Angular Head Velocity Cells within Brainstem Nuclei Projecting to the Head Direction Circuit

The sense of orientation of an animal is derived from the head direction (HD) system found in several limbic structures and depends on an intact vestibular labyrinth. However, how the vestibular system influences the generation and updating of the HD signal remains poorly understood. Anatomical and lesion studies point toward three key brainstem nuclei as key components for generating the HD signal-nucleus prepositus hypoglossi, supragenual nucleus, and dorsal paragigantocellularis reticular nuclei. Collectively, these nuclei are situated between the vestibular nuclei and the dorsal tegmental and lateral mammillary nuclei, which are thought to serve as the origin of the HD signal. To determine the types of information these brain areas convey to the HD network, we recorded neurons from these regions while female rats actively foraged in a cylindrical enclosure or were restrained and rotated passively. During foraging, a large subset of cells in all three nuclei exhibited activity that correlated with the angular head velocity (AHV) of the rat. Two fundamental types of AHV cells were observed; (1) symmetrical AHV cells increased or decreased their firing with increases in AHV regardless of the direction of rotation, and (2) asymmetrical AHV cells responded differentially to clockwise and counterclockwise head rotations. When rats were passively rotated, some AHV cells remained sensitive to AHV, whereas firing was attenuated in other cells. In addition, a large number of AHV cells were modulated by linear head velocity. These results indicate the types of information conveyed from the vestibular nuclei that are responsible for generating the HD signal.SIGNIFICANCE STATEMENT Extracellular recording of brainstem nuclei (nucleus prepositus hypoglossi, supragenual nucleus, and dorsal paragigantocellularis reticular nucleus) that project to the head direction circuit identified different types of AHV cells while rats freely foraged in a cylindrical environment. The firing of many cells was also modulated by linear velocity. When rats were restrained and passively rotated, some cells remained sensitive to AHV, whereas others had attenuated firing. These brainstem nuclei provide critical information about the rotational movement of the head of the rat in the azimuthal plane.

Vestibular Nucleus Involvement in Patients With Acute Vertigo Due to Herpes Zoster Oticus or Vestibular Neuritis

OBJECTIVES

Herpes zoster oticus (HZO) typically provokes vestibular symptoms and is traditionally viewed as a cranial nerve equivalent of shingles, but in contrast to vestibular neuritis (VN), it is unclear whether the pathology of HZO is limited to the vestibular nerve (neuritis) or can also involve the brainstem (nucleitis).

METHODS

We retrospectively compared brain MRIs of patients with HZO with those of patients with VN to study radiologic changes in the brainstem.

RESULTS

Five of 10 patients with HZO showed signal abnormalities in the vestibular nuclei, which lie in multiple vascular territories, whereas no patients with VN exhibited such findings.

DISCUSSION

HZO may at least in part reflect vestibular nucleitis, as opposed to a pure neuritis.

Convergent innervations of mesencephalic trigeminal and vestibular nuclei neurons onto oculomotor and pre-oculomotor neurons-Tract tracing and triple labeling in rats

In studies of vestibulo-ocular reflex (VOR), the horizontal VOR circuit is much clearer than vertical-torsional VOR. The circuit and mechanism of gravity-related vertical-torsional VOR is probably weak. "Somatosensory vestibular interaction" is a known extra source to facilitate VOR, and cervico-ocular reflex is a representative for torsional VOR compensation. Whereas, how the cervical afferents finally reach the oculomotor system is less documented. Actually, when the head tilts, which generates cervico-ocular reflex, not only the neck muscle is activated, but also the jaw muscle is stretched by gravity dragged mandible and/or tissue-muscle connection between the mandible and clavicle. We have previously identified a projection from the jaw muscle afferent mesencephalic trigeminal nucleus (Vme) neurons to oculomotor nuclei (III/IV) and their premotor neurons in interstitial nucleus of Cajal (INC)-a well-known pre-oculomotor center manipulating vertical-torsional eye movements. We hypothesized that these projections may interact with vestibulo-ocular signals during vertical-torsional VOR, because effects of gravity on jaw muscles and bones has been reported. Thus, we injected different anterograde tracers into the Vme and medial vestibular nucleus (MVN)-the subnuclear area particularly harboring excitatory vestibulo-ocular neurons, and immunostained III/IV motoneurons. Retrograde tracer was injected into the III in the same animals after dual anterograde tracers' injections. Under confocal microscope, we observed the Vme and MVN neuronal endings simultaneously terminated onto the same III/IV motoneurons and the same INC pre-oculomotor neurons. We consider that jaw muscle proprioceptive Vme neurons projecting to the III/IV and INC would sense spindle activity if the jaw muscle is stretched by gravity dragged mandible or connection between mandible and clavicle during head rolling. Therefore, the convergent innervation of the Vme and MVN neurons onto the oculomotor and pre-oculomotor nuclei would be a neuroanatomic substrate for interaction of masticatory proprioception with the vestibulo-ocular signals upon the oculomotor system during vertical-torsional VOR.

