Asymmetric distribution of peptide regulators of muscle tonus and substance P in the spinal cord of rats with unilateral hyperactivity of the lumbar enlargement neurons

The injection of tetanus toxin in m. gastrocnemius of the left or right hind limb of rats evokes ipsilateral hyperactivity of lumbar neurons in the spinal cord. In this case the lumbar enlargement extract after its intracisternal injection to healthy animals increases the duration of hind limb passive extension on the side where the donor neurons are hyperactive. The extract of the spinal cord of healthy rats was ineffective. Proteolysis of the extract with pronase or co-injection of opiate antagonist--naloxone--completely eliminated the lateralized changes in the muscular tone of the recipient. Substances that cause the unilateral changes in the muscular tone of the recipient are believed to be peptides. They are assumed to be involved in the functioning of endogenous opioid system. The level of substance P in the donor spinal cord was elevated bilaterally, but was higher in the hyperactive half of the spinal cord.     

Action of cortical extracts of the left and right hemispheres on the recovery of conditioned reflex activity in rats after unilateral removal of the frontal cortex

The recovery of active avoidance conditioned reflex (AACR) was investigated after unilateral frontal cortex extirpation. Intraperitoneal injection of extracts from left or right brain cortex (1 mg/kg) of healthy rats (LE or RE) stimulated AACR recovery in animals with lobectomy on the same side. If RE was extracted 9 days after left side brain extirpation, i.e. during the period of the development of compensatory processes, its effect on AACR recovery was stronger in left-operated animals, while in right-operated animals it remained unchanged.     

Met-enkephalin-induced release into the blood of a factor causing postural asymmetry

Met- and Leu-enkephalin applied subarachnoidally into the rostral portion of a transected spinal cord (at the T6-T7 level) induce postural asymmetry of the hind limbs in rats, Met-enkephalin being predominantly responsible for the flexion of the right, and Leu-enkephalin of the left, hind leg. The blood serum of rats injected with Met-enkephalin contains a factor which, when administered subarachnoidally into the caudal portion of the transected spinal cord, is capable of inducing the hind limb postural asymmetry--predominantly, with the right leg flexion. This factor is inactivated by papain and differs from Met- and Leu-enkephalin in chromatographic properties. Apparently, Met-enkephalin induces the release of a peptide factor into the blood, from the brain or organs innervated by the neurons lying above the cut. It is then carried with the blood to the hind limbs and effects the hind limb postural asymmetry.     

Monoamine oxidase -A and -B activity in the rat brain after hemitransection

The activity of MAO-A and MAO-B in four different brain regions (striatum, limbic system, occipito-temporal cortex and hemispheres) was determined after hemitransection of the left side. There was no difference in the MAO-A activities of either the left or right sides of the brain in either control or hemitransected rats. The activity of MAO-B was the same for both sides in control rats, but there was an increased MAO-B activity in the left side of the hemitransected rats with respect to the right side in all brain regions investigated, with the possible exception of the limbic system. The increase was due to a change in the V_max rather than to a changed K_m of the MAO-B. The interaction of the MAO-B with oxygen was unchanged after hemitransection.     

Muscle Activity Adaptations to Spinal Tissue Creep in the Presence of Muscle Fatigue

Aim

The aim of this study was to identify adaptations in muscle activity distribution to spinal tissue creep in presence of muscle fatigue.

Methods

Twenty-three healthy participants performed a fatigue task before and after 30 minutes of passive spinal tissue deformation in flexion. Right and left erector spinae activity was recorded using large-arrays surface electromyography (EMG). To characterize muscle activity distribution, dispersion was used. During the fatigue task, EMG amplitude root mean square (RMS), median frequency and dispersion in x- and y-axis were compared before and after spinal creep.

