Progesterone: therapeutic opportunities for neuroprotection and myelin repair

Progesterone and its metabolites promote the viability of neurons in the brain and spinal cord. Their neuroprotective effects have been documented in different lesion models, including traumatic brain injury (TBI), experimentally induced ischemia, spinal cord lesions and a genetic model of motoneuron disease. Progesterone plays an important role in developmental myelination and in myelin repair, and the aging nervous system appears to remain sensitive to some of progesterone's beneficial effects. Thus, the hormone may promote neuroregeneration by several different actions by reducing inflammation, swelling and apoptosis, thereby increasing the survival of neurons, and by promoting the formation of new myelin sheaths. Recognition of the important pleiotropic effects of progesterone opens novel perspectives for the treatment of brain lesions and diseases of the nervous system. Over the last decade, there have been a growing number of studies showing that exogenous administration of progesterone or some of its metabolites can be successfully used to treat traumatic brain and spinal cord injury, as well as ischemic stroke. Progesterone can also be synthesized by neurons and by glial cells within the nervous system. This finding opens the way for a promising therapeutic strategy, the use of pharmacological agents, such as ligands of the translocator protein (18 kDa) (TSPO; the former peripheral benzodiazepine receptor or PBR), to locally increase the synthesis of steroids with neuroprotective and neuroregenerative properties. A concept is emerging that progesterone may exert different actions and use different signaling mechanisms in normal and injured neural tissue.     

Neuroprotection: Present and future

The treatment of brain diseases (regardless of the latter's neurological or psychiatric expression) is based on either preventive, symptomatic or etiopathogenic approaches. The frequent observation of neuronal death during brain disease initially prompted researchers to favour neuroprotection for the etiopathogenic approach. The repeated failure to develop reliable neuroprotective agents has prompted emergence of the concept of "disease modifyer". The disease modifyer concept (based essentially on clinical endpoints) enables us to envisage the broader application of etiopathogenic treatments by freeing ourselves of the need to demonstrate a cellular mechanism of action. The formalization of disease modification prompts several lines of thought, which are developed in the present article.     

Mechanisms of neuronal cell death in ischemic stroke and their therapeutic implications

Ischemic stroke caused by arterial occlusion is the most common type of stroke, which is among the most frequent causes of disability and death worldwide. Current treatment approaches involve achieving rapid reperfusion either pharmacologically or surgically, both of which are time-sensitive; moreover, blood flow recanalization often causes ischemia/reperfusion injury. However, even though neuroprotective intervention is urgently needed in the event of stroke, the exact mechanisms of neuronal death during ischemic stroke are still unclear, and consequently, the capacity for drug development has remained limited. Multiple cell death pathways are implicated in the pathogenesis of ischemic stroke. Here, we have reviewed these potential neuronal death pathways, including intrinsic and extrinsic apoptosis, necroptosis, autophagy, ferroptosis, parthanatos, phagoptosis, and pyroptosis. We have also reviewed the latest results of pharmacological studies on ischemic stroke and summarized emerging drug targets with a focus on clinical trials. These observations may help to further understand the pathological events in ischemic stroke and bridge the gap between basic and translational research to reveal novel neuroprotective interventions.     

VEGF-induced neuroprotection,neurogenesis, and angiogenesis after focal cerebral ischemia

Vascular endothelial growth factor (VEGF) is an angiogenic protein with therapeutic potential in ischemic disorders, including stroke. VEGF confers neuroprotection and promotes neurogenesis and cerebral angiogenesis, but the manner in which these effects may interact in the ischemic brain is poorly understood. We produced focal cerebral ischemia by middle cerebral artery occlusion for 90 minutes in the adult rat brain and measured infarct size, neurological function, BrdU labeling of neuroproliferative zones, and vWF-immunoreactive vascular profiles, without and with intracerebroventricular administration of VEGF on days 1-3 of reperfusion. VEGF reduced infarct size, improved neurological performance, enhanced the delayed survival of newborn neurons in the dentate gyrus and subventricular zone, and stimulated angiogenesis in the striatal ischemic penumbra, but not the dentate gyrus. We conclude that in the ischemic brain VEGF exerts an acute neuroprotective effect, as well as longer latency effects on survival of new neurons and on angiogenesis, and that these effects appear to operate independently. VEGF may, therefore, improve histological and functional outcome from stroke through multiple mechanisms.     