The Long and Winding Road-Vestibular Efferent Anatomy in Mice

The precise functional role of the Efferent Vestibular System (EVS) is still unclear, but the auditory olivocochlear efferent system has served as a reasonable model on the effects of a cholinergic and peptidergic input on inner ear organs. However, it is important to appreciate the similarities and differences in the structure of the two efferent systems, especially within the same animal model. Here, we examine the anatomy of the mouse EVS, from its central origin in the Efferent Vestibular Nucleus (EVN) of the brainstem, to its peripheral terminations in the vestibular organs, and we compare these findings to known mouse olivocochlear anatomy. Using transgenic mouse lines and two different tracing strategies, we examine central and peripheral anatomical patterning, as well as the anatomical pathway of EVS axons as they leave the mouse brainstem. We separately tag the left and right efferent vestibular nuclei (EVN) using Cre-dependent, adeno-associated virus (AAV)-mediated expression of fluorescent reporters to map their central trajectory and their peripheral terminal fields. We couple this with Fluro-Gold retrograde labeling to quantify the proportion of ipsi- and contralaterally projecting cholinergic efferent neurons. As in some other mammals, the mouse EVN comprises one group of neurons located dorsal to the facial genu, close to the vestibular nuclei complex (VNC). There is an average of just 53 EVN neurons with rich dendritic arborizations towards the VNC. The majority of EVN neurons, 55%, project to the contralateral eighth nerve, crossing the midline rostral to the EVN, and 32% project to the ipsilateral eighth nerve. The vestibular organs, therefore, receive bilateral EVN innervation, but without the distinctive zonal innervation patterns suggested in gerbil. Similar to gerbil, however, our data also suggest that individual EVN neurons do not project bilaterally in mice. Taken together, these data provide a detailed map of EVN neurons from the brainstem to the periphery and strong anatomical support for a dominant contralateral efferent innervation in mammals.

Whole-brain monosynaptic inputs and outputs of glutamatergic neurons of the vestibular nuclei complex in mice

Vestibular nuclei complex (VN) glutamatergic neurons play a critical role in the multisensory and multimodal processing. The dysfunction of VN leads to a series of vestibular concurrent symptoms, such as disequilibrium, spatial disorientation, autonomic disorders and even emotion disorders. However, the reciprocal neural connectivity in the whole brain of VN glutamatergic neurons was incompletely understood. Here, we employed a cell-type-specific, cre-dependent, modified virus vector to retrogradely and anterogradely trace VN glutamatergic neurons in the VGLUT2-IRES-Cre mouse line. We identified and analyzed statistically the afferents and efferents of VN glutamatergic neurons in the whole brain, and also reconstructed monosynaptic inputs distribution of VN glutamatergic neurons at the three-dimensional level with the combination of a fluorescence micro-optical sectioning tomography system (fMOST). We found that VN glutamatergic neurons primarily received afferents from 57 nuclei and send efferents to 59 nuclei in the whole brain, intensively located in the brainstem and cerebellum. Projections from nuclei in the cerebellum targeting VN glutamatergic neurons mainly performed the balance control - the principal function of the vestibular system. In addition, VN glutamatergic neurons sent projections to oculomotor nucleus, trochlear nucleus and abducens nucleus dominating the eye movement. Except for the maintenance of balance, VN glutamatergic neurons were also directly connected with other functional regions, such as sleep-wake state (locus coeruleus, dorsal raphe nucleus, and laterodorsal tegmental nucleus, gigantocellular reticular nucleus, lateral paragigantocellular nucleus, periaqueductal gray, subcoeruleus nucleus, parvicellular reticular nucleus, paramedian raphe nucleus), and emotional regulation (locus coeruleus and dorsal raphe nucleus). Hence, this study revealed a comprehensive whole-brain neural connectivity of VN glutamatergic neurons and provided with a neuroanatomic foundation to further study on central vestibular circuits.

