In vivo recording of monophasic action potentials in awake dogs

Assessment of cardiac repolarization in dogs in vivo is of interest in numerous experimental canine models. Previous studies have used monophasic action potentials (MAPs) to investigate repolarization in vitro and in vivo in anesthetized animal models. Therefore, an approach for recording MAPs in awake dogs without the interference of anesthesia is desirable. We describe an experimental technique to record MAPs in conscious dogs by means of conventional rubber introducers which are implanted into the internal jugular vein. Atrial as well as ventricular MAPs can be simultaneously measured without complications. Pacing thresholds are low and stable over time. Continuous MAP recordings of stable amplitude can be achieved from the same endocardial site for periods up to 1h. Antegrade and retrograde atrioventricular nodal conduction properties can be assessed. Programmed stimulation can be performed to simultaneously determine local refractory periods and MAP duration at cycle lengths from 500 to 200ms. In awake, unsedated dogs measuring MAPs via rubber introducers permits safe, long-term recording of MAPs. Such recordings may be useful for safety pharmacologic studies in evaluating cardiovascular and noncardiovascular drugs with respect to their effects on repolarization. In various canine in vivo models including in vivo models of long QT syndrome, heart failures or sudden cardiac death, the present technique permits electrophysiologic measurements without the interference of anesthesia.     

中枢神经元放电的在体多通道同步记录技术

中枢神经元放电的在体多通道同步记录技术是采用细胞外记录的方法来监测神经元群的同步电活动。该系统包括微电极阵列(microarray)、数据采集和分析系统。应用这一技术可以同步记录多个脑区的大量神经元的电活动,研究不同脑区的神经元放电在时间和空间上的联系,进而通过分析神经元的放电模式来研究大脑对外部事件的编码机制。     

Measuring human brain GABA in vivo

Gamma-aminobutyric acid (GABA) plays a pivotal role in suppressing the origin and spread of seizure activity. Low occipital lobe GABA was associated with poor seizure control in patients with complex partial seizures. Vigabatrin irreversibly inhibits GABA-transaminase, raising brain and cerebrospinal fluid (CSF) GABA concentrations. The effect of vigabatrin on occipital lobe GABA concentrations was measured by in vivo nuclear magnetic-resonance spectroscopy. Using a single oral dose of vigabatrin, the rate of GABA synthesis in human brain was estimated at 17% of the Krebs cycle rate. As the daily dose of vigabatrin was increased to up to 3 g, the fractional elevation of brain GABA was similar to CSF increase. Doubling the daily dose from 3 to 6g failed to increase brain GABA further. Increased GABA concentrations appear to reduce GABA synthesis in humans as it does in animals. With traditional antiepileptic drugs, remission of the seizure disorder was associated with normal GABA levels. With vigabatrin, elevated CSF and brain GABA was associated with improved seizure control. Vigabatrin enhances the vesicular and nonvesicular release of GABA. The release of GABA during seizures may be mediated in part by transporter reversal that may serve as an important protective mechanism. During a seizure, this mechanism may be critical in stopping the seizure or preventing its spread.     

在体神经元胞外记录用于大脑皮层可塑性研究

神经元网络可塑性是大脑学习和记忆功能的基础,可塑性的变化也是某些脑功能疾病的成因。研究大脑皮层可塑性不仅可以为认识可塑性机制提供基本方法,也可对自然衰老过程和神经退行性疾病的病理过程进行观测,进而可以为评价抗衰老药物和治疗神经退行性疾病提供新方法。本文基于经典的大鼠胡须配对模型建立了一套实验方案,通过在体细胞外记录实验的数据分析,比较修剪胡须后相同时间内神经元感受野不对称变化程度的差异,衡量不同生理条件下大鼠体感皮层神经元网络可塑性。本文以中年和青年大鼠体感皮层神经元网络可塑性比较为例,详细介绍了实验方法中的关键技术和操作,如皮层D2功能柱的定位和D2功能柱内不同层神经元的定位等,结果和我室以前相关研究证明了此实验方案的可行性。     

In vivo visualization of individual neurons in arthropod ganglia facilitates intracellular neuropil recording

Summary A simple method for the in vivo visualization of dye filled cells by laser illumination is used to characterize neurons in situ in the segmentai ganglia of the locust and the crayfish (Fig. 1). Neuron visualization provides the structural information necessary for identification of cells during an ongoing physiological experiment (Figs. 2, 3). Sequential penetrations of soma and neuropil as well as simultaneous double neuropil penetrations of spiking and nonspiking cells are facilitated by the visual control afforded by neuron visualization (Figs. 4, 5, 6). Furthermore, neuron visualization allows the sampling of cellular properties at multiple, predetermined sites in the dendritic and axonal arbors of identified neurons (Fig. 7) and aids in establishing synaptic connectivity through double neuropil recordings (Fig. 8).     

