去甲肾上腺素对猕猴额叶延缓辨别作业相关神经元活动的效应

为了研究去甲肾上腺素在大脑认知功能中的作用,在3只猕猴进行延缓辨别作业的同时,在额叶弓状沟上支内侧部的皮层区,记录了230个作业相关神经元的电活动。对其中159个神经元观察了微量电泳去甲肾上腺素、妥拉苏林或心得安的效应。这些神经元在作业各期的分布是:开始期11个,暗示期28个,延缓期66个,反应期54个。约2/3的神经元在作业中出现兴奋反应(放电增多),1/3为抑制反应(放电减少)。在延缓期出现抑制反应的神经元,绝大多数对去甲肾上腺素敏感。在电泳去甲肾上腺素时,神经元的自发放电减少,延缓期的抑制加深。电泳妥拉苏林或心得安则出现相反的效应,即自发放电增多,延缓期的抑制减弱或不出现抑制,并可拮抗电泳去甲肾上腺素的抑制效应。实验结果提示,在额叶弓状沟上支内侧皮层神经元的注意、短时记忆等认知功能中,可能有去甲肾上腺素参与作用,主要参与神经活动的抑制过程。     

猕猴额叶神经元视辨别机能可塑性的研究

我们曾经提出,额叶神经元的反应,主要不是取决于刺激物的物理属性,而是与信号意义有密切的关系。为了验证这一看法,设计了两套作业,即视延缓辨别作业(作业Ⅰ)和视辨别反应作业(作业Ⅰ),对4只成年猕猴进行实验。两套作业都由1—4期组成,在第2期都有伪随机出现的红绿灯光信号,在第3期都要求动物密切注意随后的灯光信号变化。但是,作业Ⅰ要求动物对第2期出现的红绿灯光进行辨别,作业Ⅰ则要求对第4期的红绿灯光进行辨别。待动物学会作业,正确率达90％以上,在动物进行作业的同时引导额叶神经元放电。共记录作业相关神经元163个。其中作业Ⅰ98个,作业Ⅱ 65个。在作业Ⅰ中,神经元的反应多数出现在第2、3期,占该作业反应总数的70％。而在作业Ⅱ中,反应多数出现在第3、4期,也占该作业反应总数的70％。其次,作业Ⅰ第2期的神经元反应绝大多数对红、绿灯光有明显的特异性,而作业Ⅱ第2期的则没有,只有第4期的反应才有明显的特异性。本实验结果进一步支持了我们的上述看法,并且表明,额叶神经元对信号的反应主要是在学习中逐渐形成的,有很大的可塑性。     

猕猴执行痛、热延缓辨别作业时额叶神经元及肌电活动的观察

为研究额叶神经元对躯体痛、热刺激出现反应的机能意义,设计了痛、热延缓辨别作业对猕猴进行实验。痛和热仅在暗示期给予,要求动物对此不立即作出行为反应。而是暂时记住这个信号,等到行动期再作出反应。待作业正确率连续三天达90%以上,记录额叶神经元和两侧上肢肌肉的电活动.以观察神经元活动与信号刺激以及肌肉活动之间的关系。在记录的142个作业相关神经元中,与痛、热刺激相关者87个(66.4%)。其中22个仅对痛刺激、18个仅对热刺激起反应,47个对痛、热刺激都起反应(其中4个反应方向相反)。此外,有21个对痛、热、视都出现反应。其余仅对视觉刺激起反应。这些神经元主要位于额叶弓状沟上支内侧,包括前额叶和运动前区皮层。在两侧上肢12块肌肉中,除操作侧指总伸肌、尺侧腕屈肌和桡侧腕屈肌在压放杠杆时,可记录到短暂的肌电活动外,在作业的其它时期和其它肌肉均未记录到规律的肌电活动。这表明痛热刺激在暗示期引起的神经元反应与行为动作的发动没有直接关系,从而支持关于额叶皮层这一区域的神经元在对刺激物信号意义的辨别机制中,可能起着重要作用的假说。     

