Coronary thrombolysis with facilitated absorption of intramuscularly injected tissue-type plasminogen activator

Contact dermatitis

Contact dermatitis (CD) is among the most common inflammatory dermatological conditions and includes allergic CD, photoallergic CD, irritant CD, photoirritant CD (also called phototoxic CD) and protein CD. Occupational CD can be of any type and is the most prevalent occupational skin disease. Each CD type is characterized by different immunological mechanisms and/or requisite exposures. Clinical manifestations of CD vary widely and multiple subtypes may occur simultaneously. The diagnosis relies on clinical presentation, thorough exposure assessment and evaluation with techniques such as patch testing and skin-prick testing. Management is based on patient education, avoidance strategies of specific substances, and topical treatments; in severe or recalcitrant cases, which can negatively affect the quality of life of patients, systemic medications may be needed.

What role does the stress response have in congestive heart failure?

This review is concerned with cardiac malfunction as a result of an imbalance in protein proteostasis, the homeostatic balance between protein removal and regeneration in a long remodeling process involving the endoplasmic reticulum (ER) and the unfolded protein response (UPR). The importance of this is of special significance with regard to cardiac function as a high energy requiring muscular organ that has a high oxygen requirement and is highly dependent on mitochondria. The importance of mitochondria is not only concerned with high energy dependence on mitochondrial electron transport, but it also has a role in the signaling between the mitochondria and the ER under stress. Proteins made in the ER are folded as a result of sulfhydryl groups (-SH) and attractive and repulsive reactions in the tertiary structure. We discuss how this matters with respect to an imbalance between muscle breakdown and repair in a stressful environment, especially as a result of oxidative and nitrosative byproducts of mitochondrial activity. The normal repair is a remodeling, but under this circumstance, the cell undergoes or even lysosomal "self eating" autophagy, or even necrosis instead of apoptosis. We shall discuss the relationship of the UPR pathway to chronic congestive heart failure (CHF).

High and constant plasma levels of tissue plasminogen activator and PEG-hirudin can be achieved by subcutaneous delivery

Intramural thrombosis is a consistent finding in the arteries of patients who die following coronary angioplasty. This thrombosis is thought to have a role in restenosis, which is a common complication of coronary angioplasty. It has been hypothesised that antithrombotics such as hirudin or tissue-type plasminogen activator (tPA), may be therapeutically useful following angioplasty. This report describes the bioavailability of both agents following subcutaneous (sc) injection in cholesterol-fed rabbits. Intravenously delivered tPA has a half-life of 3-5 minutes. The half-life of intravenously administered hirudin is less than one hour in many species. In order to prolong the duration of action recombinant hirudin was conjugated to polyethylene glycol (PEG). Polyethylene glycol conjugated recombinant hirudin (PEG-rH) (0.7 mg/kg) antigen and activity were measurable after just 1 hr, reaching a maximum (663 and 884 ng/ml respectively) at 12 hours. Significant levels were present in rabbit plasma 24 hours after injection. Subcutaneously delivered recombinant (r-tPA) (1 mg/kg) was present in significant amounts 1 hr after injection, reaching a maximum (92 IU/ml) at 2 hours. Levels of tPA at 9 hours were approximately 80x normal circulating levels. High and constant levels of functional activity of both PEG-rH and r-tPA in rabbit plasma are achieved by subcutaneous delivery.

Augmented and sustained plasma concentrations after intramuscular injections of molecular variants and deglycosylated forms of tissue-type plasminogen activators

We have previously explored induction of coronary thrombolysis with tissue-type plasminogen activator (t-PA) administered intramuscularly. Absorption-enhancing agents that rendered the approach feasible were identified, but large amounts of activator were required and initial elevations of concentrations in plasma could not be sustained. The present study was designed to determine whether more therapeutically favorable plasma concentrations could be induced by genetically engineering or chemically modifying t-PA to prolong its half-life based on the hypothesis that the ratio of absorption to clearance would be increased. Each of four genetically engineered variants (one variant with growth factor and kringle 1 domains deleted and kringle 2 duplicated, a second variant with a cysteine for Arg substitution in the growth factor domain, a third variant with an additional urokinase kringle inserted, and a fourth variant with the growth factor domain deleted) and enzymatically deglycosylated t-PA exhibited prolonged half-life after bolus intravenous injection in rabbits. Each elicited substantially higher and more sustained elevations in plasma after intramuscular injection in rabbits or dogs with absorption-enhancing agents as compared with wild-type t-PA that were not accompanied by a systemic lytic state. Thus, use of molecular variants of t-PA with prolonged half-lives in the circulation permits induction of augmented and sustained elevations of plasma concentrations after intramuscular injection with absorption-enhancing agents as compared with wild-type t-PA, rendering potentially therapeutic blood levels more attainable with relatively modest amounts of material.