In vivo distribution of lithium in plasma and brain

A single administration of LiCl (0.5, 2 and 4 mmol/kg) to adult male albino rats produced a dose dependent increase of Li level in plasma, whole brain and brain regions. The concentration of Li in whole brain and brain regions was much less than that in plasma. Further, it is also found that concentration of Li in plasma reached a peak at 8 hr while that of Li in whole brain and brain regions reached a peak at 12 hr after the administration. The distribution and retention of Li was found to be highest in hypothalamus followed by striatum, pons-medulla, cerebellum and cerebral cortex. Daily administration of LiCl at a dose of 0.5 and 2 mmol/kg/day showed a time and dose dependent increase in plasma Li level up to a period of 21 consecutive days. But at higher dose (4 mmol/kg/day), on the other hand, under similar condition showed a time dependent increase in plasma Li level up to a period of 14 consecutive days and then gradually decreased with prolongation of treatment to 21 consecutive days. In brain there was no such decrease, rather increase in Li level was observed with the prolongation of duration of treatment, highest concentration of Li was found in hypothalamus and striatum than the rest of the brain regions. These results suggest that under short term treatment with LiCl, the clearance rate of Li in brain cell is much slower than that in plasma. Both single and long-term exposure of LiCl produces a dose dependent increase of Li in plasma, whole brain and brain regions.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vivo metabolism of 3-ketoceramide in rat brain

Eight hours after intracerebral injection of a double-labeled 3-ketoceramide⁴, [1-¹⁴C]lignoceroyl 3-keto [1-³H]sphingosine, various brain sphingolipids were isolated. Free ceramide and the ceramide portions of nonhydroxy cerebroside and sphingomyelin were further fractionated into subgroups containing longer-chain or shorter-chain fatty acids. Nonhydroxy ceramide, nonhydroxy cerebroside and sphingomyelin containing longer-chain fatty acids had significant quantities of radioactivity with ³H/¹⁴C ratios similar to each other but lower than that of the injected material. The sphingolipids containing shorter-chain fatty acids were also significantly labeled; however, the ³H/¹⁴C ratios were much higher than that of the injected material. Hydroxy-ceramide and sulfatides contained very little radioactivity. However, hydroxy-cerebroside contained an amount of radioactivity comparable to that of the longer-chain nonhydroxy cerebroside with a similar ³H/¹⁴C ratio. It is proposed that the injected 3-ketoceramide was converted into ceramide, cerebroside, and sphingomyelin and that the fatty acids of these lipids were partly replaced by other fatty acids during the metabolic conversions.     

In vivo recording of electrical activity of canine tracheal smooth muscle.

Electrical activity of the tracheal smooth muscle was studied using extracellular bipolar electrodes in 37 decerebrate, paralyzed, and mechanically ventilated dogs. A spontaneous oscillatory potential that consisted of a slow sinusoidal wave of 0.57 +/- 0.13 (SD) Hz mean frequency but lacked a fast spike component was recorded from 15 dogs. Lung collapse accomplished by bilateral pneumothoraxes evoked or augmented the slow potentials that were associated with an increase in tracheal muscle contraction in 26 dogs. This suggests that the inputs from the airway mechanoreceptors reflexly activate the tracheal smooth muscle cells. Bilateral vagal transection abolished both the spontaneous and the reflexly evoked slow waves and provided relaxation of the tracheal smooth muscle. Electrical stimulation of the distal nerve with a train pulse (0.5 ms, 1-30 Hz) evoked slow-wave oscillatory potentials accompanied by a contraction of the tracheal smooth muscle in all the experimental animals. Our observations in this in vivo study confirm that the electrical activity of tracheal smooth muscle consists of slow oscillatory potentials and that tracheal contraction is at least partly coupled to the slow-wave activity of the smooth muscle.     

Mapping human brain activity in vivo.

A wide range of structural and functional techniques now exists to map the human brain in health and disease. These approaches span the gamut from external tomographic imaging devices (positron-emission tomography, single photon-emission computed tomography, magnetic resonance imaging, computed tomography), to surface detectors (electroencephalography, magnetoencephalography, transcranial magnetic stimulation), to measurements made directly on the brain''s surface or beneath it (intrinsic signal imaging, electrocorticography). The noninvasive methods have been combined to provide unique and previously unavailable insights into the macroscopic organization of the functional neuroanatomy of human vision, sensation, hearing, movement, language, learning, and memory. All methods have been applied to patients with neurologic, neurosurgical, and psychiatric disease and have provided a rapidly expanding knowledge of the pathophysiology of diseases such as epilepsy, cerebrovascular disease, neoplasms, neurodegenerative diseases, mental illness, and addiction states. In addition, these new methods have become a mainstay of preoperative surgical planning and the monitoring of pharmacologic or surgical (transplantation) interventions. Most recently, the ability to observe the reorganization of the human nervous system after acute injury, such as occurs with cerebral infarction or head trauma, or in the course of a progressive degenerative process such as Alzheimer''s or Parkinson''s disease, may provide new insights and methods in the rapidly expanding field of neurorehabilitation. Our newfound ability to generate maps and databases of human brain development, maturation, skill acquisition, aging, and disease states is both an exciting and formidable task.     