猕猴前额叶皮层神经元在视觉延缓分辨活动中的放电活动

在已学会颜色延缓分辨的3只猕猴上,用钨丝微电极记录前额叶背外侧部皮层神经元的放电活动,着重分析神经元放电活动与颜色延缓分辨活动的各个时期之间的相互关系。延缓分辨任务开始时,同时把红色光和绿色光分别投射在测试板上的两个显示窗上,约持续1.2s(暗示期)。颜色光熄灭后2—4s(此为延缓期),各自位于每一显示窗下的两个反应键同时向猴方推出。自此,反应期开始,动物应马上有选择地作出按键反应。如果动物作出正确选择按红色光下的反应键,则给少量桔子汁作奖励。共记录了155个前额皮层单位。其中40个单位的放电频率在动物完成视觉延缓分辨作业过程中没有明显变化,另外115个单位与该任务的某些时期有关。大多数单位(n=99)在反应键推出时,或者在按反应键的前后有放电频率变化。这99个单位中,15个在暗示期和反应期内放电活动有变化(CR 型单位),13个在延缓期和反应期内放电活动有变化(DR 型单位),42个只在反应期内或反应期后放电频率出现变化(R 型单位),其余29个单位则在分辨任务的各个时期都显示出放电活动变化(CDR 型单位)。上述这些单位中,有少数单位在动物作出正确反应时的放电型式与动物作出错误反应时的放电型式有明显不同。此外,即使动物对任务测试不作出按键反应时,也观察到16个单位的放电活动在任     

清醒猕猴前额叶和运动前区神经元多感觉活动的观察

本实验对清醒猕猴前额叶和运动前区神经元多感觉活动进行了观察。在动物进行课题操作中记录单神经元放电。课题中包括视、痛、热三种感觉刺激。在所记录的338个课题相关神经元中,对一种感觉刺激呈现反应者156个,对两种刺激反应者94个,对三种刺激都反应者88个。为了观察不具有信号意义的感觉刺激的作用,在课题操作的间歇期给动物以痛、热、视、听、触等自然刺激。在测试的176个课题相关神经元中,仅72个神经元对自然刺激呈现反应。其中对一种感觉刺激反应者45个,对两种刺激反应者19个,三种者5个,四种者3个。多数神经元对痛(N=33),视(N=30)和热(N=29)刺激呈现反应,仅有3个神经元对声音,9个神经元对触刺激出现反应。绝大多数神经元位于弓状沟上支内侧的颗粒和无颗粒皮层内。本实验表明,痛、热、触、视、听觉等投射到额叶皮层的相同部位,不同程度地会聚到同一神经元上。有信号意义的刺激与没有信号意义的刺激相比,前者可激活更多的神经元。     

猕猴前额皮层神经元对信号刺激和无关刺激反应的比较研究

在两只已建立视觉分辨行为以及一只未经训练的猕猴上记录了前额皮层主沟区的单位放电,视觉分辨作业包括下列事件;（1）暗示信号红光（在R模式中）或蓝光（在B模式中）（1.30^s);(2）延缓期（2.10s);（3）反应期出现白光（1.88s)在R模式中动物必需在白光出现后立即拉杆以避免电击在B模式中不给予电击,要求动物不拉杆,共记录了127个前额皮层单位,其中80个单位的放电变化与视觉分辨作业的事件相关,占总数的63%,在测试间歇期内观察了前额皮尾神经元对无关的短声\闪光以及闪烁的红、蓝和白光的反应,总共对96个单位进行了短声和/或闪光刺激的测试,其中23个（24%）对上述刺激产生反应,并大部分（15个）是与行为作业中事件相关的单位,在对103个单位进行闪烁的红、蓝、白光测试中,发现只有12个（12%）单位有反应,在另一只未经训练的猕猴的前额皮层主沟区记录了100个单位,发现只有4个（4%）单位对无关的光刺激有反应,这些光刺激的物理性与上述实验中所采用的刺激相同,以上结果表明,通过学习具有行为意义的刺激能引起更多的前额叶神经元的放电活动,也就是说前额叶神经元对具有行为意义的刺激的反应是在学习过程中形成的,它们的活动是可塑的。     

