Mechanoreceptors distribution in the human medial collateral ligament of the elbow.

BACKGROUND: The human elbow maintains its stability mainly through its bony structure. Stability is enhanced by ligamentous structures. To allow the ligamento-muscular reflex, which protects against strain and stress, mechanoreceptors are embedded in the ligament. This report describes the existence and the distribution of the elbow medial collateral ligaments (MCLs) mechanoreceptors. HYPOTHESIS: The bony attachment site has the highest density of mechanoreceptors, and the anterior part has the highest density of mechanoreceptors. MATERIALS AND METHODS: Eight MCLs of elbow from fresh frozen cadavers were used. The MCLs were harvested deep to the periosteum from the medial epicondyle to the ulna. The fan-shaped ligaments were divided into six regions of interest (ROI) and stained with modified gold chloride stain. Specimens were evaluated under a light microscope. Golgi, Ruffini, and Pacinian corpuscles were found in every specimen. The number and the distribution of each mechanoreceptor in each ROI were recorded. The density of each mechanoreceptor was calculated in regards to its volume. RESULTS: Golgi, Ruffini, and Pacinian corpuscles were seen in the ligament with small nerve fibers. Ruffini corpuscles had the highest median density of all three corpuscles. The median corpuscle density was higher in the anterior than in the posterior part and higher in the bony attachment than in the mid-substance site except for Golgi corpuscle. CONCLUSION: The three typical types of mechanoreceptors were identified in human MCL with the anterior part and bony attachment as the dominant distribution site. LEVEL OF EVIDENCE: Basic Science Study.

Continuous distraction-induced delayed spinal cord injury on motor-evoked potentials and histological changes of spinal cord in a porcine model.

STUDY DESIGN: Experimental study. OBJECTIVES: This study evaluated distraction-induced delayed spinal cord injury in a porcine model. SETTING: Department of Orthopedics, Korea University Guro Hospital, Seoul, Korea. METHODS: Global osteotomy of three columns was performed on the thirteenth thoracic vertebrae with 13 pigs. The osteotomized vertebrae were distracted to 57-103% of segmental vertebral height (SVH) length, which was less than the distraction length that induces prompt SCI. The vertebral height was maintained until the loss of motor-evoked potential (MEP) signals with continuous distraction. The distraction distance and the time at which SCI occurred were measured, and distraction was then released to observe MEP recovery patterns. RESULTS: We found delayed SCI in 8 of the 12 pigs, with a mean 20.9 mm (range 19-25 mm) and 10.7 min (range 8-12 min) of continuous spinal distraction, which was equivalent to 74.3% (68-84%) of SVH and 3.63% (3.42-4.31%) of thoracolumbar spinal length. A continuous 74.3% SVH distraction over an average of 10.7 min caused a delayed SCI, which was indicated by mild histologic changes in the spinal cord. Recovery patterns from SCI after distraction release were compatible with the degree of histological change; however, these patterns differed from the previously investigated prompt type of SCI. CONCLUSION: Late onset injury due to continuous spinal distraction, which is comparable to iatrogenic SCI in spinal correction surgery, is important for understanding the impact of corrective surgery.

Regional cerebellar volume reflects static balance in elite female short-track speed skaters.

The cerebellum plays a critical role in balance control. Particularly, elite short-track speed skaters require fine postural control to keep a postural balance during high velocity movement across smooth ice. We investigated whether skating proficiency and gender have an effect on the volume of cerebellar subregions and static balance, using 3-dimensional magnetic resonance imaging volumetry. In addition, we further analyzed which subregions of the cerebellum correlates with the balance. The volumes of cerebellar subregions and static balance index were compared among 12 male and 11 female elite short-track speed skaters, and 11 male and 14 female healthy matched subjects. We found significant main effects of skating proficiency and gender on the volume of vermian lobule VI-VII (declive, folium, and tuber), short-track speed skaters having greater volume than control and women revealing greater volume than men. Especially, in female athletic group, the volume of vermian lobule VI-VII significantly correlates with left static balance. In addition, men showed larger skating proficiency-related differences than women in the performance of static balance. The correlation between the volume of this region and static balance in female short-track speed skaters suggests that this region would plays a critical role in balance.

Developmental expression and subcellular distribution of synaptotagmin 11 in rat hippocampus.