Brainstem BOLD response to visual and acoustic stimuli

Understanding the fundamental roles of brainstem function resulting in proper motor control is critical to motor-rehabilitation after brain injuries. In particular, vestibular and reticular formation nuclei are thought to be associated with spasticity in chronic stroke patients. We used two kinds of stimuli in 10 healthy subjects to activate these nuclei while collecting high-resolution (1.5-mm) fMRI across the majority of brainstem. Optokinetic stimuli evoked illusory self-motion to activate the vestibular nuclei. Acoustic-startle stimuli were sets of loud tones designed to activate of the reticular formation. We summarized the response represented in a form of activation volume, mean percent signal change, and the phase delay (time lag) following the stimulus. We observed patterns of significant activations in the brainstem but did not find significant differences between the stimulus. We conclude that more sensitive measurement techniques are needed to reliably detect vestibular and reticular formation nuclei responses.

[The nucleus origin of acoustically evoked short latency negative response in guinea pigs]

OBJECTIVE

This study established a model of acoustically evoked short latency negative response (ASNR) in guinea pigs. Stereotaxic coordinate guided electrolytic lesion was applied to animal brainstem nuclei, the vestibular nucleus and the cochlear nucleus, to define the neural origin of ASNR.

METHODS

Twenty four guinea pigs with normal hearing were randomly divided into the control group (8 subjects, 16 ears) and the deafened group (16 subjects, 32 ears). Each animal experienced the auditory brainstem response (ABR) test. According to the presence of ASNR, the deafened group was further divided into ASNR group and non-ASNR group. Electrolytic lesion was conducted to the vestibular nucleus and cochlear nucleus respectively, followed by ABR test. The lesion structures were verified by brainstem slice and microscope.

RESULTS

In deafened group, the ASNR was elicited in 10 ears (31.3%). The ASNR was eliminated due to the electrolytic destruction to the vestibular nucleus, but it remained unchanged after the same procedure to the cochlear nucleus.

CONCLUSION

It is clear that the ASNR is originated from the vestibular nucleus, but not the cochlear nucleus.

An antisense oligonucleotide to brain-derived neurotrophic factor delays postural compensation following unilateral labyrinthectomy in guinea pig

An antisense oligonucleotide to brain-derived neurotrophic factor (BDNF) was delivered by osmotic mini-pump at a 1 mM concentration via a cannula into the ipsilateral vestibular nucleus complex from 15 to 56h following unilateral labyrinthectomy in guinea pigs. Compared with the control groups, vestibular compensation of roll head tilt was significantly delayed (p < 0.05), while compensation of spontaneous nystagmus and yaw head tilt was unaffected. These results suggest that neurotrophins such as BDNF may be involved in specific aspects of the vestibular compensation process.

An age-dependent sensitivity of the roll-induced vestibuloocular reflex to hypergravity exposure of several days in an amphibian (Xenopus laevis)