Ischemic tolerance in stroke treatment

Although outcome after stroke treatment has significantly improved over the last 30 years, there has been no revolutionary breakthrough. Among different combined approaches, systemic thrombolysis in combination with neuroprotection became a favorite research target. Recent studies suggest that transient ischemic attacks may represent a clinical model of such ischemic tolerance; thus, a new focus on this research has emerged. In this review, we show the parallels between ischemia and neuroprotection and discuss the potential therapeutic options that may be opened by this new molecular knowledge.     

Histone deacetylase inhibitors exhibit anti-inflammatory and neuroprotective effects in a rat permanent ischemic model of stroke: multiple mechanisms of action

The pathophysiology of cerebral ischemia involves multiple mechanisms including neuroinflammation mediated by activated microglia and infiltrating macrophages/monocytes. The present study employed a rat permanent middle cerebral artery occlusion (pMCAO) model to study effects of histone deacetylase (HDAC) inhibition on ischemia-induced brain infarction, neuroinflammation, gene expression, and neurological deficits. We found that post-pMCAO injections with HDAC inhibitors, valproic acid (VPA), sodium butyrate (SB), or trichostatin A (TSA), decreased brain infarct volume. Postinsult treatment with VPA or SB also suppressed microglial activation, reduced the number of microglia, and inhibited other inflammatory markers in the ischemic brain. The reduction in levels of acetylated histone H3 in the ischemic brain was prevented by treatment with VPA, SB, or TSA. Moreover, injections with HDAC inhibitors superinduced heat-shock protein 70 and blocked pMCAO-induced down-regulation of phospho-Akt, as well as ischemia-elicited up-regulation of p53, inducible nitric oxide synthase, and cyclooxygenase-2. The motor, sensory, and reflex performance of pMCAO rats was improved by VPA, SB, or TSA treatment. The beneficial effects of SB and VPA in reducing brain infarct volume and neurological deficits occurred when either drug was administrated at least 3 h after ischemic onset, and the behavioral improvement was long-lasting. Together, our results demonstrate robust neuroprotective effects of HDAC inhibitors against cerebral ischemia-induced brain injury. The neuroprotection probably involves multiple mechanisms including suppression of ischemia-induced cerebral inflammation. Given that there is no effective treatment for stroke, HDAC inhibitors, such as VPA, SB, and TSA, should be evaluated for their potential use for clinical trials in stroke patients.     

A novel potent radical scavenger, 8-(4-fluorophenyl)-2-((2E)-3-phenyl-2-propenoyl)-1,2,3,4-tetrahydropyrazolo[5,1-c] [1,2,4]triazine (FR210575), prevents neuronal cell death in cultured primary neurons and attenuates brain injury after focal ischemia in rats