Synaptotagmins are required for Ca(2+)-dependent membrane-trafficking in either neuronal synaptic vesicles or cellular membranes. Previous reports suggested that the synaptotagmin 11 (syt11) gene is involved in the development of schizophrenia based on the genomic analysis of patients. Parkin protein binds to the C2 domains of Syt11 which leads to the polyubiquitination of Syt11. However, where and how Syt11 performs its role in the brain is largely unknown. Here, we report that Syt11 is expressed mainly in the brain. In addition, exogenously expressed Syt11 in HEK293 cells can form higher molecular weight complex via its transmembrane domain. Also, Syt11 is targeted to both dendrite and axon compartments. Immunocytochemistry showed that Syt11 is juxtaposed to postsynaptic markers in both excitatory and inhibitory synapses. Both neuroligin 1 and 2, which are postsynaptic cell adhesion molecules and differentially induce excitatory and inhibitory presynapses, respectively, recruit Syt11 in neuron coculture. Immunogold electron microscopy analysis revealed that Syt11 exists mainly in presynaptic neurotransmitter vesicles and plasma membrane, and rarely in postsynaptic sites. These results suggest that Syt11 may contribute to the regulation of neurotransmitter release in the excitatory and inhibitory presynapses, and postsynapse-targeted membrane trafficking in dendrites.

The expression of non-clustered protocadherins in adult rat hippocampal formation and the connecting brain regions.

Non-clustered protocadherins (PCDHs) are calcium-dependent adhesion molecules which have attracted attention for their possible roles in the neuronal circuit formation during development and their implications in the neurological disorders such as autism and mental retardation. Previously, we found that a subset of the non-clustered PCDHs exhibited circuit-dependent expression patterns in thalamo-cortical connections in early postnatal rat brain, but such patterns disappeared in adulthood. In this study, we identified that the non-clustered PCDHs showed differential expression patterns along the septotemporal axis in the subregions of adult hippocampus and dentate gyrus with topographical preferences. The expressions of PCDH1, PCDH9, PCDH10 and PCDH20 showed septal preferences, whereas the expressions of PCDH8, PCDH11, PCDH17 and PCDH19 showed temporal preferences, suggesting that they play roles in the formation/maintenance of intrahippocampal circuits. PCDHs also exhibited the region-specific expression patterns in the areas connected to hippocampal formation such as entorhinal cortex, lateral septum, and basolateral amygdaloid complex. Furthermore, the expression levels of three PCDHs (PCDH8, PCDH19 and PCDH20) were regulated by the electroconvulsive shock stimulation of the brain in the adult hippocampus and dentate gyrus. These results suggest that non-clustered PCDHs are involved in the maintenance and plasticity of adult hippocampal circuitry.

Effects of aerobic exercise training on cognitive function and cortical vascularity in monkeys.

This study examined whether regular exercise training, at a level that would be recommended for middle-aged people interested in improving fitness could lead to improved cognitive performance and increased blood flow to the brain in another primate species. Adult female cynomolgus monkeys were trained to run on treadmills for 1 h a day, 5 days a week, for a 5 month period (n=16; 1.9+/-0.4 miles/day). A sedentary control group sat daily on immobile treadmills (n=8). Half of the runners had an additional sedentary period for 3 months at the end of the exercise period (n=8). In all groups, half of the monkeys were middle-aged (10-12 years old) and half were more mature (15-17 years old). Starting the fifth week of exercise training, monkeys underwent cognitive testing using the Wisconsin General Testing Apparatus (WGTA). Regardless of age, the exercising group learned to use the WGTA significantly faster (4.6+/-3.4 days) compared to controls (8.3+/-4.8 days; P=0.05). At the end of 5 months of running monkeys showed increased fitness, and the vascular volume fraction in the motor cortex in mature adult running monkeys was increased significantly compared to controls (P=0.029). However, increased vascular volume did not remain apparent after a 3-month sedentary period. These findings indicate that the level of exercise associated with improved fitness in middle-aged humans is sufficient to increase both the rate of learning and blood flow to the cerebral cortex, at least during the period of regular exercise.

Light and electron microscopic analysis of the somata and parent axons innervating the rat upper molar and lower incisor pulp.

The morphology of intradental nerve fibers of permanent teeth and of continuously growing rodent incisors has been studied in detail but little information is available on the parent axons that give rise to these fibers. Here we examined the axons and somata of trigeminal neurons that innervate the rat upper molar and lower incisor pulp using tracing with horseradish peroxidase and light and electron microscopic analysis. The majority (approximately 80%) of the parent axons in the proximal root of the trigeminal ganglion that innervated either molar or incisor pulp were small myelinated fibers (<20 microm(2) cross-sectional area). The remaining approximately 20% of the fibers were almost exclusively large myelinated for the molar pulp and unmyelinated for the incisor pulp. The majority of neuronal somata in the trigeminal ganglion that innervated either molar (48%) or incisor pulp (62%) were medium in size (300-600 microm(2) cross-sectional area). Large somata (>600 microm(2)) constituted 34% and 20% of the trigeminal neurons innervating molar and incisor pulp, respectively, while small somata (<300 microm(2)) constituted 17% of the molar and 18% of the incisor neurons. The present study revealed that the morphology of parent axons of dental primary sensory neurons may differ from that of their intradental branches, and also suggests that the nerve fiber function may be carried out differently in the molar and incisor pulp in the rat.