In tadpoles of the Southern Clawed Toad (Xenopus laevis), the effects of an exposure to hypergravity of several days duration on the development of the roll-induced static vestibuloocular reflex (rVOR) were investigated. Special attention was given to the onset of the 9 or 12 days lasting 3G-period during early life. First recordings of the rVOR characteristics for complete 360 degrees rolls of the tadpoles were performed 24 hrs after the end of the 3G-period. The rVOR peak-to-peak amplitudes as well as the VOR-gain for a roll angle of 15 degrees from 3G-and 1G-samples recorded at the 2nd and 3rd day after 3G-termination agreed for the youngest group, but were reduced by approx. 30% in the older tadpoles. Long-term observations lasting up to 8 weeks after termination of the 3G-period, demonstrated (i) an early retardation of the development, and (ii) a developmental acceleration in all groups so that after 2 weeks in the stage 6/9- and 33/36-samples and after 8 weeks in the stage 45-tadpoles, the rVOR-amplitude as well as the rVOR-gain for a 15 degrees roll were at the same level in both the 3G- and the 1G-samples. The results support the existence of a sensitive period for the rVOR development, and additionally demonstrate the importance of the period of the first appearance of the rVOR for the development of adaptive properties of the underlying neuronal network. They also demonstrate the dominant efficiency of genetic programs in the functional development of the vestibular system. Methodological approaches are discussed which will be useful in the further description of the critical period. They include studies on the neuronogenesis and synaptic maturation within the vestibular pathways as well as on the fundamentals of buoyancy control during swimming. A modular but closed mini-system for experimental use is described which allows survival periods lasting many weeks and multiple types of treatments of developing aquatic animals in orbit, controlled automatically.

LIPIDS OF ISOLATED NEURONS

1. Lipids were extracted from neurons isolated from the lateral vestibular nucleus of ox (Bos taurus L.) and the ganglia of Aplysia punctata Cuvier. 2. Thin-layer chromatography of ox-neuron lipid revealed three major fractions corresponding to neutral lipid, phosphatidylethanolamine and phosphatidylserine. Part of the phosphatidylethanolamine was present as the plasmalogen. 3. Aplysia-neuron lipid contained neutral lipid, phosphatidylethanolamine and phosphatidylserine. Both phospholipids appeared to be present predominantly as the plasmalogen form. 4. The fatty acids of alkali-labile lipids of ox neurons were examined by gas-liquid chromatography. The major fatty acids were oleic acid, stearic acid and palmitic acid.

Periodic vestibulocerebellar ataxia, an autosomal dominant ataxia with defective smooth pursuit, is genetically distinct from other autosomal dominant ataxias

BACKGROUND

Periodic vestibulocerebellar ataxia is an autosomal dominant disorder characterized by defective smooth pursuit, gaze-evoked nystagmus, ataxia, and vertigo. The age of onset ranges from the third to the sixth decade. To date, all patients have originated from North Carolina, suggesting a single common founder.

OBJECTIVE

To clarify the classification of periodic vestibulocerebellar ataxia by determining whether it is allelic to other autosomal dominant cerebellar ataxias for which genes have been either localized or identified.

METHODS

Blood was collected and DNA isolated from 66 subjects (19 affected individuals) in two multigenerational families. The microsatellite markers used in the analysis either flanked or were tightly linked to the disease gene regions. Two-point and multipoint linkage analyses were performed to define the limits of exclusion.

RESULTS

Periodic vestibulocerebellar ataxia was excluded from loci linked to spinocerebellar ataxia type 1 (chromosome 6p), type 2 (chromosome 12q) type 3/Machado/Joseph disease (chromosome 14q), type 4 (chromosome 16q), and type 5 (11cent) as well as to episodic ataxia with myokymia (chromosome 12p), episodic ataxia with nystagmus (chromosome 19p), acetazolamide-responsive hereditary paroxysmal cerebellar ataxia (chromosome 19p), and dentatorubral-pallidoluysian atrophy/Haw River syndrome (chromosome 12p).

CONCLUSION

Periodic vestibulocerebellar ataxia is genetically distinct from those autosomal dominant ataxias for which chromosomal localization has been established.

Responses of neurons in the central cervical nucleus of the rat to proprioceptive and vestibular inputs