Reactive oxygen species (ROS) play a vital role in brain damage after cerebral ischemia-reperfusion injury, and ROS scavengers have been shown to exert neuroprotective effects against ischemic brain injury. We have recently identified 8-(4-fluorophenyl)-2-((2E)-3-phenyl-2-propenoyl)-1,2,3,4-tetrahydropyrazolo[5,1-c][1,2,4]triazine (FR210575) as a novel, powerful free-radical scavenger. In the present study, the neuroprotective efficacy of FR210575 was evaluated in two neuronal death models in vitro as well as rat focal cerebral ischemia models in vivo. In the first model, primary cortical cultures were exposed to a high oxygen atmosphere (50% O2) for 48 h to induce cell death with apoptotic features. Treatment with FR210575 (10-7-10-5 M) significantly inhibited neuronal death. The second model used a growth-factor withdrawal paradigm. Withdrawal of TIP (transferrin, insulin, putrescine and progesterone)-supplemented medium induced apoptotic cell death after 2 days, but treatment with FR210575 exhibited dramatic protection against neuronal death. In two models of cerebral ischemia [photothrombotic occlusion of middle cerebral artery (MCA) for transient model and by permanent MCA occlusion for permanent model], rats received 3-h intravenous infusion (1-10 mg/kg/3 h) of FR210575, with brain damage determined 24 h later. FR210575 (3.2 mg/kg/3 h) significantly reduced the volume of focal damage in the cortex by 36% in the transient model and also reduced the size of ischemic brain damage in the permanent model. These findings indicate that the powerful radical scavenger FR210575 has potent neuroprotective activity and that FR210575 could be an attractive candidate for the treatment of stroke or other neurodegenerative disorders.     

Design and retrospective analysis of the los angeles prehospital stroke screen (lapss)

Objectives. The therapeutic window for intervention in acute cerebral ischemia is brief. Prehospital identification of acute stroke patients and paramedic administration of neuroprotective agents may soon become critical components of successful acute stroke treatment. This preliminary study sought to demonstrate that a new prehospital screening instrument, the Los Angeles Prehospital Stroke Screen (LAPSS), sensitively identifies acute stroke patients. Further, the study evaluated the potential time savings that could be achieved by paramedic administration of neuroprotective agents in the field. Methods. The authors designed a simple stroke screening tool for use by prehospital personnel, emphasizing motor deficits. They then tested instrument performance and time savings retrospectively, employing data from patients enrolled within six hours of symptom onset in randomized stroke trials at three university-associated paramedic receiving hospitals. Results. Fifty of 83 patients enrolled in hyperacute stroke trials arrived by ambulance, including 41 with ischemic infarcts and seven with hemorrhages. Of the 41 with acute ischemic stroke, 38 (93%) would have been accurately identified by the LAPSS. For these 38 patients, 1 hour and 50 minutes would have been saved had neuroprotective drug been administered by paramedics at the time of transport vs the actual time of study agent administration in the emergency department. Conclusions. The LAPSS sensitively identifies ambulance-arriving acute stroke patients, and a substantial time savings will potentially occur if neuroprotective agents are administered by paramedics in the field. The LAPSS is a promising tool that may enable paramedic recognition of stroke with a high degree of sensitivity and simplicity in a short period of time.     

A newly synthesized poly(ADP-ribose) polymerase inhibitor, DR2313 [2-methyl-3,5,7,8-tetrahydrothiopyrano[4,3-d]-pyrimidine-4-one]: pharmacological profiles, neuroprotective effects, and therapeutic time window in cerebral ischemia in rats

We investigated the pharmacological profiles of DR2313 [2-methyl-3,5,7,8-tetrahydrothiopyrano[4,3-d]pyrimidine-4-one], a newly synthesized poly(ADP-ribose) polymerase (PARP) inhibitor, and its neuroprotective effects on ischemic injuries in vitro and in vivo. DR2313 competitively inhibited poly(ADP-ribosyl)ation in nuclear extracts of rat brain in vitro (K(i) = 0.23 microM). Among several NAD(+)-utilizing enzymes, DR2313 was specific for PARP but not selective between PARP-1 and PARP-2. DR2313 also showed excellent profiles in water solubility and rat brain penetrability. In in vitro models of cerebral ischemia, exposure to hydrogen peroxide or glutamate induced cell death with overactivation of PARP, and treatment with DR2313 reduced excessive formation of poly(ADP-ribose) and cell death. In both permanent and transient focal ischemia models in rats, pretreatment with DR2313 (10 mg/kg i.v. bolus and 10 mg/kg/h i.v. infusion for 6 h) significantly reduced the cortical infarct volume. To determine the therapeutic time window of neuroprotection by DR2313, the effect of post-treatment was examined in transient focal ischemia model and compared with that of a free radical scavenger, MCI-186 (3-methyl-1-phenyl-2-pyrazolone-5-one). Pretreatment with MCI-186 (3 mg/kg i.v. bolus and 3 mg/kg/h i.v. infusion for 6 h) significantly reduced the infarct volume, whereas the post-treatment failed to show any effects. In contrast, post-treatment with DR2313 (same regimen) delaying for 2 h after ischemia still prevented the progression of infarction. These results indicate that DR2313 exerts neuroprotective effects via its potent PARP inhibition, even when the treatment is initiated after ischemia. Thus, a PARP inhibitor like DR2313 may be more useful in treating acute stroke than a free radical scavenger.     