Electroconvulsive shock reduces inositol trisphosphate receptor1 mRNA in rat brain.

We studied the expression pattern of the inositol 1,4,5-trisphosphate receptor1 (InsP3R1) mRNA after a single electroconvulsive shock (ECS) in the rat brain by in situ hybridization. The expression was significantly decreased in the dentate gyrus and the CA1 area of the hippocampal formation 3 to 24 h after ECS. While the downregulation of InsP3R1 by accelerated protein degradation has been reported, our results indicate that the downregulation of InsP3R1 occurs at the mRNA level. This finding, along with our previous report on the InsP3 3-kinase(A), suggests that ECS regulates the phosphoinositide mediated signaling, which might be related to the therapeutic mechanism of ECS.

The induction of BDNF and c-fos mRNA in the hippocampal formation after febrile seizures.

In this study we investigated the expression of brain-derived neurotrophic factor (BDNF) and c-fos mRNA in the hippocampal formation after febrile seizures (FSs) with in situ hybridization histochemistry using riboprobes. The induction of BDNF mRNA was firstly observed in the dentate gyrus at 30 min after FSs. The expression in the dentate gyrus peaked at 3 h and returned to basal level at 24 h. It was also observed in the CA3 of hippocampus from 2 to 3 h. The induction of c-fos mRNA was observed in the dentate gyrus at 30 min and 1 h. These observations suggest that BDNF and c-fos are the genes whose expression can be altered by FSs and might be related to pathologic alterations after FSs.

Isolation of novel human fetal brain cDNAs mapped to human chromosome bands, 1q25 and 8q24.1.

We isolated chromosome band-specific human fetal brain cDNAs by the microdissection mediated cDNA capture method, and localized these cDNA using in situ hybridization histochemistry with developing rat brain sections. Uni-Amp cDNAs were prepared from an 18-week old human fetal brain, and hybridized to human metaphase chromosomes. Eight Uni-Amp cDNAs, hybridized to chromosome band 1q25 or 8q24.1, were recovered by microdissection and PCR amplification with Uni-Amp primers. Among these cDNAs, two novel genes (FB113 of 8q24.1 and FB134 of 1q25) showed a temporospatially interesting expression pattern in the developing rat brains. The expression of FB113 was under dynamic regulation in the developing granule cells of cerebellum and dentate gyrus. FB134 showed a nervous tissue specific expression pattern and an exclusively prominent expression in the developing presubiculum and parasubiculum. By the fluorescence in situ hybridization using human genomic DNAs, FB113 and FB134 were mapped back to the human chromosome bands 8q24.1 and 1q25, respectively. These results indicate that combined application of the microdissection mediated cDNA capture method and in situ hybridization histochemistry can be used for the isolation of chromosomal band-specific genes related to brain development or human genetic diseases.

Magnetic resonance image-based cerebellar volumetry in healthy Korean adults.

The effects of age and gender on cerebellar size have not been established yet. To understand these effects, the area of cerebellar vermis and the volume of cerebellum were measured using serial magnetic resonance images of 124 Korean adults free of neurologic symptoms and signs. Cerebellar volume of male was significantly larger than that of female, although the size of vermis did not show significant gender difference. Correlation analysis revealed that cerebellar volume was not affected by aging. Regressional analysis demonstrated that female vermis had a tendency to shrink after age of 50, whereas male vermis and total cerebellar volume in both sexes were not altered with aging. The different response of vermis with aging and maintenance of cerebellum volume need to be more explored.

Morphologic investigation of rolling mouse Nagoya (tg(rol)/tg(rol)) cerebellar Purkinje cells: an ataxic mutant, revisited.

Rolling mouse Nagoya (rolling: tg(rol)) is a neurologic mutant mouse exhibiting severe ataxia. Two alleles of the rolling mutation, tottering (tg) and leaner(tg(la)), have been identified as mutations in the voltage-dependent calcium channel alpha1A subunit. No specific light and electron microscopic findings have been reported for the rolling mouse cerebellum except a decreased number of granule cells, while altered Purkinje cell/parallel fiber synapses have been observed in tottering and leaner cerebella. Rolling mouse cerebella were analyzed using anti-calbindin-D immunohistochemistry and transmission electron microscopy to investigate Purkinje cell morphology and synaptic contacts between Purkinje cell dendritic spines and parallel fiber varicosities. Multiple Purkinje cell dendritic spines synapsing with single parallel fiber varicosities were frequently observed in rolling cerebella. The correlation between the presence of altered Purkinje cell synapses and ataxia in rolling mice warrants further investigation.

An ultrastructural study of granule cell/Purkinje cell synapses in tottering (tg/tg), leaner (tg(la)/tg(la)) and compound heterozygous tottering/leaner (tg/tg(la)) mice.

