Combination therapy with insulin-like growth factor-1 and hypothermia synergistically improves outcome after transient global brain ischemia in the rat.

OBJECTIVES: Hypothermia has a well-established neuroprotective effect and offers a foundation for combination therapy for brain ischemia. The authors evaluated the effect of combination therapy with insulin-like growth factor-1 (IGF-1) and hypothermia on brain structure and function in the setting of global brain ischemia and reperfusion in rats. METHODS: Male Sprague-Dawley rats were randomly assigned to groups by a registrar. Animals were subjected to 8 minutes of global brain ischemia using bilateral carotid occlusion and systemic hypotension, followed by 7 days (Stage I dose studies) or 28 days (Stage II outcome studies) of reperfusion. Sham controls were subjected to surgery, but not ischemia. Stage II animals were randomized to no treatment, IGF-1 at the dose determined in Stage I, hypothermia (32°C for 4 hours), or a combination of IGF-1 and hypothermia. Stage II animals underwent 21 days of spatial memory testing. At 7 days (Stage I) or 28 days (Stage II), brains were harvested for counting of CA1 neurons. The primary Stage II outcome was a neurologic outcome index computed as the ratio of viable CA1 neurons per 300-µm field to the number of days to reach success criteria on the memory task. RESULTS: Stage I experiments confirmed the neuroprotective effect of the hypothermia protocol and IGF-1 at a dose of 0.6 U/kg. Stage II studies suggested that early neuroprotection with hypothermia and IGF-1 was not well maintained to 28 days and that combination therapy was more beneficial than either IGF-1 or hypothermia alone. Median and interquartile ranges (IQRs) of viable neurons per 300-µm field were 114 (IQR = 99.5 to 136) for sham, three (IQR = 2 to 4.8) for untreated ischemia, four (IQR = 3 to 70.25) for ischemia treated with IGF-1 alone, 25 (IQR = 3 to 70) for ischemia treated with hypothermia alone, and 78 (IQR 47.3 to 97.5) for ischemia treated with combination therapy. Days to memory success criteria were 13.6 (IQR = 11.5 to 15.5 days) for sham, 23.5 (IQR = 20 to 25.5 days) for untreated ischemia, 17.5 (IQR = 15.5 to 25.5 days) for ischemia treated with IGF-1, 15 (IQR = 14.5 to 21 days) for ischemia treated with hypothermia, and 13.5 (IQR = 12.25 to 18.5 days) for ischemia treated with combination therapy. Neurologic outcome indices were 8.5 (IQR = 7.4 to 9.5) for sham, 0.14 (IQR = 0.08 to 0.2) for untreated ischemia, 0.18 (IQR = 0.17 to 4.6) for ischemia treated with IGF-1, 0.7 (IQR = 0.2 to 4.8) for ischemia treated with hypothermia, and 5.7 (IQR = 3.3 to 6.2) for ischemia treated with combination therapy. Statistically significant differences in neuron counts, days to memory test criteria, and outcome index were found between sham and untreated ischemic animals. Of the three treatment regimens, only combination therapy showed a statistically significant difference from the untreated ischemic group for neuronal salvage (p = 0.02), days to criteria (p = 0.043), and outcome index (p = 0.014). CONCLUSIONS: Combination therapy with IGF-1 (0.6 U/kg) and therapeutic hypothermia (32°C for 4 hours) at the onset of reperfusion synergistically preserves CA1 structure and function at 28 days after 8 minutes of global brain ischemia in healthy male rats.

Acute administration of ethanol reduces apoptosis following ischemic stroke in rats.