Results

Important fatigue-related changes in EMG median frequency were observed during muscle fatigue. Median frequency values showed a significant main creep effect, with lower median frequency values on the left side under the creep condition (p≤0.0001). A significant main creep effect on RMS values was also observed as RMS values were higher after creep deformation on the right side (p = 0.014); a similar tendency, although not significant, was observed on the left side (p = 0.06). A significant creep effects for x-axis dispersion values was observed, with higher dispersion values following the deformation protocol on the left side (p≤0.001). Regarding y-axis dispersion values, a significant creep x fatigue interaction effect was observed on the left side (p = 0.016); a similar tendency, although not significant, was observed on the right side (p = 0.08).

Conclusion

Combined muscle fatigue and creep deformation of spinal tissues led to changes in muscle activity amplitude, frequency domain and distribution.     

Opioids evoke postural asymmetry in rats: the side of the flexed paw depends on the type of opioid agonist

Opioid kappa-agonists bremazocine and dynorphin (1-13), sigma-agonist SKF 10.047 and delta-agonist D-Ala2, D-Leu5-enkephalin (DADL) induce postural asymmetry of rats hind limbs under subarachnoidal administration below the level of spinal cord section (T3-T4). The side of the flexed leg depends on the opioid agonist type: bremazocine and dynorphin (1-13) induce predominantly right flexion. SKF 10.047--the left flexion, but not in all doses, DADL--in small doses (1 and 100 pg per animal)--of the right one, in larger doses (up to 10 ng per animal)--of the left one. Saline and opiate mu-agonist morphine do not induce postural asymmetry. Opiate antagonist naloxone prevents asymmetry development when injected prior opioid agonists, and also decreases the number of asymmetries induced by these agonists. Naloxone alone does not influence the per cent of animals with pose asymmetry. The opioid receptors are involved in asymmetry development. The revealed ability of opioid kappa-, delta- and sigma-agonists may be based on lateralization of opioid receptors in the rat spinal cord.     

Effect of tetanus toxin on the content of glycine, gamma-aminobutyric acid, glutamate, glutamine and aspartate in the rat spinal cord

Tetanus toxin injected intramuscularly induced no significant changes in the levels of glycine, GABA, glutamate, glutamine or aspartate in extracts of spinal cord from rats killed at timed intervals during the development of local and generalized tetanus. The amino acid contents in the hemisegment (longitudinal one-half) of the spinal cord (L₂-L₆) on the injected side (left gastrocnemius muscle) did not differ significantly from the contents in the hemisegment of the spinal cord on the non-injected side. Nor were there any consistent changes in the contents of the amino acids in either hemisegment of the spinal cord as the tetanic symptoms became progressively more severe. Hence, the amino acid pool in the spinal cord was relatively stable despite the metabolic changes known to occur in tetanus. Our observations are consistent with the view of Johnston , De Groat and CURTIS (1969) who suggested that if glycine were indeed a spinal inhibitory neurotransmitter released by interneurons affected by tetanus toxin, the toxin should interfere with the release of the amino acid rather than deplete the transmitter stores.     

Central nervous system neuropeptides after peripheral nerve deafferentation

Beta-endorphin, Met-enkephalin, substance P, somatostatin and dynorphin concentrations were evaluated in right and left brain areas, and in cervical, thoracic, and lumbosacral spinal cord of rats that underwent section of either the right, the left, both sciatic nerves, the right brachial plexus, the saphenous, or the sural nerve. With all the surgeries, beta-endorphin concentrations decreased significantly in all brain areas with the exception of the striatum where they did not change. By contrast Met-enkephalin increased in all brain areas and in the spinal cord tracts interested by the lesions. The other peptides were always unaffected. The changes in the concentrations of the neuropeptides were observed starting twenty-four hours after surgery and lasted for at least four months. We did not find a lateralization in the brain peptide concentrations of either sham operated or unilaterally deafferentated rats. Moreover, the treatment with serotoninergic agents normalized the concentrations of beta-endorphin, suggesting a role of the serotoninergic system in the decrease of the peptide that follows the lesion of peripheral nerves.     