Homozygous tottering (tg/tg) and compound heterozygous tottering/leaner (tg/tg(la)) mutant mice exhibit juvenile onset of three abnormal neurological phenotypes: (i) petit mal-like epilepsy; (ii) ataxia; and (iii) an intermittent myoclonus-like movement disorder. Homozygous leaner mice (tg(la)/tg(la)) exhibit early onset of ataxia (postnatal days 10-12), and also exhibit the myoclonus-like movement disorder and evidence of absence seizure activity; the myoclonus-like disorder is most evident in the first month of life, then diminishes in severity and frequency. The ultrastructure of the cerebellar molecular layer was examined in adult (six to eight months) and juvenile (20-25 days) mice of all three mutant genotypes. In mice of all three genotypes and both ages, Purkinje cell dendritic spines were observed to make multiple contacts with individual parallel fiber varicosities in all sections analysed. These multiple synaptic units were observed in both anterior and posterior vermis and hemispheres of the cerebellum, and ranged from two to nine spines/parallel fiber varicosity. Occasionally, one of the postsynaptic spines belonged to an ectopic spine emerging from the proximal region of a Purkinje cell dendrite. This increase in the multiple synaptic index of some parallel fiber varicosities was observed in juvenile tottering mice before the onset of the symptoms of the neurological disorders. This is highly suggestive that the onset of the neurological phenotype is not a primary cause of multiple Purkinje cell dendritic spines synapsing with single parallel fiber varicosities in these mice, but on the contrary, that it could be the cause of the ataxic symptoms.

MK-801, a non-competitive NMDA receptor antagonist, prevents postischemic decrease of inositol 1,4,5-trisphosphate receptor mRNA expression in mongolian gerbil brain.

Changes of inositol 1,4,5-trisphosphate receptor (IP3R) mRNA expression after transient brain ischemia and the effect of MK-801, a non-competitive N-methyl-D-aspartic acid (NMDA) receptor antagonist, on the IP3R mRNA expression was studied in mongolian gerbil brain by in situ hybridization. Transient ischemia was induced by ligating left common carotid artery for 10 min, and the animals were allowed recovery from 15 min to 24 h. MK-801 was introduced intraperitoneally 30 min before ischemia. IP3R mRNA expression was decreased in dentate gyrus and hippocampus from 90 min until 24 h after ischemia. MK-801 pretreatment prevented the change of IP3R mRNA expression after ischemia. These results suggest that IP3R mRNA expression in ischemia may be related with NMDA receptor.

Expression of calcium channel alpha1A mRNA and protein in the leaner mouse (tgla/tgla) cerebellum.

Homozygous leaner mice carry an autosomal recessive mutation in the Ca2+ channel subunit gene, alpha1A, causing them to exhibit severe ataxia, petit-mal-like epilepsy and a myoclonus-like movement disorder. Expression of alpha1A mRNA in cerebella from 20-day-old homozygous leaner mice was compared to control mice, using in situ hybridization histochemistry. Expression of alpha1A protein was examined in cerebella from 20-day-old homozygous leaner and control mice using immunocytochemistry. No differences in either mRNA or protein expression of the alpha1A subunit were observed when homozygous leaner mice were compared to age-matched controls. Therefore, functional alterations in P/Q-Type Ca2+ channels containing the alpha1A subunit need to be explored to further understand the relationship of mutations in the alpha1A gene to the pathogenesis of the neurologic disorders occurring in leaner mice.

Chromosomal localization and neural distribution of voltage dependent calcium channel beta 3 subunit gene.

Voltage dependent calcium channel (VDCC) mediates the influx of free calcium ions that acts as a signal transducer. The beta 3 subunit of the VDCC regulates the activation (opening) and inactivation (closing) kinetics through phosphorylation/dephosphorylation. We isolated a genomic clone of the human VDCC beta 3 subunit from a human genomic DNA library using VDCC beta 3 cDNA as a probe. We localized VDCC beta 3 with this genomic DNA on the chromosome by fluorescent in situ hybridization, and the distribution of VDCC beta 3 in the nervous system was investigated in rats by in situ hybridization histochemistry with rat VDCC beta 3 cDNA. The gene for the VDCC beta 3 was specifically localized on human chromosome 12q13. The mRNA for the VDCC beta 3 was predominantly expressed in the nervous system. In the brain, a strong expression of VDCC beta 3 mRNA was found in the medial habenular nucleus, a high level of expression was observed in the olfactory bulb and cerebellum, and a relatively high level of VDCC beta 3 mRNA was localized in the cerebral cortex, caudate-putamen and hippocampal formation. Interestingly, this distribution pattern is very similar to that of the rbE-II, mid-low VDCC 1 subunit, and it is suspected that VDCC beta 3 and rbE-II may function together as a pair.