In recent studies, acute ethanol administration appears to play a neuroprotective role during ischemic stroke. We sought to confirm these findings by identifying if ethanol-derived neuroprotection is associated with a reduction in apoptosis. Ethanol at 0.5 and 1.5 g/kg doses was given by intraperitoneal injections to Sprague-Dawley rats after 2h of middle cerebral artery (MCA) occlusion, followed by reperfusion. We quantified apoptotic cell death in each of the treatment groups with ELISA, and measured pro- and anti-apoptotic protein expression with Western blot analysis. Cell death was significantly increased in rats after ischemia and was subsequently significantly reduced by the administration of 1.5 g/kg of ethanol. We found that the 1.5 g/kg dose promoted the expression of pro-survival factors and decreased the expression of apoptotic proteins at 3h after reperfusion. This effect was maintained at 24h for Caspase-3 and apoptosis-inducing factor (AIF), although not for Bcl-2, Bcl-xL, and Bcl-2-associated X (Bax). Administration of 0.5 g/kg of ethanol was not as effective in regulating protein expression as the 1.5 g/kg dose. Our study suggests that administration of ethanol at a dose of 1.5 g/kg after stroke - which provides rat blood alcohol levels equivalent to the legal driving limit - produces a differential protein profile, with increased expression of anti-apoptotic proteins and decrease in pro-apoptotic factors. This results in a significant reduction of neuronal apoptosis and is neuroprotective in ischemia-reperfusion injury.

The "Refrige-a-RAT-or": an accurate, inexpensive, and clinically relevant small animal model of therapeutic hypothermia.

BACKGROUND: Physical and molecular mechanisms for the neuroprotective effect of therapeutic hypothermia are not completely understood, and new therapeutic applications incorporating hypothermia remain to be developed and tested. Clinically relevant animal models of therapeutic hypothermia are not well established or consistent. OBJECTIVES: The objective was to develop and test an inexpensive small animal therapeutic hypothermia system that models those in widespread clinical use and verify that such a system confers neuroprotection in a rat model of global brain ischemia. METHODS: A water-cooled extracorporeal system and attendant anesthesia/sedation protocol were developed and tested. In Stage 1, animals were instrumented for brain, temporalis, and rectal temperature monitoring, and the system was tested for its effect on temperature and hemodynamics. In Stage 2, animals were instrumented for rectal temperature only, subjected to global brain ischemia by two-vessel occlusion and hypotension for 8 minutes, and given either sham therapy (37°C) or hypothermia (32°C) for 4 hours. Viable CA1 neurons were counted at 7 days. RESULTS: The system was well tolerated, provided exquisite control of animal core and brain temperatures, and conferred robust neuroprotection at 7 days. The median and interquartile ranges (IQRs) of viable neurons per 300-µm field were 130 (IQR = 128 to 135) for sham control, 19 (IQR = 15 to 30) for untreated ischemic animals, and 101 (IQR = 94 to 113) for ischemic animals treated with hypothermia (p < 0.05 for comparison between all groups). CONCLUSIONS: Like human protocols, this model incorporates sedation and analgesia, results in robust neuroprotection, is well tolerated, and offers exquisite temperature control. The system is noninvasive and inexpensive and offers a model that is similar to methods used in clinical practice. This system will be of interest to investigators using small animal models to examine neuroprotective mechanisms of hypothermia and translational strategies that combine hypothermia with targeted pharmacotherapy.

Neuroprotective effect of acute ethanol administration in a rat with transient cerebral ischemia.

BACKGROUND AND PURPOSE: Ethanol consumption is inversely associated with the risk of ischemic stroke, suggesting a neuroprotective effect. In a rat model of transient cerebral ischemia, we identified ethanol as a possible treatment for acute ischemic stroke. METHODS: Sprague-Dawley rats were subjected to middle cerebral artery occlusion for 2 hours. Five sets of experiments were conducted: to determine the dose-response effect of ethanol on brain infarction and functional outcome; to determine whether combining ethanol and hypothermia produces synergistic neuroprotection; to determine the therapeutic windows of opportunity for ethanol in stroke; to test whether ethanol promotes intracerebral hemorrhage in a hemorrhagic or ischemic stroke or after administration of thrombolytics; and to test the affect of ethanol on hypoxia-inducible factor-1α protein expression. RESULTS: Ethanol at 1.5 g/kg reduced infarct volume and behavioral dysfunction when administered at 2, 3, or 4 hours after middle cerebral artery occlusion. The protective effect of ethanol was not improved when paired with hypothermia. Ethanol did not promote cerebral hemorrhage in hemorrhagic or ischemic stroke in combination with recombinant tissue-type plasminogen activator or urokinase. Ethanol treatment (1.5 g/kg) increased protein levels of hypoxia-inducible factor-1α at 3 hours postreperfusion. CONCLUSIONS: Ethanol exerts a strong neuroprotective effect when administered up to 4 hours after ischemia, increases expression of hypoxia-inducible factor-1α, and does not promote intracerebral hemorrhage when used with thrombolytics. Ethanol is a potential neuroprotectant for acute ischemic stroke.