The noradrenaline and serotonin content in symmetrical parts of the normal rat brain and during learning and peptide administration]

Content was compared of noradrenaline (NA) and serotonine (5-OT) in the right and left halves of the rats brain in norm, at elaboration of defensive conditioned reflexes of two-ways avoidance (CRTWA) and at administration of neuropeptides influencing the learning and memory--dezglycilargininvasopressin (DG-AVP), ACTH4-7 pro-gli-pro and dalargin. The conducted studies showed that in control animals the content of NA in the cortex of the right hemisphere was significantly higher than in the cortex of the left one. For the content of 5-OT in symmetric brain parts no significant differences were revealed. Under the elaboration of CRTWA the asymmetry of NA content was not eliminated. Systemic administration of DG-AVP, ACTG4-7 pro-gli-pro and dalargin practically did not change the content of 5-OT, but reduced the content of NA in the cortex and the rest of the brain, and the content of NA in the right and left cortex was equalized. The obtained data point to the asymmetric character of neuropeptides action and to greater resistance of 5-OT-ergic brain system to functional load and to administration of peptides in comparison with NA-ergic system.     

骨髓间充质干细胞经BDNF基因修饰后移植治疗大鼠半横断脊髓损伤的电生理研究

目的采用电生理的研究方法,观察脑源性神经营养因子(BDNF)基因修饰的骨髓间充质干细胞对脊髓损伤的修复作用。方法随机将大鼠分成3组:空白组10只(只切除椎板,暴露脊髓硬脊膜);SCI组10只;SCI术后细胞移植组10只;从以上三组大鼠随机抽取8只于细胞移植后1 d、7 d、14 d、21 d、30 d、60 d进行SEP(皮层体感诱发电位)、MEP(运动诱发电位)等电生理检测技术,并观察大鼠的运动评分恢复程度。结果细胞移植4d后,大鼠饮食和活动开始增加;后肢变化过程如下:损伤后1~4 d损伤侧后肢迟缓性瘫痪,拖地行走,损伤对侧后肢由损伤初期的运动减弱逐渐恢复,损伤后5~9 d损伤侧后肢痉挛性瘫痪;10~14 d损伤侧下肢恢复少量活动,损伤对侧后肢恢复至较损伤前稍弱的状态;15~21 d损伤侧后肢活动能力较之前有明显改善,至30 d损伤侧后肢活动能力及肌张力恢复程度最明显,30 d以后无更明显改善。免疫组化发现损伤处诱导标记的骨髓间充质干细胞存活,行为学观察发现细胞移植改善了损伤大鼠运动能力。结论骨髓间充质干细胞经BDNF基因修饰后可以促进脊髓损伤大鼠的神经再生及部分传导功能恢复。     

Aging and Lateralization of the Rat Brain on a Biochemical Level

It has been suggested that the lateralization of the human brain underlies hemispheric specialization and that it can be observed also on a biochemical level. Biochemical laterality appears to be a basis of volumetric or functional asymmetry but direct relationships among them are still unclear. Moreover, age-related differences between the right and left hemispheres are not well documented in various rat strains. In the current study, biochemical markers sensitive to Alzheimer disease (activities of high-affinity choline uptake and of nitric oxide synthases, expression of 17β-hydroxysteroid dehydrogenase type 10) were estimated in both hemispheres of young and old male Wistar/Long Evans rats. Our experiments indicate (1) differences in some biochemical markers between young Wistar and Long Evans rats (the activities of endothelial nitric oxide synthase are higher in Long Evans and those of citrate synthase in Wistar rats), (2) more similar brain asymmetry of healthy human/young Wistar brains when compared to those of young Long Evans, (3) the decrease in asymmetry of the physiologically left/right lateralized biomarker during aging (the activity of the high-affinity choline uptake decreases more markedly in the left side of old Wistar rats) in accordance with the HAROLD model, (4) the age-related shift to reversed left/right asymmetry of the physiologically right/left lateralized biomarker (the activity of inducible nitric oxide synthase increases especially in the left side of old Long Evans rats), and finally (5) age-related differences in physiologically unlateralized biomarkers between Wistar and Long Evans rats (changes in the activities of neural/endothelial nitric oxide synthases or in expression of 17β-hydroxysteroid dehydrogenase type 10 are more asymmetrical in old Wistar when compared to rather bilateral alterations of old Long Evans animals). It seems that the physiological lateralization of the human or rat brains on a biochemical level and their age-related alterations are dependent on biomarker type/function. By our opinion, it is difficult, perhaps impossible, to make one simple universal model, at least on a biochemical level. Since lateral analyses are of sufficient sensitivity to reveal subtle links, we recommend using Wistar rather than Long Evans rats in modeling of diseases accompanied by alterations in brain asymmetry.     