Activity of neurons in the central cervical nucleus (CCN) was recorded extracellularly in decerebrate, immobilized rats. Neurons were identified by their antidromic response to electrical stimulation of the contralateral superior cerebellar peduncle. Stimulation of the ipsilateral dorsal neck muscles (m. biventer cervicis and complexus [BCC]; m. splenius [S]) by a single electric pulse evoked a short-latency (approximately 1 ms) excitatory response in the majority of CCN neurons. The response was usually followed by a period of inhibition of the resting discharge (approximately 20 ms). Stimulation of the contralateral BCC or S usually produced only inhibition of the resting discharge (approximately 20 ms). Mechanical stretching of BCC or S resulted in activation (about 100% increased firing rate) of the ipsilateral CCN neurons, lasting for the duration of the stretch. A pronounced dynamic component, i.e. an extra-excitation at the beginning of the stretch and inhibition after termination of the stretch, was also observed. Stroking and pinching of the skin in the neck region affected the tested CCN neurons, while cutaneous stimuli at other sites of the body were inefficient. Stimulation of the vestibular receptors was performed in two ways. (i) Unilateral galvanic stimulation of the labyrinths by constant current pulses through the external acoustic meatus affected all CCN neurons tested. Contralateral stimulation with negative current was found to be most efficient; it produced excitation followed by inhibition. (ii) Natural vestibular stimulation was performed by rotating the animal in the transverse plane (roll, +/- 10 degrees) or the sagittal plane (pitch, +/- 5 degrees). Sinusoidal movements (0.5-1 Hz) or trapezoid movements were applied. Sinusoidal roll tilt evoked responses in all neurons tested, with a peak discharge during contralateral rolling or at the moment of transition from the ipsi- to contralateral position. All tested CCN neurons also responded statically to roll tilt, i.e. their tonic activity increased with up to 65%, of which the majority (80%) responded in the continuously maintained contralateral roll tilt position compared to the ipsilateral. Sinusoidal pitch tilt also affected all tested neurons, although the reaction was smaller than compared to roll. They usually responded by increasing their firing rate when moving towards the nose-down position. A static response (40-60% difference in the firing rate between the extreme pitch positions) was observed in some neurons. No tested neurons showed any clear rhythmic modulation during either spontaneous or induced, real or fictive locomotion.(ABSTRACT TRUNCATED AT 400 WORDS)

A critical study into the fecal analysis routine in practice in Jordan

The fecal analysis routine adopted by 21 diagnostic medical laboratories in Jordan was surveyed by the means of a questionnaire filled in by the senior year medical technology students who spent 16 weeks in these laboratories as trainees. The recommended routine fecal analysis was not completed satisfactorily by any of the laboratories surveyed. The wet mount microscopic examination was the sole technical test done for the examination of parasite and ova by the majority of the laboratories, 90% (19 of 21). None of the surveyed laboratories adopted the routine use of a concentration technique. One hundred and eight known positive stool specimens were examined by four qualified medical technologists. The wet mount technique revealed positivity in 53% of specimens only, while the formol-ether sedimentation technique yielded 98-100% positivity. This indicates the value of the formol-ether sedimentation technique over the practiced wet mount technique in the routine fecal analysis.

Differential effects of bicuculline and muscimol microinjections into the vestibular nuclei on simian eye movements

1.) Eye movements were recorded in four Java monkeys (M. fascicularis) after unilateral microinjections (1 microliter, concentration 1 micrograms/microliter) of the GABA antagonist, bicuculline, and the GABA agonist, muscimol, into oculomotor related regions of the vestibular nuclei. Eye movements were investigated in the dark and light during spontaneous eye movements, vestibular stimulation (sinusoidal: 0.2 Hz, +/- 40 deg/s, and velocity trapezoid: 40 deg/s2 acceleration, 120 deg/s constant velocity), and visual-vestibular conflict stimulation. 2.) Bicuculline and muscimol injections consistently led to specific eye movement changes, which were maximal 5-10 min after bicuculline injection (muscimol 10-30 min), and lasted 90-120 min (muscimol 2-4 h). Control injections with NaCl (0.9%) into the responsive area and with bicuculline 2-3 mm more lateral showed no effect. 3.) Bicuculline induced a spontaneous nystagmus of 40.9 deg/s (average, range 10.5-93 deg/s), beating in 60% of the cases to the contralateral and in 40% to the ipsilateral side. The analysis of the slope of the slow phase gave no evidence for an additional gaze holding deficit. The VOR gain in the dark showed a slight decrease (pre: 0.96; post: 0.86) on average. The time constant of decay for slow phase nystagmus velocity after vestibular ramp stimulation was reduced, reflecting a 'velocity storage' deficit. After bicuculline injections nystagmus suppression in the light and during visual-vestibular conflict stimulation was generally well preserved. 4.) After muscimol injections horizontal gaze holding was severely affected. Each saccade was followed by an exponentially decreasing postsaccadic drift with a time constant as short as 250 ms (average 414 ms). The eyes always drifted towards a null-position, which generally did not coincide with the midposition of the eye. The null-position could move up to 35 deg to the contralateral or ipsilateral side. The highly distorted eye movements after muscimol injections prevented VOR-measurements based on eye velocity. Instead vestibular stimulation led to a shift of the null-position with an amplitude corresponding to a gain (eye position/stimulus position) of 0.17 (average) at 0.2 Hz (+/- 40 deg/s). Vertical eye movements did not show a major gaze holding deficit. 5.) From the experiments it can be concluded that the inhibitory transmitter GABA plays an important role for eye movement generation within the vestibular nuclei. Bicuculline induces mainly a vestibular imbalance with little evidence for a neural integrator deficit. In contrast unilateral muscimol injections lead to a complete, reversible loss of function for the common horizontal neural integrator, which converts eye velocity into eye position signals. The accompanying shift of the null-position reflects an additional vestibular imbalance.