Trafermin for stroke recovery: is it time for another randomized clinical trial?

INTRODUCTION: Basic fibroblast growth factor (bFGF) has been shown to reduce volume in acute ischemic stroke models, and to promote functional recovery as well as new synapse formation when given to animals with completed cerebral infarction. A recombinant native form of human bFGF, trafermin, has been tested in Phase III clinical trials in patients with stroke. AREAS COVERED: The role of trafermin in stroke. Data were identified by searching PubMed for single or combined terms including: trafermin, basic fibroblast growth factors, neuroprotection, neuroprotective drugs, stroke therapy, stroke rehabilitation and acute stroke. Original research papers, clinical series and reviews are included. Our research covered all relevant data up until 1 April 2011. EXPERT OPINION: To date, all Phase III trials have failed to demonstrate the superiority of trafermin over placebo when given within 6 h from stroke onset because trafermin causes a dose-dependent hypotension and an increased mortality rate in treated patients. However, a 24-h intravenous infusion seems to be safe for stroke patients and may result in an improved outcome when given 5 - 6 h after infarct. This finding may open renewed interest in restorative treatment for stroke, which could enhance recovery mechanisms rather than immediate neuroprotection. Studies suggest that growth factors can produce improvement in animal models of stroke, even when administered at postischemic intervals from many hours to days, when conventional neuroprotective approaches are typically ineffective. Because of the number of side effects and increased mortality reported in the first clinical studies with high dose of FGF, further experimental studies are necessary to asses whether it is possible to achieve a pharmacologically significant therapeutic level in the brain, by minimizing peripheral side effects. Another randomized clinical trial is needed to test trafermin in stroke patients but to enhance functional recovery.     

Time for a neurorestorative therapy in stroke

Stroke remains one of the main causes of death and disability worldwide. The aging of the population is likely to result in a dramatic increase in the burden of stroke. Thus, it is not surprising that the pharmaceutical industry has invested much money in the development of pharmacotherapies for ischemic stroke. Promising experimental data, however, have almost consistently failed to produce a clinically effective neuroprotective or neurorestorative drug. Only intravenous recombinant tissue plasminogen activator (rtPA) has been approved for the treatment of acute ischemic stroke. Many pharmaceutical companies have scaled down their stroke programs and despite the unmet need, activity in the field is almost frozen. Trafermin, a recombinant form of human basic fibroblast growth factor (bFGF), is a good example of a translational failure in neuroprotection. However, trafermin may also promote neuronal plasticity after cerebral insults. Thus, clinical trials with trafermin in stroke are warranted but should be based on neuronal restoration rather than acute neuroprotection.     

