Neuro-Stimulus Chip with Photodiodes Array for Sub-retinal Implants

A prototype neuro-stimulus chip for sub-retinal implants in blind patients affected by Age-related Macular Degeneration (AMD) or Retinitis Pigmentosa (RP) is presented in this paper. This retinal prosthetic chip was designed to replace the degenerated photoreceptor cells, and in order to stimulate directly the remaining healthy layers of retinal neurons. The current stimulus circuits are monolithic integrated with photodiodes (PD) array, which can convert the illumination on the eyes into bi-phasic electrical pulses. In addition, a novel charge cancellation circuit is used to discharge the electrodes for medical safty. The prototype chip is designed and fabricated in HJTC 0.18 mu m N-well CMOS 1P6M Mix-signal process, with a +/- 2.5 V dual voltage power supply.

Peptidomics and genomics analysis of novel antimicrobial peptides from the frog, Rana nigrovittata

Much attention has been paid on amphibian peptides for their wide-ranging pharmacological properties, clinical potential, and gene-encoded origin. More than 300 antimicrobial peptides (AMPs) from amphibians have been studied. Peptidomics and genomics analysis combined with functional test including microorganism killing, histamine-releasing, and mast cell degranulation was used to investigate antimicrobial peptide diversity. Thirty-four novel AMPs from skin secretions of Rana nigrovittata were identified in current work, and they belong to 9 families, including 6 novel families. Other three families are classified into rugosin, gaegurin, and temporin family of amphibian AMP, respectively. These AMPs share highly conserved preproregions including signal peptides and spacer acidic peptides, while greatly diversified on mature peptides structures. In this work, peptidomics combined with genomics analysis was confirmed to be an effective way to identify amphibian AMPs, especially novel families. Some AMPs reported here will provide leading molecules for designing novel antimicrobial agents. (C) 2009 Elsevier Inc. All rights reserved

氟代柠檬酸对体外培养的神经胶质瘤细胞G422增殖的抑制效应

为研究氟代柠檬酸(Fluorocitrate)对体外培养的神经胶质瘤细胞生长的影响,采用MTT法研究不同的氟代柠檬酸浓度(0.0025mmol/L,0.005mmol/L,0.01 mmol/L,0.025mmol/L和0.1 mmol/L)和作用时间(36h,48h和60h)对神经胶质瘤细胞G422增殖的影响.结果发现:(1)氟代柠檬酸可抑制G422细胞的增殖,并且其抑制作用随氟代柠檬睃浓度的增加而增强;(2)高浓度(0.01 mmol/L,0.025 mmol/L和0.1 mmol/L)氟代柠檬酸对G422细胞的增殖抑制作用随作用时问的延长而增强:(3)低浓度(0.0025mmol/L和0.005mmol/L)氟代柠檬酸对G422细胞的增殖抑制作用不随作用时间的延长而改变.实验表明,氟代柠檬酸能够抑制神经胶质瘤细胞的增殖,其抑制能力随氟代柠檬酸浓度的增加和作用时间的延长而加强.

Delta EEG Activity in Left Orbitofrontal Cortex in Rats Related to Food Reward and Craving

眶额叶皮质与中脑边缘多巴胺奖赏系统有着复杂的相互纤维联系.先前的研究探讨了药物成瘾过程中眶额叶皮质的脑电活动.在本实验中,将探讨食物奖赏和渴求过程中该皮质的脑电活动.实验采用了两个环境:对照环境和食物刺激相关的环境.首先,训练大鼠在食物刺激相关的环境中吃巧克力花生豆,而后在该环境中设置两种不同的刺激方式:能看到和闻到但不能吃到(渴求实验),或者仍旧可以吃到巧克力花生豆(奖赏实验):同时进行左侧眶额叶皮质的脑电记录.结果发现,在食物刺激相关的环境中大鼠Delta频段(2-4Hz)的脑电活动与食物刺激显著相关,此外,与在对照环境中相比,其相对功率在食物渴求时下降而在食物奖赏时升高.本实验表明,食物相关的奖励可以改变大鼠眶额叶皮质的脑电活动,而且,Delta频段的脑电活动能够作为监测该奖励的一个指标.