Tissue-type plasminogen activator. A review of its pharmacology and therapeutic use as a thrombolytic agent

Coronary arterial thrombolysis is becoming an established treatment of acute myocardial infarction. If given early enough, it recanalises occluded coronary arteries, salvages myocardial function and reduces mortality. A reduction of mortality in patients with acute myocardial infarction has now been demonstrated for streptokinase, anisoylated plasminogen streptokinase activator complex (APSAC; anistreplase) and recombinant tissue-type plasminogen activator (rt-PA). From the biochemical point of view, rt-PA has several attractive properties. It is similar to or identical with the physiological plasminogen activator in blood, it does not induce an antibody response, and it is more fibrin-specific than most or all other currently known thrombolytic agents. The rate of recanalisation of occluded coronary arteries with rt-PA is about 60 to 80% in non-comparative and placebo-controlled trials. rt-PA was similar in efficacy to urokinase in the only trial to compare the 2 agents. In 2 comparative trials evaluated by meta-analysis, rt-PA appeared more effective than streptokinase for the early recanalisation of occluded arteries. Both agents were comparable in their effects on left ventricular function in 2 comparative trials, but further study is needed to conclusively evaluate this parameter. Moreover, both agents reduce inhospital mortality, but much larger direct comparative trials are required before scientifically valid statements can be made on the relative clinical efficacy of available thrombolytic agents in terms of their effects on both morbidity and mortality. Thus, rt-PA constitutes a notable contribution of recombinant DNA technology to the treatment of thromboembolic disease, the main cause of death and disability in Western societies.

[Antibody mediated thrombolysis. A new therapeutic principle]

Thrombosis of a coronary artery is the most common cause of myocardial infarction. Thrombolytic therapy, when instituted timely, has been shown capable of reducing morbidity and mortality. However, the use of presently available thrombolytic agents is associated with a bleeding tendency and efficacy is not optimal. This article reviews one of several lines of investigation that are presently being pursued in order to improve efficacy and specificity of thrombolytic therapy. The chemical conjugation of a fibrin specific monoclonal antibody and urokinase or tissue plasminogen activator results in markedly enhanced thrombolytic potency, both in vitro and in vivo. Specificity of the conjugates is greater than that of the parent plasminogen activators as reflected by conservation of fibrinogen, plasminogen and alpha-2 antiplasmin. A bispecific antibody, with specificity for both, fibrin and tissue plasminogen activator, has the potential of concentrating endogenous tissue plasminogen activator at the site of a thrombus. In the presence of the bispecific antibody, efficacy and specificity of tissue plasminogen activator are markedly enhanced in vitro and in vivo. The tools of molecular biology are presently being applied in order to translate these findings into better thrombolytic therapy.

The thrombolytic effects of native tissue-type plasminogen activator (AK-124) on experimental canine coronary thrombosis

To evaluate the thrombolytic effects of the native tissue-type plasminogen activator (t-PA), the authors used a thrombus model simulating clinical situations. The native t-PA (AK-124) was obtained from human-derived normal cells. Experimental canine coronary thrombosis was produced by partial constriction and endothelial denudation of the vessel. In 19 dogs, coronary occlusive thrombus was produced. Three hours after total occlusion of the coronary artery with thrombus, the authors attempted the thrombolytic therapy in 16 dogs. Histologically, three-hour thrombus was composed of a mixture of platelet aggregates, fibrin, and blood cells. They infused 0.375 mg/kg t-PA intravenously in 7 dogs and 20,000 IU/kg urokinase (UK) in 9. Coronary recanalization was achieved in 5 (71%) with t-PA infusion and 6 (67%) with UK infusion. Plasma fibrinogen levels decreased to 76% of preinfusion value in the dogs with t-PA infusion and to 34% in those with UK infusion. Coronary reocclusion occurred in 2 dogs with t-PA and 3 with UK. Thus, the native t-PA (AK-124) can provide coronary thrombolysis without severe depletion of plasma fibrinogen levels.