Insulin activates the PI3K-Akt survival pathway in vulnerable neurons following global brain ischemia.

UNLABELLED: Insulin is neuroprotective following transient global brain ischemia; however, the mechanisms by which insulin exerts its salutary effects remain unclear. OBJECTIVE: We assessed insulin's effect on the PI3K-Akt survival system and consequent modulation of the pro-apoptotic proteins Bim, Bad and FoxO3a. METHODS: We utilized rats subjected to 10 minutes of global brain ischemia, with or without insulin administered at the onset of reperfusion. RESULTS: In sham-operated animals, minimal pAkt immunofluorescence was detected in the CA1. Moreover, at 30 minute reperfusion, there was no change in pAkt in CA1 neurons. Single bolus high-dose insulin treatment resulted in an early increase in pAkt after 30 minutes, preservation of CA1 neurons to 14 days of reperfusion and preservation of spatial learning ability. Insulin treatment increased cytoplasmic and nuclear staining for pAkt in both CA1 and cortex. Insulin-induced Akt phosphorylation was suppressed by the PI3K inhibitor wortmannin. Neither reperfusion nor insulin induced any change in the phosphorylation or subcellular localization of FoxO3a, Bim or Bad. A single bolus of high-dose insulin reduced CA1 neuronal cell death and thus represents a potential therapeutic intervention for global brain ischemia. DISCUSSION: These results reveal that proximal elements of a known cell-survival pathway are triggered by high-dose insulin during early reperfusion. Insulin induces robust PI3K-dependent phosphorylation of Akt by 30 minute reperfusion and results in improvement of hippocampal structure and function. However, the Akt substrates FoxO3a, Bim and Bad do not undergo corresponding changes in phosphorylation or subcellular localization in this model of global brain ischemia. The downstream components of insulin-induced Akt survival signaling after transient global brain ischemia remain to be identified.

Insulin blocks cytochrome c release in the reperfused brain through PI3-K signaling and by promoting Bax/Bcl-XL binding.

The critical event of the intrinsic pathway of apoptosis following transient global brain ischemia is the release of cytochrome c from the mitochondria. In vitro studies have shown that insulin can signal specifically via phosphatidylinositol-3-OH-kinase (PI3-K) and Akt to prevent cytochrome c release. Therefore, insulin may exert its neuroprotective effects during brain reperfusion by blocking cytochrome c release. We hypothesized that insulin acts through PI3-K, Akt, and Bcl-2 family proteins to inhibit cytochrome c release following transient global brain ischemia. We found that a single bolus of insulin given immediately upon reperfusion inhibited cytochrome c release for at least 24 h, and produced a fivefold improvement in neuronal survival at 14 days. Moreover, insulin's ability to inhibit cytochrome c release was completely dependent on PI3-K signaling and insulin induces phosphorylation of Akt through PI3-K. In untreated animals, there was an increase in mitochondrial Bax at 6 h of reperfusion, and Bax binding to Bcl-X(L) was disrupted at the mitochondria. Insulin prevented both these events in a PI3-K-dependent manner. In summary, insulin regulates cytochrome c release through PI3-K likely by activating Akt, promoting the binding between Bax and Bcl-X(L), and by preventing Bax translocation to the mitochondria.