Morphine and propranolol co-administration impair consolidation of Y-maze spatial recognition memory

In the present study, the interaction between morphine and the beta-adrenergic receptor antagonist, propranolol (PROP), in memory consolidation was investigated in a two-trial recognition Y-maze task. Four sets of Y-maze experiments were carried out in mi

Distracters Impair and Create Working Memory-Related Neuronal Activity in the Prefrontal Cortex

The prefrontal cortex (PFC) has a central role in working memory (WM). Resistance to distraction is considered a fundamental feature of WM and PFC neuronal activity. However, although unexpected stimuli often disrupt our work, little is known about the un

Pentylenetetrazole-induced status epilepticus following training does not impair expression of morphine-induced conditioned place preference

Learning and memory play an important role in morphine addiction. Status epilepticus (SE) can impair the spatial and emotional learning and memory. However, little is known about the effects of SE on morphine-induced conditioned place preference (CPP). Th

钠离子通道类毒素的细胞毒性和检测方法的研究

赤潮毒素广泛存在于各种赤潮藻和各类海洋生物中，不仅对渔业、养殖业危害甚大，而且还直接威胁着人类的生存健康。其中，离子通道类毒素是一类毒性较高的毒素。除一些赤潮藻可以产生此类毒素之外，海洋中还存在某些生物也能够产生离子通道类毒素。为进一步阐明钠离子通道类毒素对细胞的毒性效应机制，本文选取一株小鼠神经母细胞瘤（Neuro-2a）作为受试对象，研究了四种钠离子通道类毒素STX、GTX1,4、GTX2,3、TTX对Neuro-2a细胞的毒性影响机制，并利用STX和TTX，建立了钠离子通道类毒素的细胞毒性检测方法，且应用此方法检测了贝体内、藻体内的毒素含量，进一步与小鼠法和HPLC法进行了比较。 研究表明：STX、GTX1,4、GTX2,3、TTX四种钠离子通道类毒素在长时间内均会对Neuro-2a细胞的增殖产生不利影响。在短时间（24h）内，以上各毒素均没有抑制Neuro-2a细胞的增殖，但是48h后，以上各毒素对Neuro-2a细胞的增殖均产生了抑制作用，且随着各毒素剂量的增加，细胞增殖受抑制程度也表现出一定程度的增高，二者呈剂量-反应关系。STX、GTX1,4、GTX2,3、TTX对Neuro-2a细胞的48h半数抑制浓度（IC50）分别为：250ng/ml、1000ng/ml、1300ng/ml、700ng/ml。本论文还首次研究了STX、GTX1,4、GTX2,3、TTX四种钠离子通道类毒素对Neuro-2a细胞内酶活性的影响。研究发现，STX、GTX1,4、GTX2,3、TTX四种钠离子通道阻断剂类毒素均能够影响Neuro-2a细胞内Na+-K+-ATP酶和乙酰胆碱酯酶TChE的活性。当各毒素作用24h后，Neuro-2a细胞内Na+-K+-ATP酶和乙酰胆碱酯酶TChE的活力均会受到抑制，并且随着各毒素剂量的增加，两种酶的活性也逐渐降低。可见，钠离子通道阻断剂类毒素能对细胞内酶的功能产生一定的影响，此影响连同阻断细胞膜钠离子通道，造成离子流的失衡作用，进一步对细胞产生毒性效应。在对细胞膜通透性的研究中发现，上述四种钠离子通道阻断剂类毒素各剂量组细胞培养液乳酸脱氢酶LDH的漏出率与对照组相比均无显著差异，它们均未引起Neuro-2a细胞膜内LDH的改变，看来钠离子通道阻断剂类毒素不会通过影响细胞膜的通透性而对细胞引起毒性效应。 本研究还利用STX和TTX两种钠离子通道标准毒素以及乌苯苷、藜芦定两种生物毒素，参照Jellett（1992）方法，建立了STX和TTX两种钠离子通道类毒素的细胞毒性检测的标准曲线，分别为：Y=0.266X+51.184和 Y=1.6068X+47.186。检出限分别为5ng/ml和0.8ng/ml。并且利用已建立的细胞毒性检测方法检测了来自浙江舟山和连云港赣榆市的19个织纹螺样品和5株实验室培养的亚历山大藻，得到的实验结果与小鼠生物测试和HPLC检测的结果存在较好的相关关系。鉴于该方法具有高通量、省时、检出限低等优点，因此更具有在沿海环境检测中推广应用的潜力。