[Bilateral internuclear ophthalmoplegia in association with basilar artery occlusive disease]

A 56 year-old man presented with vertigo and the right sided weakness. Neurological examination revealed a lethargic man with good orientation to three spheres. His neck was supple. He had anisocoria, the right pupil being larger than the left by 1.5 mm with sluggish light reaction bilaterally. He had exotropia of the right eye in primary gaze. The abduction of both eyes were full with terminal horizontal nystagmus. The adduction of both eyes were quite limited in each eye. He had a limited upward gaze with poor convergence. These were interpreted as the syndrome of the medial longitudinal fasciculus (MLF) bilaterally. He had a depressed gag reflex on the right side with tongue deviation to the right. He had a mild weakness of the right side limb and also had the right sided hemihyperesthesia including his face to pain and temperature. Twenty four hours after the onset, the left brachial angiography revealed a complete occlusion of the rostral portion of the basilar artery without visualization of the posterior cerebral and superior cerebellar arteries bilaterally. CT scans three days after the onset revealed a low density area in the mid pons with extension rostrally up to the mesencephalon. Four days later he became quadriplegic with bilateral horizontal gaze palsy. No more internuclear ophthalmoplegia is noted on both sides. The midline location of the MLF in the pons, and the separate blood supplies by different paramedian branches of the basilar artery, form the anatomical explanation for the frequent unilaterality of vascular and bilaterality of demyelinating lesions. Bilateral MLF syndrome has been considered almost pathognomonic of multiple sclerosis.(ABSTRACT TRUNCATED AT 250 WORDS)

[Peripheral vestibular neuropathy and a central vestibular equivalent]

The results of the initial and follow-up examinations of 217 patients with vestibular neuritis and 63 patients with a so called "vestibular neuritis syndrome" were statistically evaluated and quantified using the vestibular index. The results for patients with vestibular neuritis were compared at the different stages to those of patients after neurectomy of the vestibular nerve. The site of the lesion in patients with vestibular neuritis may therefore be in the region of Scarpa's ganglion (retrolabyrinthine). Alternatively the total peripheral end-organ may be affected. This conclusion agrees with histopathological findings. The "vestibular neuritis syndrome" included patients with the same history as patients with true vestibular neuritis but with signs of a central-vestibular disturbance or a combination of a central and peripheral lesion of the vestibular system. In these cases the lesion may be situated closer to the vestibular nuclei or its central pathways. Both disorders were similar with respect to history, etiology and the prognosis.

DDT myoclonus: sites and mechanism of action

Intragastric injection of the insecticide DDT produces a stimulus-sensitive myoclonus in mice and rats. Unilateral stereotaxic infusions of DDT into rat medullary reticular formation also induced generalized myoclonus, identical to that produced by systemic administration. Similar myoclonus, but of lesser intensity, occurred when DDT was injected into cerebellar nuclei, red nucleus, and the inferior olive. Multiple other regions of the brain were resistant to the myoclonic action of locally infused DDT. Direct infusions into the medullary reticular formation of allethrin, which has a similar action on neuronal membranes as DDT, or the glycine receptor antagonist, strychnine, also elicited myoclonus.

