively increased. However, the ratio between the dosage producing these effects is quite large. The current studies are designed to provide additional data on the molecular profile using new calibration methods and additional results on the pharmacologic studies in a dose-dependent manner. In particular, the release of TFPI following IV and SC administration in a primate model is described. The effect of repeated administration mimicking the post-surgical prophylaxis of
DVT
is also reported in terms of any augmentation of the antithrombotic or hemorrhagic effects of these agents.
...
PMID:Pharmacologic validation of the clinical effects of an optimized low-molecular-weight heparin-reviparin. 766 Jan 44
Some major developments in the area of antithrombotic therapy have occurred during the past decade. Of these, the concept of fractionation of heparin has resulted in the development of several products from this agent. The introduction of low molecular weight heparins (LMWHs) has added a new chapter to the prophylactic and therapeutic management of thromboembolic disorders. These agents are now globally accepted as drugs of choice for post-surgical prophylaxis of
deep vein thrombosis
(
DVT
). Currently, the LMWHs are being developed for various therapeutic and cardiovascular indications. Reviparin is an optimized LMWH prepared by controlled
nitrous acid
digestion of porcine mucosal heparin. This drug has been developed using validated procedures and exhibits a relatively narrow molecular weight distribution in contrast to most other commercially available LMWHs. The specific activity in anticoagulant assays is approximately 32 U/mg whereas the specific activity in terms of anti-Xa units is 120 anti-Xa U/mg. Reviparin is capable of producing a dose- and time-dependent antithrombotic effect in animal models of thrombosis. While the ex vivo effects initially occur at dosages that are antithrombotic, this agent has been found to produce sustained antithrombotic effects without any detectable ex vivo anticoagulant actions. This agent has also been found to release tissue factor pathway inhibitor (TFPI) after both intravenous and subcutaneous administration. Repeated administration of reviparin produces progressively stronger antithrombotic effects. The current studies are designed to provide additional data on its molecular profile using new calibration methods and additional results on the pharmacological studies in a dose-dependent manner. In particular, the release of TFPI following i.v. and s.c. administration in a primate model is described. The effect of repeated administration mimicking the post-surgical prophylaxis of
DVT
is also reported in terms of any increase in the antithrombotic or haemorrhagic effects of this agent. Comparative antithrombotic and pharmacological studies are also reported to compare the pharmacological profiles of reviparin, nadroparin and enoxaparin.
...
PMID:Preclinical studies on a low molecular weight heparin. 882 24
The introduction of low-molecular-mass heparins (LMMHs) has added a new dimension to the prophylactic and therapeutic management of thromboembolic disorders. These agents are now globally accepted as drugs of choice for postsurgical prophylaxis of
deep vein thrombosis
(
DVT
). Currently, the LMMHs are being developed for various therapeutic and cardiovascular indications. Reviparin is an optimized LMMH prepared by controlled
nitrous acid
digestion of porcine mucosal heparin. This drug has been developed utilizing validated procedures and exhibits a relatively narrow molecular mass distribution in contrast to most other commercially available LMMHs. The specific activity in the anticoagulant assays is approximately 40 U/mg whereas the specific activity in amidolytic anti-Xa assays is approximately 100 anti-Xa U/mg. Reviparin is capable of producing dose- and time-dependent antithrombotic effects in animal models of thrombosis. Although ex vivo anticoagulant effects are initially observed at dosages that are antithrombotic, this agent has been found to produce sustained antithrombotic effects when ex vivo anticoagulant actions are not measurable. Repeated administration of this LMMH induces progressively stronger antithrombotic effects. This drug has also been found to release tissue factor pathway inhibitor (TFPI) following both intravenous (IV) and subcutaneous (SC) administration. The studies included in this article are designed to provide additional data on the molecular profile using new calibration methods and additional results on pharmacologic studies. In particular, the release of TFPI following IV and SC administration to nonhuman primates is described. The effect of repeated administration of Reviparin mimicking the postsurgical prophylaxis of
DVT
is also reported in terms of any augmentation of the antithrombotic or hemorrhagic effects of this agent.
...
PMID:Biochemical and pharmacologic characteristics of Reviparin, a low-molecular-mass heparin. 920 Mar 35
The low molecular weight heparins (LMWHs) are now not only used for the prophylaxis and treatment of
deep vein thrombosis
(
DVT
), but also for the management of acute coronary syndromes. Beside these approved usages, the LMWHs have been developed for indications such as thrombotic and ischaemic stroke, cancer-associated thrombotic and vascular disorders, Alzheimer's disease and a variety of inflammatory disorders. In the United States, there are three approved LMWHs (enoxaparin, dalteparin and ardeparin). In Canada, reviparin and tinzaparin are also approved. The European Union has taken the lead; eight LMWHs are approved for various indications. Certoparin represents one of the earlier LMWHs used for
DVT
prophylaxis and treatment, with additional indications currently under development. Certoparin represents an isoamyl nitrite depolymerised LMWH with comparable structural characteristics to other
nitrous acid
depolymerised products such as nadroparin and reviparin. While comparable in structure to dalteparin, this agent differs in function due to a secondary purification process that is employed in the manufacture of dalteparin. The preclinical pharmacology of this drug has been extensively investigated. Although indication specific dosing and the optimisation of use in, for example, acute coronary syndromes and thrombotic stroke, may be require, certoparin represents a typical LMWH with comparable performance characteristics to some other agents. This chapter describes some of the preclinical and clinical pharmacologic characteristics of this drug. This information will be useful in designing clinical trials for newer indications of this drug.
...
PMID:Pharmacologic profile of certoparin. 1599 81
Low-molecular weight heparins (LMWHs), as compared with unfractionated heparin (UFH), present superior bioavailability, much longer plasma half-life, and lower incidence of side effects. For these reasons, over the past two decades LMWHs have become the drugs of choice for the treatment of
deep venous thrombosis
, pulmonary embolism, arterial thrombosis, and unstable angina. Furthermore, their use in acute ischemic stroke is currently under study. LMWHs are obtained by UFH depolymerization, which can be performed using various methods, including
nitrous acid
depolymerization, cleavage by beta-elimination of benzyl ester, enzymatic depolymerization, and peroxyl radical-dependent depolymerization. This article addresses the chemical depolymerization, obtained by free radical attack (mainly hydroxyl radical), of heparin. The electron spin resonance (ESR) spectroscopy, coupled to the spin trapping technique, was employed to study this reaction. Free radical-mediated heparin depolymerization was performed under different chemical conditions. The final products of the reactions were purified and classified on the basis of their molecular weight and other characteristics. The level of heparin fragmentation was different depending on the type of depolymerization reaction used. Moreover, the level of reproducibility and the resulting radical species were different for every type of reaction performed.
...
PMID:Free radical generation during chemical depolymerization of heparin. 1609 71
