Nonproteolytic neuroprotection by human recombinant tissue plasminogen activator
Human recombinant tissue plasminogen activator (tPA) may benefit ischemic stroke patients
by dissolving clots. However, independent of thrombolysis, tPA may also have deleterious
effects on neurons by promoting excitotoxicity. Zinc neurotoxicity has been shown to be an
additional key mechanism in brain injuries. Hence, if tPA affects zinc neurotoxicity, this may
provide additional insights into its effect on neuronal death. Independent of its proteolytic
action, tPA markedly attenuated zinc-induced cell death in cortical culture, and, when …
by dissolving clots. However, independent of thrombolysis, tPA may also have deleterious
effects on neurons by promoting excitotoxicity. Zinc neurotoxicity has been shown to be an
additional key mechanism in brain injuries. Hence, if tPA affects zinc neurotoxicity, this may
provide additional insights into its effect on neuronal death. Independent of its proteolytic
action, tPA markedly attenuated zinc-induced cell death in cortical culture, and, when …
Human recombinant tissue plasminogen activator (tPA) may benefit ischemic stroke patients by dissolving clots. However, independent of thrombolysis, tPA may also have deleterious effects on neurons by promoting excitotoxicity. Zinc neurotoxicity has been shown to be an additional key mechanism in brain injuries. Hence, if tPA affects zinc neurotoxicity, this may provide additional insights into its effect on neuronal death. Independent of its proteolytic action, tPA markedly attenuated zinc-induced cell death in cortical culture, and, when injected into cerebrospinal fluid, also reduced kainate seizure–induced hippocampal neuronal death in adult rats.
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