Time for a neurorestorative therapy in stroke

Stroke remains one of the main causes of death and disability worldwide. The aging of the population is likely to result in a dramatic increase in the burden of stroke. Thus, it is not surprising that the pharmaceutical industry has invested much money in the development of pharmacotherapies for ischemic stroke. Promising experimental data, however, have almost consistently failed to produce a clinically effective neuroprotective or neurorestorative drug. Only intravenous recombinant tissue plasminogen activator (rtPA) has been approved for the treatment of acute ischemic stroke. Many pharmaceutical companies have scaled down their stroke programs and despite the unmet need, activity in the field is almost frozen. Trafermin, a recombinant form of human basic fibroblast growth factor (bFGF), is a good example of a translational failure in neuroprotection. However, trafermin may also promote neuronal plasticity after cerebral insults. Thus, clinical trials with trafermin in stroke are warranted but should be based on neuronal restoration rather than acute neuroprotection.     

Critical role for nitric oxide signaling in cardiac and neuronal ischemic preconditioning and tolerance

Preconditioning to ischemic tolerance is a phenomenon in which brief episodes of a subtoxic insult induce a robust protection against the deleterious effects of subsequent, prolonged, lethal ischemia. The subtoxic stimuli that constitute the preconditioning event are quite diverse, ranging from brief ischemic episodes, spreading depression or potassium depolarization, chemical inhibition of oxidative phosphorylation, exposure to excitotoxins and cytokines. The beneficial effects of preconditioning were first demonstrated in the heart; it is now clear that preconditioning can induce ischemic tolerance in a variety of organ systems including brain, heart, liver, small intestine, skeletal muscle, kidney, and lung. There are two temporally and mechanistically distinct types of protection afforded by preconditioning stimuli, acute and delayed preconditioning. The signaling cascades that initiate the acute and delayed preconditioning responses may have similar biochemical components. However, the protective effects of acute preconditioning are protein synthesis-independent, mediated by post-translational protein modifications, and are short-lived. The effects of delayed preconditioning require new protein synthesis and are sustained for days to weeks. Elucidation of the molecular mechanisms that are involved in preconditioning and ischemic tolerance and identification of drugs that mimic this protective response have the potential to improve the prognosis of patients at risk for ischemic injury. This article focuses on recent findings on the effects of ischemic preconditioning in the cardiac and nervous systems and discusses potential targets for a successful therapeutic approach to limit ischemia-reperfusion injury.     

From pharmacological promises to controlled clinical trials to meta-analysis and back: the case of nimodipine in cerebrovascular disorders

On the basis of their promising experimental evidence, calcium channel blockers are today largely used in clinical practice for treatment of patients with cerebrovascular disorders. We propose a meta-analytical evaluation of published clinical trials on nimodipine, a dihydropiridin calcium antagonist, in subarachnoid hemorrhage and in ischemic stroke. In seven trials of subarachnoid hemorrhage, 112 deaths occurred among 682 patients randomized to active treatment compared with 154 deaths among 689 control patients (odds ratio of 0.68, 95% confidence interval of 0.52 to 0.90). Poor outcome due to delayed cerebral ischemia following subarachnoid hemorrhage was also lower in the group allocated to receive nimodipine (odds ratio of 0.47, 95% confidence interval of 0.36 to 0.62). In 12 trials of ischemic stroke, 382 deaths occurred among 2056 patients allocated to receive nimodipine compared to 288 deaths among 1462 control patients (odds ratio of 0.98, 95% confidence interval of 0.82 to 1.18). Pooled results strongly suggest a protective effect of nimodipine in delayed cerebral ischemia following subarachnoid hemorrhage and no effect in ischemic stroke, but the direction and the significance of these results are due to the contribution of a single large trial on subarachnoid hemorrhage and of two trials on ischemic stroke, which account respectively for 40% and 65% of randomized patients. The dissociated effect of nimodipine on these similar conditions could be related to its preventive role in ischemic damage, resembling animal models of ischemic stroke where a beneficial effect of calcium antagonists was clearly shown only when treatment was started before experimental cerebral artery occlusion. In this view, the negative results obtained from the clinical setting of ischemic stroke seem to indicate nimodipine as an aspecific neuroprotective agent without a curative effect.     