在延缓分辨作业的学习过程中猕猴大脑皮层慢电位的变化

本工作在两只猕猴上记录了在延缓分辨作业不同训练阶段的皮层慢电位变化,分辨作业模型与前文报道的相同^[1],延缓分辨行为建立后,在额奁的许多部位都能记录到负的慢电位变化,这种慢电位变化出现在延缓期,其幅度随动物行为正确率的提高而增大,这种慢电位在前额区具有最大幅度,在中央沟以后的区域则未能记录到,负慢电位在左右两侧半球的分布基本对称,其幅度大小亦无显著差别,在延缓分辨行为反应消退后,负慢电位也随之消失,在延缓分辨作业的两种测试模式,即给予电南的R模式及不给予电击的B模式上,负慢电位均出现在延缓期,在时程和幅度上未表现出模式特异性。以上结果提示,本实验中记录到的负慢电位是依赖于学习过程的,它反映了事件间条件性联系的建立,这一负慢电位在前额皮层具有最大的幅值,并出现在延缓期的实验结果支持了前额皮层在短时记忆过程中起着重要作用的论点。     

情前期与间情期大鼠内侧视前区-下丘脑前区神经元的电活动

在氯化筒箭毒制动的情前期及间情期大鼠上进行实验。用玻璃微电极记录内侧视前区-下丘脑前区(mPOA-AHA)的单位放电。mPOA-AHA 的大多数单位表现连续性或周期性自发放电。情前期大鼠周期性放电单位所占的百分比显著地多于间情期大鼠(P<0.01)。刺激子宫颈部可以使单位放电发生两种反应。一种单位对宫颈刺激发生放电频率增加的反应(宫颈兴奋神经元,CE 神经元),另一种单位则发生放电频率降低的反应(宫颈抑制神经元,CI神经元)。情前期大鼠 CE 与 CI 神经元所占的百分比与间情期大鼠没有明显的差异(P>0.05)。但情前期大鼠的 CE和 CI 神经元多呈现周期性放电,而间情期大鼠的 CE 和 CI 神经元则多呈现连续性放电。这说明 mPOA-AHA 神经元的电活动随生殖周期发生明显的变化。脑室注射去甲肾上腺素(NE)能使 mPOA-AHA 内大多数 CE 神经元对宫颈刺激的兴奋反应暂时受到抑制,而注射 NE 却使大多数 CI 神经元发生抑制解除。这些结果提示 NE 可能有抑制 CE 神经元和刺激 CI 神经元的作用。     

恒河猴,懒猴和树Qu的短时空间记忆功能与前额叶背侧部进化水平的相关性

本文研究探讨了进化地位不同的三种动物的短时空间记忆功能及其与前额叶背侧部进化水平的相关性。结果表明,在延缓反应作业中,经1000次训练后,7只恒河猴对空间位置的记忆时间平均为7.7±3.2 min,懒猴为3.8±0.44 min,而树qu即使在延缓时间几乎为零秒的延缓反应中,其正确反应率也未达到90%标准。一种延缓时间仅测试一个单元,即不经训练的实验表明,恒河猴在延缓期为“0”-5 min的各测试单元中,正确反应率稳定在80%以上;懒猴在延缓时间为“0”-4 min的各测试单元中,平均正确反应率与恒河猴无明显差异,而当延缓时间增加到5 min时,在延缓反应作业中取得的成绩显著下降;树qu在延缓时间为1-5 min的作业中取得的正确反应率在70%以下。3种动物在视觉辨别学习作业中却无明显差异。形态学研究表明,灵长类大脑前额叶的面积和结构的复杂性在进化过程中逐渐增大,如恒河猴大脑前额叶的表面积占大脑半球表面积的11.5%（Brodmann,1929）,其内颗粒层发达,背侧部明显凸起,主沟区发达;懒猴的前额叶表面积占其大脑半球表面积的8.3%,背侧部凸起不显著,主沟未形成,额极内颗粒层分化明显,背侧部的内颗粒层较内侧部的发达程度差（Sanides,1967）;树qu的前额叶表面积占7.5%,额极的内颗粒层分化不明显,为非颗粒化区,此区之后为颗粒区和运动前区,颗粒区背侧部的发育程度明显较内侧部差。恒河猴前额叶损伤研究结果表明,短时空间记忆功能依赖前额叶背侧部的完整性。本研究提示,短时空间记忆功能的发达程度与大脑前额叶背侧部的进化程度有相关性。     

恒河猴、懒猴和树鼩的短时空间记忆功能与前额叶背侧部进化水平的相关性(英文)

