Exercise enhanced functional recovery and expression of GDNF after photochemically induced cerebral infarction in the rat

Exercise has been considered to affect the functional recovery from central nervous damage. Neurotrophic factors have various effects on brain damage. However, the effects of exercise for expression of GDNF on functional recovery with brain damage are not well known. We investigated the difference in functional recovery between non-exercise and beam-walking exercise groups, and the expression of GDNF in both groups after photochemical infarction. Adult male Wistar rats (N = 64) were used. Animals were divided into two groups: non-exercise (N = 35), and beam-walking exercise (N = 29). All rats underwent surgical photochemical infarction. The rats of the beam-walking group were trained every day to walk on a narrow beam after a one-day recovery period and those of the non-exercise group were left to follow a natural course. Animals were evaluated for hind limb function every day using a beam-walking task with an elevated narrow beam. The number of GDNF-like immunoreactive cells in the temporal cortex surrounding the lesion was counted 1, 3, 5, and 7 days after the infarction. Functional recovery of the beam-walking exercise group was significantly earlier than that of the non-exercise group. At 3 days after infarction, the number of GDNF-positive cells in the temporal cortex surrounding the infarction was significantly increased in the beam-walking exercise group compared with that in the non-exercise group. In the exercise group, motor function was remarkably recovered with the increased expression of GDNF-like immunoreactive cells. Our results suggested that a rehabilitative approach increased the expression of GDNF and facilitated functional recovery from cerebral infarction

Contralateral cortical role on functional recovery in a rat model of hemiplegia

The role of the contralateral cerebral cortical plasticity in functional recovery after cerebral infarction is controversial. To clarify this role, we made a second contralateral cortical infarction after recovery from the first cerebral infarction. To produce the first infarction, Wistar rats were intravenously injected with Rose Bengal to the sensorimotor area of the right hemisphere of the cerebral cortex under green-light irradiation. Two weeks after the first hemiplegia, a secondary infarction was induced in the left cerebral cortex. Functional recovery was evaluated in a beam-walking test. Hemiplegia observed 1 day after both the first and second infarctions was given a score of 1. At 14 days after the first infarction, the average recovery score (± standard error) was 6.8 ± 0.1. In contrast, functional recovery was slower after the second infarction, reaching an average score of only 3.5 ± 0.5 after 14 days. Therefore, recovery after the contralateral secondary infarction was slower than that from the first, and received a lower recovery score compared to the recovery after the first infarction. These results suggest that the undamaged contralateral cortex plays an important role in motor recovery after hemiplegia caused by cerebral infarction

Effects of Edaravone, a Free Radical Scavenger, on Photochemically Induced Cerebral Infarction in a Rat Hemiplegic Model

Edaravone is a free radical scavenger that protects the adjacent cortex during cerebral infarction. We created a hemiparetic model of cerebral thrombosis from a photochemically induced infarction with the photosensitive dye, rose bengal, in rats. We examined the effects of edaravone on recovery in the model. A total of 36 adult Wistar rats were used. The right sensorimotor area was irradiated with green light with a wavelength of 533 nm (10 mm diameter), and the rose bengal was injected intravenously to create an infarction. The edaravone group was injected intraperitoneally with edaravone (3 mg/kg), and the control group was injected with saline. The recovery process of the hemiplegia was evaluated with the 7-step scale of Fenny. The infarcted areas were measured after fixation. The recovery of the paralysis in the edaravone-treated group was significantly earlier than that in the untreated group. Seven days later, both groups were mostly recovered and had scores of 7, and the infarction region was significantly smaller in the edaravone-treated group. Edaravone reduced the infarction area and promoted the functional recovery of hemiparesis from cerebral thrombosis in a rat model. These findings suggest that edaravone treatment would be effective in clinical patients recovering from cerebral infarction

Passive Repetitive Stretching for a Short Duration within a Week Increases Myogenic Regulatory Factors and Myosin Heavy Chain mRNA in Rats' Skeletal Muscles