DSP等赤潮藻毒素对哺乳类细胞的毒性效应及机制研究

本文研究了腹泻性贝毒的主要组分大田软海绵酸以及几株重要赤潮藻的提取物对四株哺乳类细胞的毒性效应，并探讨了应用细胞毒性检测方法作为赤潮藻毒素毒性检测常规方法的可能性。 结果发现：OA和利玛原甲藻提取物显著地抑制四株细胞的增殖并诱导四株细胞发生凋亡；四株细胞对毒素的敏感性存在一定的差异，人肝癌细胞和小鼠神经瘤细胞较敏感，其次分别为人肝细胞和小鼠皮肤细胞。 小鼠神经瘤细胞对OA反应敏感，细胞毒性检测指标及检测方法灵敏、快速，应用小鼠神经瘤细胞Neuro-2a进行的DSP毒素细胞毒性测试方法具有发展为该类毒素毒性监测常规方法的潜能。 米氏凯伦藻内存在抑制细胞增殖的毒性物质，且该物质是一种具有一定极性的脂溶性物质；该物质能够导致细胞肿胀、破裂，并诱导细胞发生脂质过氧化，导致脂质过氧化产物丙二醛(MDA)的积累。 相关亚历山大藻的去藻过滤液内存在抑制细胞增殖和诱导细胞凋亡的毒性物质，该毒性物质的分子量＞5K，这与本实验室以往的研究结果一致。 　　总之，通过我们的研究发现：DSP等赤潮藻毒素或毒性物质对哺乳类细胞存在毒性影响，且不同毒素的危害机制存在差异，赤潮藻毒素或赤潮藻产生的一些毒性物质威胁人类的健康，应引起我们的高度关注。

去甲肾上腺素刺激高原鼠兔CRF的分泌

We studied the effect of neuro transmitter no repin ephrine (N E) on immuno reactive cortico trop inreleasing factor (CRF) of median eminence (M E) in the native pika (Ochotona cu rz oniae). At one hour after intra cerebrovent ricular ( icv) adm inistrat ion of N E in doses of 3.75,7.5, 15 and 30 μg/100 g BW , the CRF level ofM E increased. And the plasma cortico sterone concent rat ion also increased. Two and six days after adrenalectomy (ADX) , N E concent ration in hypothalamus declined to 76.32% and 76.27% of those in intact pika, plasma cortico rsterone concent ration also decreased to 16.57 and 2.05% of the control. These results indicated that N E have a effect on activating HPA axis through activating hypothalamic CRF in Ochotona curzoniae.