The activity of postural asymmetry factors in symmetrical sections of the rat spinal cord

The distribution of the low-molecular weight and high-molecular weight postural asymmetry factors (FPA) activity in the left and right parts of the lumbal region of the rat spinal cord was studied. Low-molecular weight FPA induces flexion of the hind limb ipsilateral to the half of the spinal cord from which FPA was isolated, while high-molecular weight FPA induces contralateral flexion. The activities of the low- and high-molecular weight FPAs in each half of the spinal cord are comparable in normal rat. After the suction lesion of the motor areas in the left hemisphere the increase of the low-molecular weight FPA activity in the right half of the lumbal region of the spinal cord was observed.     

Spinal regions involved in baroreflex control of renal sympathetic nerve activity in the rat

Spinal cord injury causes debilitating cardiovascular disturbances. The etiology of these disturbances remains obscure, partly because the locations of spinal cord pathways important for sympathetic control of cardiovascular function have not been thoroughly studied. To elucidate these pathways, we examined regions of the thoracic spinal cord important for reflex sympathetic control of arterial pressure (AP). In anesthetized rats, baroreceptor relationships between pharmacologically induced changes in AP and changes in left renal sympathetic nerve activity (RSNA) were generated in spinally intact rats and after acute surgical hemisection of either the dorsal, left, or right T8 spinal cord. None of these individual spinal lesions prevented the baroreceptor-mediated increases in RSNA caused by decreases in AP. Thus, baroreceptor-mediated increases in RSNA in rats are mediated by relatively diffuse, bilateral, descending, excitatory projections. The ability to reduce RSNA at increased AP was impaired after both dorsal and left hemisections, and baroreceptor gain was significantly decreased. Baroreceptor-induced maximum decreases in RSNA were not affected by right hemisections. However, baroreflex gain was impaired. Because both dorsal and left hemisections, but not right hemisections, attenuated the decrease in RSNA at elevated AP, we conclude that pathways involved in the tonic inhibition of spinal sources of sympathetic activity descend ipsilaterally in the dorsal spinal cord. Our results show that many lesions that do not fully transect the spinal cord spare portions of both descending excitatory pathways that may prevent orthostatic hypotension and descending inhibitory pathways that reduce the incidence of autonomic dysreflexia.     

Viscerosomatic interaction induced by myocardial ischemia in conscious dogs.

Studies tested the hypothesis that myocardial ischemia induces increased paraspinal muscular tone localized to the T(2)-T(5) region that can be detected by palpatory means. This is consistent with theories of manual medicine suggesting that disturbances in visceral organ physiology can cause increases in skeletal muscle tone in specific muscle groups. Clinical studies in manual and traditional medicine suggest this phenomenon occurs during episodes of myocardial ischemia and may have diagnostic potential. However, there is little direct evidence of a cardiac-somatic mechanism to explain these findings. Chronically instrumented dogs [12 neurally intact and 3 following selective left ventricular (LV) sympathectomy] were examined before, during, and after myocardial ischemia. Circumflex blood flow (CBF), left ventricular contractile function, electromyographic (EMG) analysis, and blinded manual palpatory assessments (MPA) of tissue over the transverse spinal processes at segments T(2)-T(5) and T(11)-T(12) (control) were performed. Myocardial ischemia was associated with a decrease in myocardial contractile function and an increase in heart rate. MPA revealed increases in muscle tension and texture/firmness during ischemia in the T(2)-T(5) segments on the left, but not on the right or in control segments. EMG demonstrated increased amplitude for the T(4)-T(5) segments. After LV sympathectomy, MPA and EMG evidence of increased muscle tone were absent. In conclusion, myocardial ischemia is associated with significant increased paraspinal muscle tone localized to the left side T(4)-T(5) myotomes in neurally intact dogs. LV sympathectomy eliminates the somatic response, suggesting that sympathetic neural traffic between the heart and somatic musculature may function as the mechanism for the interaction.     