In vivo imaging of the brain cannabinoid receptor

The CB1 cannabinoid receptor is expressed in the brain at levels sufficient to serve as potential target for in vivo imaging using positron emission tomography (PET) or single photon emission computed tomography methodology. To date, the most promising radioligands for the in vivo imaging of this receptor have structures based on that of the cannabinoid antagonist, SR141716A. Rodent data obtained using these in vivo radiotracers has demonstrated that both the behavioral and neurochemical effects of cannabinoids occur at very low levels of receptor occupancy. More recently, an agonist radiotracer based on the structure of aminoalkylindole cannabinoids has also been examined for in vivo labeling of CB1 receptors. Although rodent studies have indicated that in vivo imaging of CB1 receptors is feasible, at the present time this receptor has still to be successful imaged in a human PET study.     

VI. The concurrent estimation of the major monoamine metabolites in human and non-human primate brain by HPLC with fluorescence and electrochemical detection

A simple and sensitive method for the concurrent determination of the monoamine metabolites MHPG, DOPAC, HVA and 5HIAA in brain samples is described. After solvent extraction at acid pH, the metabolites are separated by HPLC on a C₁₈ reversed phase column using phosphate buffers. Detection and quantification are achieved using fluorescence and electrochemical detection in series. The method is applied to control samples of divers areas of human and non-human primate brain, and the distribution of results agrees well with those obtained by existing methods. The concentrations found also agreed well with literature values, and, for 5HIAA and DOPAC, with results obtained on parallel samples analysed by fluorimetry and by GC. Results for HVA however are higher than those obtained by GC, but agree well with literature values obtained by fluorimetry and by GCMS.     

In vivo acetylation of homocholine and beta-methylcholine in rat brain

A nitrogen phosphorus-gas chromatographic procedure was modified to determine the extent of in vivo acetylation of the choline analogs homocholine and beta-methylcholine. Infusion of homocholine (18 mumoles) for 2 hours into the lateral ventricle of the rat produced 2.3 nmoles/gram of acetylhomocholine which represented 0.035% of the detected homocholine. Infusion of the same quantity of beta-methylcholine produced 1.0 nmole/gram of acetyl-beta-methylcholine representing 0.025% of the detected beta-methylcholine. Although pretreatment with hemicholinium-3 reduced the amount of acetylated product formed from either analog, the reduction was significant only for acetyl-beta-methylcholine (p less than 0.01).     

In vivo recording of adult zebrafish electrocardiogram and assessment of drug-induced QT prolongation

In the last decade the zebrafish has become a major model organism for the study of development and organogenesis. To maximize the experimental utility of this organism, it will be important to establish methods for adult phenotyping. We previously proposed that the embryonic zebrafish may be useful in high-throughput screening for drug-induced cardiotoxicity. We now describe a method for the reproducible recording of the adult zebrafish ECG and illustrate its application in the investigation of QT-prolonging drugs. Zebrafish ECGs were obtained by inserting two needle electrodes through the ventral epidermis. Fish were perfused orally, and motion artifacts were eliminated with a paralytic dose of mu-conotoxin GIIIB. Test compounds were delivered via the perfusion system. Without a means of hydration and oxygenation, the fish succumb rapidly. The use of a perfusion system allowed stable recording for > 6 h. Baseline conduction intervals were as follows: PR, 66 ms (SD 14); QRS, 34 ms (SD 11); QT, 242 ms (SD 54); and R-R, 398 ms (SD 77). The known QT-prolonging agents astemizole, haloperidol, pimozide, and terfenadine caused corrected QT increases of 18% (SD 9), 16% (SD 11), 17% (SD 9), and 11% (SD 6), respectively. The control drugs clonidine, penicillin and propranolol did not prolong the corrected QT interval. In conclusion, perfusion and muscular paralysis allows stable, low-noise recording of zebrafish ECGs. Agents known to cause QT prolongation in humans caused QT prolongation in fish in each case. The development of rigorous tools for the phenotyping of adult zebrafish will complement the high-throughput assays currently under development for embryonic and larval fish.