本文研究探讨了进化地位不同的三种动物的短时空间记忆功能及其与前额叶背侧部进化水平的相关性。结果表明,在延缓反应作业中,经1000次训练后,7只恒河猴对空间位置的记忆时间平均为7.7±3.2min,懒猴为3.8±0.44min,而树鼩即使在延缓时间几乎为零秒的延缓反应中,其正确反应率也未达到90％标准。一种延缓时间仅测试一个单元,即不经训练的实验表明,恒河猴在延缓期为“0”—5min的各测试单元中,正确反应率稳定在80％以上;懒猴在延缓时间为“0”—4min的各测试单元中,平均正确反应率与恒河猴无明显差异,而当延缓时间增加到5min时,在延缓反应作业中取得的成绩显著下降;树鼩在延缓时间为1—5min的作业中取得的正确反应率在70％以下。3种动物在视觉辨别学习作业中却无明显差异。形态学研究表明,灵长类大脑前额叶的面积和结构的复杂性在进化过程中逐渐增大,如恒河猴大脑前额叶的表面积占大脑半球表面积的11.5％(Brodmann,1929),其内颗粒层发达,背侧部明显凸起,主沟区发达;懒猴的前额叶表面积占其大脑半球表面积的8.3％,背侧部凸起不显著,主沟未形成,额极内颗粒层分化明显,背侧部的内颗粒层较内侧部的发达程度差(Sanides,1967);树鼩的前额叶表面积占7.5％,额极的内颗粒层分化不明显,为非颗粒化区,此区之后为颗粒区     

猕猴执行痛,热延缓辨别作业时额叶神经元及肌电...

To study the functional implication of neuronal responses in frontal cortex to noxious and innocuous heat stimuli, experiments were carried out on two monkeys (Macaca mulatta) during performing a delayed discrimination GO/NO-GO task. The animals were trained to hold a lever for at least 3 s in the response period when an innocuous heat stimulus had been applied to the forearm in the cue period, or release it within 1 s with a noxious one. After a criterion of 90% of correct responses in 3 successive days was reached, single neuronal activity was recorded from the frontal cortex along with EMGs from six muscles in both arms. Of 142 task-related neurons recorded, 87 (66.4%) were related to heat, 34 to visual, and 21 to both visual and heat stimuli. Among the heat-related neurons, 22 were responsive to noxious heat, 18 to innocuous heat, and 47 to both. Of the neurons responding to both noxious and innocuous heat stimuli, 4 neurons showed changes in discharge rates, depending on the type of stimuli. In most cases, muscular activities just appeared at the moment of lever pressing and/or releasing in m. extensor digitorium communis, m. flexor carpi ulnaris and m. flexor carpi radialis of the performing arm. No regular muscular activities appeared in other muscles and in other periods of the task. The result showed that the neuronal responses in frontal cortex elicited by heat stimuli in the cue period were not related directly to the initiation and modulation of behaviours.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ensemble activity of neurons in the visual, frontal, and sensorimotor cortices and dorsal striatum during actualization of behavioral program under conditions of strategy choice

Unit and network activity of neurons in the visual, sensorimotor, and frontal cortical areas and dorsal striatum was investigated in cats under conditions of choice of the reinforcement value depending on its delay. The animals did not differ from each other in behavior. After immediate or delayed responses cats got low- or highly-valuable reinforcement, respectively. Single-unit activity in the visual and sensorimotor cortical areas and dorsal striatum was similar during performance of immediate and delayed responses. However, significant inhibition was observed in the frontal neurons during the delay period. The network activity of visual and frontal cortex displayed smaller number of interneuronal interactions during delayed responses as compared to immediate reactions. The network activity of neurons in the brain structures under study pointed to the interstructural interaction, but only during delayed reactions, steady interneuronal communication was observed between the frontal cortex and dorsal striatum. Thus, both types of estimation of cellular activity revealed differences in the ensemble organization during different types of behavior and showed specific reactions of neuronal ensembles.     

去甲肾上腺素对猕猴额叶延缓辨别作业相关神经元活动...