Experiments on the central pattern generator for swimming in amphibian embryos

The central nervous system of paralysed Xenopus laevis embryos can generate a motor output pattern suitable for swimming locomotion. By recording motor root activity in paralysed embryos with transected nervous systems we have shown that: (a) the spinal cord is capable of swimming pattern generation; (b) swimming pattern generator capability in the hindbrain and spinal cord is distributed; (c) caudal hindbrain is necessary for sustained swimming output after discrete stimulation. By recording similarly from embryos whose central nervous system was divided longitudinally into left and right sides, we have shown that: (a) each side can generate rhythmic motor output with cycle periods like those in swimming; (b) during this activity cycle period increases within an episode, and there is the usual rostrocaudal delay found in swimming; (c) this activity is influenced by sensory stimuli in the same way as swimming activity; (d) normal phase coupling of the left and right sides can be established by the ventral commissure in the spinal cord. We conclude that interactions between the antagonistic (left and right) motor systems are not necessary for swimming rhythm generation and present a model for swimming pattern generation where autonomous rhythm generators on each side of the nervous system drive the motoneurons. Alternation is achieved by reciprocal inhibition, and activity is initiated and maintained by tonic excitation from the hindbrain.     

Thermal interhemispheric asymmetry of the brain in rats in a cataleptic state]

The rat brain thermal fields were studied using the thermoencephaloscopic technique in three experimental conditions: the genetic catalepsy (GC rat strain), cataleptic phase of an audiogenic epileptic seizure (Krushinski?-Molodkina strain), and pharmacological catalepsy produced by haloperidol injection (Wistar rats). Irrespective of the experimental conditions, the state of catalepsy, accompanied by a decrease in the muscle tone and inhibition of motor reactions, was characterized by total asymmetric cooling of the brain cortex with the dominance of the right hemisphere. Temperature difference between the parieto-occipital areas of the right and left hemispheres reached 0.3-0.6 degree C.     

Neuroprotective effect of testosterone treatment on motoneuron recruitment following the death of nearby motoneurons

Motoneuron loss is a significant medical problem, capable of causing severe movement disorders or even death. We have previously shown that motoneuron death induces marked dendritic atrophy in surviving nearby motoneurons. Additionally, in quadriceps motoneurons, this atrophy is accompanied by decreases in motor nerve activity. However, treatment with testosterone partially attenuates changes in both the morphology and activation of quadriceps motoneurons. Testosterone has an even larger neuroprotective effect on the morphology of motoneurons of the spinal nucleus of the bulbocavernosus (SNB), in which testosterone treatment can completely prevent dendritic atrophy. The present experiment was performed to determine whether the greater neuroprotective effect of testosterone on SNB motoneuron morphology was accompanied by a greater neuroprotective effect on motor activation. Right side SNB motoneurons were killed by intramuscular injection of cholera toxin‐conjugated saporin in adult male Sprague‐Dawley rats. Animals were either given Silastic testosterone implants or left untreated. Four weeks later, left side SNB motor activation was assessed with peripheral nerve recording. The death of right side SNB motoneurons resulted in several changes in the electrophysiological response properties of surviving left side SNB motoneurons, including decreased background activity, increased response latency, increased activity duration, and decreased motoneuron recruitment. Treatment with exogenous testosterone attenuated the increase in activity duration and completely prevented the decrease in motoneuron recruitment. These data provide a functional correlate to the known protective effects of testosterone treatment on the morphology of these motoneurons, and further support a role for testosterone as a therapeutic agent in the injured nervous system. © 2009 Wiley Periodicals, Inc. Develop Neurobiol, 2009     