Nitrones as neuroprotective agents in cerebral ischemia, with particular reference to NXY-059

Stroke is a major clinical problem, and acute pharmacological intervention with neuroprotective agents has so far been unsuccessful. Recently, there has been considerable interest in the potential therapeutic benefit of nitrone-derived free radical trapping agents as neuroprotective agents. Nitrone compounds have been shown to be beneficial in animal models of various diseases, and the prototypic compound -phenyl-N-tert-butylnitrone (PBN) has been extensively demonstrated to be neuroprotective in rat models of transient and permanent focal ischemia. The nitrone radical trapping agent disodium 2,4-disulfophenyl-N-tert-butylnitrone (NXY-059) has also been shown to be neuroprotective in these models. Furthermore, it has recently been shown to improve neurological function and reduce infarct volume in a primate model of permanent focal ischemia even when given 4 hr postocclusion. While radical trapping activity is demonstrable with NXY-059 and other nitrone compounds such as PBN, this activity is weak. Arguments for and against ascribing radical trapping as the therapeutic mechanism of action are discussed. This compound is well tolerated in human stroke patients and can be administered to produce plasma concentrations exceeding those effective in animal models; crucially, at the same time, it has also been shown to be effective in animal models. NXY-059 may thus be the first compound to be examined in stroke patients using drug exposure and time to treatment that have been shown to be effective in animal models of stroke.     

Therapeutic hypothermia for acute ischemic stroke

Intravenous recombinant tissue plasminogen activator remains the only US FDA-approved treatment for acute ischemic stroke. However, the very limited time window for its administration restricts its usefulness. Furthermore, it is becoming increasingly clear that, given the numerous pathways via which cerebral ischemia causes cell death, the capacity to inhibit multiple mechanisms simultaneously may provide additive or synergistic beneficial clinical effects for stroke patients. Although no clinical trials have yet investigated the efficacy of therapeutic hypothermia in focal cerebral ischemia, its pleiotropic neuroprotective actions, positive results in preclinical studies, as well as proven enhancement of neurologic outcomes in survivors of cardiac arrest and newborns with hypoxic-ischemic encephalopathy, make this neuroprotective strategy highly promising. This review presents an overview of the potential role of hypothermia in the treatment of acute ischemic stroke and discusses ischemic cell death pathophysiology, neuroprotective mechanisms of hypothermia, methodologies employed for the induction of hypothermia, results from animal models of cerebral ischemia, and finally, currently available clinical trial data. Two valuable lessons learned thus far are that first, rapid induction of hypothermia is key and is best accomplished with a combination of ice-cold saline infusion and the use of endovascular cooling devices, and second, that shivering can be overcome with aggressive anti-shivering protocols including meperidine, buspirone and surface warming. We await the results of clinical trials to determine the utility of therapeutic hypothermia in acute ischemic stroke. If proven efficacious, hypothermia would be a welcome complement to established reperfusion therapies for ischemic stroke patients.     

基于神经-血管单元空间构筑探讨针刺治疗缺血性脑卒中的研究进展CSCD

目的:基于脑缺血后神经-血管单元(NVU)空间构筑变化探讨针刺治疗缺血性脑卒中(IS)作用机制的研究进展。方法:通过查阅国内外文献资料,总结归纳神经科学领域中对NVU的研究成果,以及针刺治疗IS的研究现状,主要从NVU的结构功能和在IS中的空间构筑变化,以神经元为单维靶点,以神经元、脑微血管内皮细胞(BMEC)为二维靶点,以及以神经元、BMEC、胶质细胞为多维靶点的针刺研究等方面进行阐述。结果:以往关于针刺治疗IS的研究,大多仅停留在对神经元或血管新生调控的单一层面,较少涉及对NVU的整体及各组分间相互作用的研究,同时无论是基础研究还是临床研究,均缺乏以NVU空间构筑为切入点的系统治疗方案。针刺治疗IS具备多组分、多靶点、多环节作用的优势和特点,此与中医辨证论治、整体观念相吻合,一直是中医学和神经科学等领域的研究热点。针刺可抑制神经元凋亡,调节突触可塑性,重组、补偿大脑功能网络;针刺可诱导新生血管形成,调控脑部血流量,协同神经和血管间的耦合;针刺能调控星形胶质细胞能量代谢,抑制兴奋性毒性和炎症反应,基于双向调节效应,统筹、协调神经元、BMEC、胶质细胞间的相互作用。在诸多靶点中选择针对性干预措施,可为阐明针刺减轻脑缺血损伤的可能物质基础与有效作用靶点提供方向。结论:针刺治疗脑缺血作用机制与NVU关系密切,可通过双向调控NVU空间构筑变化,发挥协同神经保护作用,是促进脑缺血后功能恢复的关键。     