To study the role of norepinephrine (NE) in the cognitive function of the brain, the effects of NE, tolazoline (TOL) and propranolol (PR) on the activity of frontal neurons were examined in 3 rhesus monkeys (Macaca mulatta) during the performance of a delayed visual discrimination go/no-go task. Of the 230 task-related neurons recorded from the area medial to the superior ramus of the arcuate sulcus, 159 neurons were tested with NE applied microiontophoretically. Of these tested neurons, 11 neurons were related to starting period, 28 neurons to cue period, 66 neurons to delay period and 54 neurons to response period. About 2/3 of these neurons increased in discharge rate in the task, and the rest decreased. For most of the neurons with decrease of discharge rate in the delay period, the discharge rate was further decreased during application of NE. During application of TOL or PR, the discharge rate was increased and the effect of NE was antagonized. The present results suggest that NE may play a role in the cognitive function of the frontal neurons, particularly in attention and short-term memory, and may be involved in the inhibitory process of the neuronal activities.     

Different neuroplasticity for task targets and distractors

Adult learning-induced sensory cortex plasticity results in enhanced action potential rates in neurons that have the most relevant information for the task, or those that respond strongly to one sensory stimulus but weakly to its comparison stimulus. Current theories suggest this plasticity is caused when target stimulus evoked activity is enhanced by reward signals from neuromodulatory nuclei. Prior work has found evidence suggestive of nonselective enhancement of neural responses, and suppression of responses to task distractors, but the differences in these effects between detection and discrimination have not been directly tested. Using cortical implants, we defined physiological responses in macaque somatosensory cortex during serial, matched, detection and discrimination tasks. Nonselective increases in neural responsiveness were observed during detection learning. Suppression of responses to task distractors was observed during discrimination learning, and this suppression was specific to cortical locations that sampled responses to the task distractor before learning. Changes in receptive field size were measured as the area of skin that had a significant response to a constant magnitude stimulus, and these areal changes paralleled changes in responsiveness. From before detection learning until after discrimination learning, the enduring changes were selective suppression of cortical locations responsive to task distractors, and nonselective enhancement of responsiveness at cortical locations selective for target and control skin sites. A comparison of observations in prior studies with the observed plasticity effects suggests that the non-selective response enhancement and selective suppression suffice to explain known plasticity phenomena in simple spatial tasks. This work suggests that differential responsiveness to task targets and distractors in primary sensory cortex for a simple spatial detection and discrimination task arise from nonselective increases in response over a broad cortical locus that includes the representation of the task target, and selective suppression of responses to the task distractor within this locus.     

Activity of precentral neurons during torque-triggered hand movements in awake primates.

In monkeys performing a handle-repositioning task involving primarily wrist flexion-extension (F-E) movements after a torque perturbation was delivered to the handle, single units were recorded extracellularly in the contralateral precentral cortex. Precentral neurons were identified by passive somatosensory stimulation, and were classified into five somatotopically organized populations. Based on electromyographic recordings, it was observed that flexors and extensors about the wrist joint were specifically involved in the repositioning of the handle, while many other muscles which act at the wrist and other forelimb joints were involved in the task in a supportive role. In precentral cortex, all neuronal responses observed were temporally correlated to both the sensory stimuli and the motor responses. Visual stimuli, presented simultaneously with torque perturbations, did not affect the early portion of cortical responses to such torque perturbations. In each of the five somatotopically organized neuronal populations, task-related neurons as well as task-unrelated ones were observed. A significantly larger proportion of wrist (F-E) neurons was related to the task, as compared with the other, nonwrist (F-E) populations. The above findings were discussed in the context of a hypothesis for the function of precentral cortex during voluntary limb movement in awake primates. This hypothesis incorporates a relationship between activities of populations of precentral neurons, defined with respect to their responses to peripheral events at or about single joints, and movements about the same joint.     

Characteristics of Human Luminance Discrimination and Modeling a Neural Network Based on the Response Properties of the Visual Cortex

Reaction time (RT) and error rate that depend on stimulus duration were measured in a luminance-discrimination reaction time task. Two patches of light with different luminance were presented to participants for ‘short’ (150 ms) or ‘long’ (1 s) period on each trial. When the stimulus duration was ‘short’, the participants responded more rapidly with poorer discrimination performance than they did in the longer duration. The results suggested that different sensory responses in the visual cortices were responsible for the dependence of response speed and accuracy on the stimulus duration during the luminance-discrimination reaction time task. It was shown that the simple winner-take-all-type neural network model receiving transient and sustained stimulus information from the primary visual cortex successfully reproduced RT distributions for correct responses and error rates. Moreover, temporal spike sequences obtained from the model network closely resembled to the neural activity in the monkey prefrontal or parietal area during other visual decision tasks such as motion discrimination and oddball detection tasks.