Characteristics of the development of postural asymmetry in rats as affected by the opioids met-enkephalin and the kappa-agonist bremazocine

It has been found that bremazocine and met-enkephalin induce postural asymmetry in spinal rats under subarachnoidal and intravenous administration. Intravenous administration of bremazocine to intact animals--even if after it (an hour later) their spinal cord is sectioned--produces no asymmetry, i. e. the spinal cord section is necessary for asymmetry development. The magnitude of postural asymmetry and the side of limb flexion are not constant for each animal, but they change in time. Though, on the average, the percent of asymmetric animals and the ratio of left and right flexions in each group of animals are practically constant. When the spinal cord is sectioned at the T1-T4 level, the bremazocine and metenkephalin induce mainly the right-leg flexion: when the section is made at the T5-T9 level, the left-leg is bent, i. e. the flexion side depends on the level of the section. It is suggested that the ability of opioids to induce postural asymmetry is based on lateralization of opioid receptors in the rat spinal cord.     

Effect of unilateral motor cortex ablation on activity of choline acetyltransferase and levels of amino acid transmitter candidates in the spinal cord of adult monkeys

Evidence thatl-glutamate is a neurotransmitter of corticofugal fibers was sought by measuring changes in several biochemical markers of neurotransmitter function in discrete regions of spinal cord after ablation of sensorimotor cortex in monkeys. One and five weeks after unilateral cortical ablation, samples from six areas of spinal cord (ventral, lateral and dorsal regions of the left and right sides) were analysed for choline acetyltransferase (ChAT) activity and contents of amino acid transmitter candidates-glutamic acid (Glu), aspartic acid (Asp), glycine (Gly), taurine (Tau) and -aminobutyric acid (GABA). During one to five weeks after unilateral cortical ablation of the monkey, prolonged hemiplegia in the contralateral side was observed. Histological examination of the spinal cord 5 weeks after unilateral (left) cortical ablation showed no apparent change in either control (ipsilateral, left) or affected (contralateral, right) sides of the cord as examined by the Klüver-Barrera method. The ChAT activity as a cholinergic marker was scarcely changed in any region of either left (control) or right (affected) side of the spinal cord at one and five weeks after unilateral (left side) ablation of the motor cortex. Amino acid levels in each region of the spinal cord were not significantly changed one week after unilateral ablation of the motor cortex. However, a significant decrease of Glu content was observed in the lateral column of the affected (right) side compared to the control (left) side of cervical and lumbar cord five weeks after cortical ablation of the left motor area. No concomitant alterations of other amino acids were detected. These data strongly suggest thatl-Glu is a neurotransmitter for corticofugal pyramidal tract fibers to anterior horn secondary neurons related to motor control activity in monkey spinal cord.     

Changes in protein turnover in hypertrophying plantaris muscles of rats: effect of fenbufen--an inhibitor of prostaglandin synthesis

Plantaris muscle of the right hind limb of rats was subjected to hypertrophic stimulus by section of the tendons of the right gastrocnemius muscle. The RNA and protein content and the fractional rate of protein synthesis were elevated both 3 and 7 days after operation compared both with the unoperated left limb and with sham-operated control rats. The rate of protein degradation, calculated from the difference between the fractional rates of protein synthesis and protein gain of the muscles, was elevated in the plantaris 3-7 days after tenotomy. Dietary administration of the drug fenbufen reduced the RNA content and the ratio of RNA:protein in muscles from control animals. In one group of tenotomised rats administration of fenbufen commenced 3 days before tenotomy and resulted in a reduction in the ratio RNA:protein of the muscles of the left limb 3 days after the operation. Four days later, i.e. 7 days after tenotomy, both the ratio RNA:protein and the fractional rate of protein synthesis were significantly reduced in the fenbufen treated rats. In spite of these effects, fenbufen did not impair the ability of the plantaris to hypertrophy since the drug also reduced the rate of protein degradation.