Cyclin-dependent kinase inhibition with roscovitine: neuroprotection in acute ischemic stroke

Stroke is the third most common cause of mortality and the leading cause of disability in industrialized country. According to population based-studies, ischemic stroke accounts for 67-80% of all strokes. Thrombolysis is used during the acute phase in only 2-5% of ischemic patients. Clinical trials of candidate neuroprotective agents have failed to identify viable therapies for ischemic stroke in humans. There is therefore a great need for new therapeutic strategies, considering that not all brain cells die immediately after ischemic stroke.     

Inhibition of p38 mitogen-activated protein kinase provides neuroprotection in cerebral focal ischemia

Mitogen-activated protein kinases (MAPKs) are involved in many cellular processes. The stress-activated MAPK, p38, has been linked to inflammatory cytokine production and cell death following cellular stress. Here, we demonstrate focal ischemic stroke-induced p38 enzyme activation (i.e., phosphorylation) in the brain. The second generation p38 MAPK inhibitor SB 239063 was identified to exhibit increased kinase selectivity and improved cellular and in vivo activity profiles, and thus was selected for evaluation in two rat models of permanent focal ischemic stroke. SB 239063 was administered orally pre- and post-stroke and intravenously post-stroke. Plasma concentration levels were achieved in excess of those that effectively inhibit p38 activity. In both moderate and severe stroke, SB 239063 reduced infarct size by 28-41%, and neurological deficits by 25-35%. In addition, neuroprotective plasma concentrations of SB 239063 that reduced p38 activity following stroke also reduced the stroke-induced expression of IL-1beta and TNFalpha (i.e., cytokines known to contribute to stroke-induced brain injury). SB 239063 also provided direct protection of cultured brain tissue to in vitro ischemia. This robust SB 239063-induced neuroprotection emphasizes a significant opportunity for targeting MAPK pathways in ischemic stroke injury, and also suggests that p38 inhibition be evaluated for protective effects in other experimental models of nervous system injury and neurodegeneration.     

Perlecan domain V is neuroprotective and proangiogenic following ischemic stroke in rodents

Stroke is the leading cause of long-term disability and the third leading cause of death in the United States. While most research thus far has focused on acute stroke treatment and neuroprotection, the exploitation of endogenous brain self-repair mechanisms may also yield therapeutic strategies. Here, we describe a distinct type of stroke treatment, the naturally occurring extracellular matrix fragment of perlecan, domain V, which we found had neuroprotective properties and enhanced post-stroke angiogenesis, a key component of brain repair, in rodent models of stroke. In both rat and mouse models, Western blot analysis revealed elevated levels of perlecan domain V. When systemically administered 24 hours after stroke, domain V was well tolerated, reached infarct and peri-infarct brain vasculature, and restored stroke-affected motor function to baseline pre-stroke levels in these multiple stroke models in both mice and rats. Post-stroke domain V administration increased VEGF levels via a mechanism involving brain endothelial cell α5β1 integrin, and the subsequent neuroprotective and angiogenic actions of domain V were in turn mediated via VEGFR. These results suggest that perlecan domain V represents a promising approach for stroke treatment.