Lateralization, impedance, auditory brain stem response and synthetic sentence audiometry in brain stem disorders

Applied individually, the conventional audiometric tests are unsatisfactory in the diagnosis of retrocochlear disorders. An accurate identification of a retrocochlear lesion, however, is not always possible using a single test, and only an appropriate test battery provides the basis for correct prediction of a retrocochlear lesion. Because of this observation, lateralization tests, impedance studies, auditory brain stem responses and speech audiometry with synthetic sentences have been applied to patients affected with retrocochlear disorders (acute nucleoreticular vestibular syndrome, multiple sclerosis and focal lesions). Analysis of the results has demonstrated the value of the tests employed, but the various tests were not strongly correlated and are therefore complementary.

[Changes in the posture of healthy rats following intracranial administration of brain extracts from animals with experimental vestibulopathies]

A fraction consisting of low-molecular components (LMCs) was isolated from the brain of rats with unilateral destruction of the Deuters lateral vestibular nucleus (LVN) or with the generator of excitation (GE) created in the LVN with tetanus toxin. Intracranial administration of the preparation to normal rats produced the tension of body muscles, bending and opposite changes in the muscle tone of the hind limbs - the delay in the pulling up of the paw passively set aside and enhancement of the flexor tone of the opposite hind limb. The delayed pulling up of the hind paw in the recipients occurred on the side where the donors manifested an activated LVN (on the GE side or on the opposite side of the nucleus destruction). The effects cited did not occur if LMCs were exposed to proteolytic destruction or if the administration of LMCs was preceded by intraperitoneal injection of nalorphine, as well as if LMCs were administered in conjunction with naloxone. It is suggested that the test factors of the postural asymmetry are of peptide nature and that the opiate brain systems participate in the formation of the responses to their administration. A possible contribution of neurochemical lateralization of the brain to the phenomena of the "pathological condition transfer" is discussed.

Age related differences in binding of concanavalin A to plasma membranes of isolated neurons

Neurons isolated from the lateral vestibular nucleus of young adult and senescent Fischer-344 rats were incubated with fluorescamine-labelled Concanavalin A (fl-Con A) alone, or following incubation in trypsin or Vibrio cholerae neuraminidase. They were then observed and photographed. Microdensitometric analysis of fluorescence micrographs showed that senescent rat neurons were significantly more fluorescent than those from young adult rats. Additionally, either patches or caps of fl-Con A were seen on the surface of neurons from senescent rats, while most young adult rat neurons bound fl-Con A uniformly. Pretreatment with trypsin or neuraminidase had no effect on the amount of fluorescence on the surface of senescent rat neurons, and only a slight effect on the surface distribution. Trypsin and neuronal plasma membranes of young adult rats and a rearrangement of the binding pattern in the majority of neurons observed.

Acceptable and controversial approaches to treating the child with learning disabilities

There are many professionals in multiple disciplines developing approaches for helping children with learning disabilities. Much of these data and reports are published in journals normally not read by physicians. On occasion, such publications are reported in newspapers or lay magazines. Thus, parents may know of ideas and suggestions before the professional. It is understandable that the parent of a handicapped child would continually seek out improved ways of helping his or her child. The treatment of choice is basically special education. Medication will minimize the hyperactivity and distractability; psychotherapy may minimize the emotional effects. However, special educational therapy for the underlying learning disabilities is essential. No one yet has a rapid or "guaranteed" cure. Parents are often caught in the middle. They turn to their physician for guidance. It is the purpose of this paper to review the significant literature in an effort to assist the family physician in providing this guidance.

The presence of phosphatidylcholine in neurons isolated from the lateral vestibular nucleus of ox brain

1. Lipid was extracted from neurons isolated from the lateral vestibular nucleus of ox brain and examined by two-dimensional thin-layer chromatography. 2. The major lipids found were phosphatidylethanolamine and its plasmalogen, phosphatidylcholine, phosphatidylserine and cholesterol.