Stretching is a stimulation of muscle growth. Stretching for hours or days has an effect on muscle hypertrophy. However, differences of continuous stretching and repetitive stretching to affect muscle growth are not well known. To clarify the difference of continuous and repetitive stretching within a short duration, we investigated the gene expression of muscle-related genes on stretched skeletal muscles. We used 8-week-old male Wistar rats () for this study. Animals medial gastrocnemius muscle was stretched continuously or repetitively for 15 min daily and 4 times/week under anesthesia. After stretching, muscles were removed and total RNA was extracted. Then, reverse transcriptional quantitative real-time PCR was done to evaluate the mRNA expression of MyoD, myogenin, and embryonic myosin heavy chain (MyHC). Muscles, either stretched continuously or repetitively, increased mRNA expression of MyoD, myogenin, and embryonic MyHC more than unstretched muscles. Notably, repetitive stretching resulted in more substantial effects on embryonic MyHC gene expression than continuous stretching. In conclusion, passive stretching for a short duration within a week is effective in increasing myogenic factor expression, and repetitive stretching had more effects than continuous stretching for skeletal muscle on muscle growth. These findings are applicable in clinical muscle-strengthening therapy

A new non-human primate model of photochemically induced cerebral infarction.

BACKGROUND AND PURPOSE: Rat models of photochemically induced cerebral infarction have been readily studied, but to date there are no reports of transcranial photochemically induced infarctions in the marmoset. In this report, we used this non-human primate as a model of cerebral thrombosis and observed the recovery process. METHODS: Five common marmosets were used. Cerebral ischemia was produced via intravascular thrombosis induced by an intravenous injection of Rose Bengal and irradiation with green light. After inducing cerebral infarction, we observed the behavior of marmosets via a continuous video recording. We evaluated maximum speed, mean speed, and distance traveled in 1 min. In addition, we evaluated scores for feeding behavior, upper limb grip, and lower limb grip. We confirmed the infarct area after cerebral infarction using 2,3,5-triphenyltetrazolium chloride staining in a separate marmoset. RESULTS: We found functional decreases 2 days after creating the cerebral infarction in all measurements. Total distance traveled, average speed, upper limb score, and feeding behavior score did not recover to pre-infarction levels within 28 days. Maximum speed in 1 min and lower limb score recovered 28 days after infarction as compared to pre-infarction levels. We confirmed the infarct area of 11.4 mm × 6.8 mm as stained with 2,3,5-triphenyltetrazolium chloride. CONCLUSION: We were able to create a primate photothrombosis-induced cerebral infarction model using marmosets and observe functional recovery. We suggest that this is a useful model for basic research of cerebral infarction

Behavioral analysis including feeding motion.

<p>a) Distance traveled per minute. We show the mean value and standard error of total distance traveled, including feeding behavior, for a 1-min period 28 days after surgery. b) Mean speed/min. The mean and standard error of the moving speed during 1 min 28 days after operation. c) Maximum speed/min. The mean and standard error of the maximum speed, including feeding behavior, for 1 min 28 days after operation. * P<0.05 in comparison with preoperative values indicating presence of deficit. † P<0.05 in comparison with the lowest value (2 days after operation) indicating recovery.</p

TTC (2,3,5-Triphenyltetrazolium chloride) staining.

<p>Normal region of mitochondrial activity was stained, while the ischemic area was not.</p

Behavior score.

<p>a) Hind limb score. The mean and standard error of lower limb scores pre-surgery to postoperative day 28. b) Feeding behavior score. The mean and standard error of feeding behavior scores pre-surgery to postoperative day 28. c) Total behavior score. The mean and standard error of the total score of feeding behavior, upper limb grip, and lower limb. * P<0.05 in comparison with preoperative values indicating presence of deficit. † P<0.05 in comparison with the lowest value (2 days after operation) indicating recovery.</p