Feline aortic thromboemboli and the potential utility of thrombolytic therapy with tissue plasminogen activator

Feline aortic thromboembolism is a common and devastating clinical condition for which there is presently no effective therapy. Thrombolytic therapy with tissue plasminogen activator represents a promising, relatively noninvasive method for resolution of the clinical syndrome. In clinical trials in man, tissue plasminogen activator is proving to have advantages over previously available thrombolytic agents. Previously available thrombolytic agents require intensive monitoring and commonly cause complications that entail large monetary and manpower costs to monitor and control. Being specific for thrombus-associated plasminogen, t-PA enables more safe and effective thrombolysis without the hazards previously associated with thrombolytic therapy. In cats with aortic thromboemboli, early clinical trials are promising with regard to acute thrombolytic efficacy but raise questions concerning the risks and benefits of therapy and will require more controlled studies. It is estimated that t-PA therapy for a cat with aortic thromboemboli will cost approximately +500 to +1500, including hospitalization and drugs. This compares favorably with what most veterinary clients are willing to spend for quality veterinary care. However, before we can look upon t-PA therapy as a useful therapeutic advance, we must consider the etiopathogenesis and probability of rethrombosis. The results of controlled studies have not been published, but it is generally considered that there is a high probability of recurrence in cats. Fifty per cent of cats treated with t-PA have rethrombosed despite aspirin therapy at the recommended dose of 25 mg per kg every third day. Finding a cure for feline myocardial diseases (cardiomyopathies) and/or an effective method for safely anticoagulating cats at risk would help justify the monetary and manpower costs associated with thrombolytic therapy.(ABSTRACT TRUNCATED AT 250 WORDS)

Newer emergency reperfusion techniques in acute myocardial infarction

We have given an overview of the management of the acute myocardial infarction patient utilizing the aggressive reperfusion techniques available today. Anatomic reperfusion rates have been over 95% with the combined methods described. The remaining problems technically are those of earlier reperfusion, methods to enhance myocardial recovery after ischemia, and prevention of restenosis or reocclusion. The use of laser methodology, coronary sinus retroperfusion, partial left heart bypass, and other innovative strategies may improve these results. The introduction of tissue plasminogen activator will affect our approach and will profoundly alter society's expectations of therapeutic success. Still, patients will die from acute myocardial infarction and its complications. The search for a prevention must, therefore, not be overshadowed by our current enthusiasm for reperfusion techniques. Hopefully, our current approach will become a historical footnote as breakthroughs in preventive strategies occur.

Intramuscular administration of human tissue-type plasminogen activator in rabbits and dogs and its implications for coronary thrombolysis

To determine whether sustained plasma concentration of human tissue-type plasminogen activator (t-PA) can be induced promptly after intramuscular injection with enhancers of absorption devoid of deleterious local and systemic effects, we studied 250 rabbits and 13 dogs. In rabbits with t-PA injected directly into exposed muscle followed by local electrical stimulation at the site, early absorption was increased markedly by addition of 0.63M methylamine plus 0.079M hydroxylamine to the excipient. Elevations peaked within 5 min and increased with dose of t-PA, concentration of methylamine, and volume of injection medium. The enhancers were effective with percutaneous injections in the absence of local electrical stimulation as well. They did not elicit any obviously deleterious local or systemic effects. In separate experiments in rats, intramuscular injections of 0.63M methylamine plus 0.079M hydroxylamine induced local egress of intravascular radiolabeled albumin within the injection site and endothelial gaps in venules detected with colloidal carbon--changes consistent with direct effects on vascular permeability. In dogs, percutaneous intramuscular injection of t-PA in excipient without enhancers did not lead to early elevations of human t-PA in plasma, although late elevations were seen. When the enhancers were used, early elevations occurred as well, with functional activity documented by fibrin plate assays of serially obtained plasma samples and by sequential coronary angiography delineating thrombolysis after experimentally induced coronary thrombosis. The results indicate that intramuscular administration of t-PA with selected enhancers of absorption is a feasible approach for rapid induction of fibrinolysis.