去甲肾上腺素参与吗啡神经适应性改变的中枢机制

That relapse still exists even after prolonged withdrawal is a difficult issue in the medical cure of drug addiction. Neuro-adaptation induced by prolonged exposure to addictive drugs is the neural mechanisms of both compulsive drug seeking and relapse.Neuro-adaptation caused by addictive drugs increases the individuals’ response to drugs and on the other hand, it reduces the response to natural reward in withdrawn individuals.There must be common neural mechanisms between the co-existing phenomena, and there must also be unique neural mechanisms in the drugs.To reveal the neuro-adaptation arising in the process from random, controllable drug-use to uncontrollable compulsive drug seeking is of great significance both theoretically and practically.Based on the above hypothesis, in order to reveal the function of alpha adrenergic receptor in compulsive drug-seeking motivation during the process of drug addiction, using sensitization of morphine-induced psychomotor activity as behavioral model, through the method of behavioral pharmacology, the neural mechanisms of alpha adrenergic receptor’s involvement in the process of addiction has been studied.The adjustment function caused by alpha receptors in medial prefrontal cortex and nucleus accumbens to morphine-induced psychomotor activity has been compared in the period of first use of drugs and in repetitive-use period. Furthermore, the effect on novelty seeking caused by alpha-receptors in relevant brain areas has also been compared. Major results are as follow: 1 After prolonged morphine exposure, rats’ response to morphine-induced psychomotor activity is strengthened and response to novel object induced reward weakened. 2 Injection of prazosin in medial prefrontal cortex will block morphine-induced psychomotor activity of naïve rats, however, it will not block that of morphine-withdrawn rats, but it will block the novelty seeking behavior of morphine-withdrawn rats. 3 Injection of clonidine in medial prefrontal cortex will block morphine-induced psychomotor effect of both naïve rats and morphine-withdrawn rats, and will block the novelty seeking behavior of morphine-withdrawn rats. 4 Injection of prazosin in nucleus accumbens will not affect the morphine-induced psychomotor effect of either naïve rats or morphine-withdrawn rats, nor will it affect the novelty seeking behavior of morphine-withdrawn rats. 5 Injection of clonidine in nucleus accumbens will block morphine-induced psychomotor effect of naïve rats, however, it will not block that of morphine-withdrawn rats, nor will it affect the novelty seeking behavior of morphine-withdrawn rats. These results show: 1 The weakening of the function of alpha1 receptors in medial prefrontal cortex and alpha2 receptors in nucleus accumbens caused by repetitive exposure to morphine is probably the cause of compulsive drug-seeking activity. 2 Blocking alpha1 receptors in medial prefrontal cortex accelerates the loss of interest in natural reward after morphine withdrawal. 3 Blocking alpha2 receptors in medial prefrontal cortex not only restrains drug-seeking motivation, but also blocks the individual’s seeking motivation for novelty stimulus, which suggests that, while selecting medicine for curing addiction, it should be considered to reduce the influence on natural reward as much as possible and to avoid major side-effect.

慢性海洛因成瘾者的冲动性和行为抑制缺陷脑机制

In recent years, the deficit of inhibition has become an important reason for explaining addiction. Response inhibition resembles the compulsive drug seeking behavior and it is the basement of addiction inhibition deficits. However, there were no enough evidence for the relationship between addiction and response inhibition deficits and the results of the neuro mechanisms studies remains unclear. Few studies has focused on the exploring the heroin users. Among those paradigms for study response inhibition deficits, stop signal is a very suitable model for the representation of compulsive drug seeking, but only a few researches has worked on this paradigm. In this study, we selected about 100 heroin abusers and had behaviour and neuro imaging scannings for investigating the response inhibition deficits. The behaviour researches found: first, the chronic heroin users had longer reaction time than control group and this reaction time were not affected by stop signals in heroin users. Second, heroin users had less waiting time than control group and they were more impulsive but less flexibility. Their erro monitoring and flexibale adjustment ability decreased. Third, the SSRT of heroin users was significantly longer than control group. These results suggested that the inhibition of heroin users were impaired. Further investigation showed that the SSRT of heroin users had positive correlation of four factor scores of ASI and the macro correlation coefficient was factor three of drug use. This correlation suggested that drug use was the main reason of inhibition deficits. fMRI results mainly focused on the ANOVA analysis for group difference. First, there was no intensity difference in M1 and SMA brain areas between the two groups. Second, heroin users had less activation in right dorsalateral prefrontal cortex, right inferior prefrontal cortex and anterior cingulated cortex, while in bilateral striatum and amygdala, heroin users had more activation than control group. The right prefrontal cortex was indentified as the main inhibition brain area. The anterior cingulated cortex has relationship with erro monitoring and amygdale was an important brain area for impulsivity and emotion control. The network of these brain areas was envovled in impulsivity and inhibition and it was suggested the mainly damaged network for heroin users’ disinhibition. We also investigated the gray matter changes of heroin users and found that chonic heroin use made their gray matter density decreased in prefrontal cortex (including bilateral dorsalateral prefrontal cortex, obital frontal cortex, inferior prefrontal cortex) and anterior cingulated cortex. The gray matter density in these brain regions had negative correlation with drug use duration. In conclusion, we indentified the disinhibition of heroin users and its neuro mechanism. Their compulsivity brain areas had more activation than control group and their inhibition brain areas had less activation than normal control. On the other side, the biological mechanism of this activation changes was the gray matter density decrease in these brain areas.