Plasminogen activators and their potential in therapy

Plasminogen activators (PAs) are proteases that convert plasminogen to plasmin. Plasmin, in turn, is a protease that can lyse a fibrin clot and, therefore, PAs have a primary role in fibrinolysis. Two PAs, urokinase (UK) and streptokinase (SK), have been available for therapeutic use for years. Unfortunately, both can cause systemic fibrinogenolysis and other side effects which have limited their use. Interest has focused on a different enzyme, tissue plasminogen activator (t-PA), which will cause specific clot lysis without systemic problems. The gene for t-PA has been cloned and many biotechnology firms are preparing to produce t-PA for therapeutic use. The properties and potential for therapy of t-PA are reviewed and compared to new forms of other activators, such as pro-urokinase. How the interactions of PAs and inhibitors may affect the use of PAs is also discussed.

Coronary thrombolysis with tissue-type plasminogen activator (t-PA): emerging strategies

Fundamental observations and the conceptual framework underlying coronary thrombolysis have a history dating back to 1789. Recent enthusiasm for it is predicated on the recently established safety of cardiac catheterization in critically ill patients, the high incidence of coronary thrombosis underlying acute transmural myocardial infarction and demonstrable benefit conferred to the heart and the patient when thrombolysis is initiated early after the onset of ischemia. Clot-selective activators of the fibrinolytic system offer promise for safe induction of coronary thrombolysis without marked predisposition to bleeding. One such activator, tissue-type plasminogen activator (t-PA), has been synthesized by recombinant deoxyribonucleic acid (DNA) technology, amenable to large scale production of pharmaceutical agents and hence widespread availability. Initial clinical trials conducted with t-PA have demonstrated opening rates of completely occluded, infarct-related coronary arteries of approximately 75% without marked depletion of fibrinogen. The focus of research in progress includes: noninvasive delineation of recanalization and estimation of the extent of myocardium salvaged by initial recanalization, development of alternative routes of administration of thrombolytic agents potentially exploitable by paramedical personnel and, perhaps, high risk patients themselves, and definitive elucidation of the extent to which benefits conferred by thrombolysis can be enhanced with adjunctive pharmacologic interventions as well as early angioplasty or surgery.

Prevention of coronary thrombosis with subthrombolytic doses of tissue-type plasminogen activator

To determine whether tissue-type plasminogen activator (t-PA) may prevent coronary thrombosis or accelerate the lysis of clot formed under conditions in which increased concentration of the activator is present before thrombosis, clot lysis studies were undertaken in vitro and in vivo. In vitro, exogenous t-PA (6 to 100,000 ng/ml) accelerated the lysis of clot in a dose-dependent fashion when the clot was formed either from whole plasma or from euglobulin fractions (n = 316 determinations). Adding t-PA before clot formation shortened the time to lysis by at least threefold with euglobulin fractions and by at least 10-fold with whole plasma clots, which is consistent with the presence of inhibitors of fibrinolysis in whole plasma and with the binding of t-PA to nascent fibrin. In an intact dog preparation of coronary thrombosis (n = 25), occlusive thrombus formation was prevented when t-PA was present in subthrombolytic concentrations (430 to 1200 ng/ml, n = 5). Occlusive thrombus formation occurred after only discontinuation of the t-PA infusion and clearance of t-PA. Lower concentrations of t-PA (147 to 427 ng/ml, n = 6) significantly delayed occlusion (26 +/- 6.5 vs 7.8 +/- 2.8 min for controls). In animals with t-PA concentrations of less than 140 ng/ml (n = 4), the time to occlusion was unaltered (7.7 +/- 4.5 min). The present study demonstrates that t-PA present before clot formation inhibits thrombosis or accelerates thrombolysis depending on concentration, and that subthrombolytic doses of t-PA can prevent thrombus formation in vivo.(ABSTRACT TRUNCATED AT 250 WORDS)