西伯利亚幼鲟对偶极子电场的避让行为研究

研究利用人工偶极子电场来模拟生物电场刺激, 对西伯利亚幼鲟的电感受能力进行了行为探究。结果显示西伯利亚幼鲟对本实验中的偶极子电场产生躲避行为, 其平均感受阈值在2月龄为(457.532.5) V/cm,3月龄为(29.52.5) V/cm, 7月龄为(101.0) V/cm。这表明西伯利亚鲟鱼的电感受敏感性随个体的发育而增强, 而这可能与电感受器官数量的增加有关(2月龄为2234470, 7月龄为5273523)。     

电场诱导细胞融合

细胞在电场中极化成偶极子,并沿电力线排列成串;在加直流脉冲后,膜被击穿而导致融合。这是一种空间定向、时间同步的可控式的细胞融合新技术。     

食蚊鱼的生物电场特征

文章采用活体记录的方法测量了食蚊鱼(Gambusia affinis)的生物电场。实验分单尾鱼、两尾鱼同向和两尾鱼反向三组测量, 每组10 个重复。结果表明:单尾鱼的生物电场表现为头负、尾正的偶极子直流电场,头部相对电势为(242.4) V, 尾部为(211.6) V, 且头部附近产生1-3 Hz 与呼吸频率对应的交流呼吸电场, 大小为(4.20.8) V。两尾鱼生物电场测量表明, 其直流电场均大于单尾鱼(P0.05); 两尾鱼同向靠近时产生的交流呼吸电场显著大于单尾鱼(P0.01), 而反向靠近时产生的呼吸电场显著小于单尾鱼(P0.001)。这表明两条鱼不同方向靠近时, 可通过呼吸作用改变交流呼吸电场的大小。此种现象对于依靠感知交流呼吸电场来摄食的被动电感受鱼类是不利的。       

鲶鱼和胡子鲶的两性异形与雌性个体生育力

检测了鲶鱼(Silurus asotus)和胡子鲶(Clarias fuscus)繁殖期18个形态特征的两性异形以及雌性个体生育力。结果表明,鲶鱼和胡子鲶雌雄性别比例均符合1∶1。One-way ANOVA显示,鲶鱼雌雄个体体长差异不显著,胡子鲶雌性个体体长显著小于雄性个体(P0.05)。以体长为协变量的One-way ANCOVA显示,特定体长的鲶鱼雌性个体的眼间距和体高显著大于雄性个体(P0.05),两性间其它局部特征不存在显著的两性差异;特定体长的胡子鲶雌性个体的体高、腹鳍基前距和腹鳍臀鳍间距显著大于雄性个体,雌性个体的臀鳍基长、尾柄高和尾鳍长显著小于雄性个体(P0.05),两性间其它局部特征不存在显著的两性差异。Two-way ANOVA显示,胡子鲶体长显著大于鲶鱼(P0.05),性别及物种与性别两因素的相互作用对体长影响不显著。以体长为协变量的Two-way ANCOVA显示,胡子鲶的头长、头宽、吻长、眼间距、尾柄高、尾鳍长、背鳍基前距、背鳍基长、腹鳍基前距、腹鳍臀鳍间距、体重和去内脏体重显著大于鲶鱼,头高、体高、臀鳍基长显著小于鲶鱼(P0.05),物种间的其他形态特征变量差异不显著;雌性个体的体高、背鳍基前距、腹鳍基前距、腹鳍臀鳍间距显著大于雄性个体,臀鳍基长、尾柄高、尾鳍长、背鳍基长显著小于雄性个体(P0.05),两性间的其他形态特征变量差异不显著;物种与性别两因素的相互作用对体高、臀鳍基长、尾柄高、尾鳍长、背鳍基长和腹鳍臀鳍间距影响显著,对其余的形态特征变量影响不显著。15个形态特征变量的主成分分析(Eigenvalue≥1)发现,前2个主成分共解释68.4%的变异。头宽、眼间距、尾柄高、尾鳍长、背鳍基前距、背鳍基长、腹鳍基前距和腹鳍臀鳍间距在第一主成分有较高的正负载系数,臀鳍基长在第一主成分有较高的负负载系数(解释51.2%变异);眼后头长在第二主成分有较高的负负载系数(解释17.2%变异)。胡子鲶在第一主成分和第二主成分的分值均显著大于鲶鱼,雌雄两性的差异以及两因素的相互作用对分值的影响均不显著。实验检测的鲶鱼、胡子鲶的怀卵数量与体长和体重回归关系显著。One-way ANCOVA及矫正平均值Tukey's检验显示,特定体长的胡子鲶的产卵数量显著大于鲶鱼。性选择是胡子鲶大个体雄性形成的主要原因,同时影响与运动相关的尾部特征。生育力选择更多的影响与雌性胡子鲶较大腹腔容积相关的形态特征变异。环境因子、食物可得性和营养状况同时影响了个体大小两性异形的形成。     

我国鲶科鱼类的总述

本总述包括3个属(鲶属、缺鳍鲶属和叉尾鲶属),共计12个种。其中1个种是新种,命名为兰州鲶(Silurus lanzhouensis,sp.nov.),采于黄河水系;另1个是南方大口鲶新亚种(Silurussoldatovi meridionalis,subsp.nov.),生活在长江及长江以南大的江河中。两种成体均具有2对口须。通过鲶属大多数种的头骨的比较,发现鲶属有3个类型,主要是以上筛骨的形状来区别。在这3个类型中各有2对和3对口须的种,因此作者认为以口须的多少作为属的特征是不够的,本文仍按以往有些学者的观点,将4须鲶属作为鲶属的异名。在我国各处最普通的种是鲶鱼,但时常在若干水系中也出现具4根口须的很相近似的种,互相混淆。鲶鱼必须依据什么特征来识别,是长期没有解决的问题。作者根据各方面的记述,提出无论雌雄其胸鳍刺外缘均具有显著的锯齿,才是鲶鱼的主要特征。我们曾函询瑞典的两个博物馆,据回信:“看来,保藏在瑞典的林奈的鲶鱼模式标本已经遗失了。”因而作者指定把我国黑龙江水系所产的10尾鲶鱼标本作为新的模式标本,存放于水生生物研究所鱼类标本室。本文还讨论了鲶科鱼类的起源与地理分布问题。     

我国鲶科鱼类的总述

本总述包括3个属(鲶属、缺鳍鲶属和叉尾鲶属),共计12个种。其中1个种是新种,命名为兰州鲶(Silurus lanzhouensis,sp．nov．),采于黄河水系;另1个是南方大口鲶新亚种(Silurus soldatovi meridionalis,subsp．nov．),生活在长江及长江以南大的江河中。两种成体均具有2对口须。通过鲶属大多数种的头骨的比较,发现鲶属有3个类型,主要是以上筛骨的形状来区别。在这3个类型中各有2对和3对口须的种,因此作者认为以口须的多少作为属的特征是不够的,本文仍按以往有些学者的观点,将4须鲶属作为鲶属的异名。在我国各处最普通的种是鲶鱼,但时常在若干水系中也出现具4根口须的很相近似的种,互相混淆。鲶鱼必须依据什么特征来识别,是长期没有解决的问题。作者根据各方面的记述,提出无论雌雄其胸鳍刺外缘均具有显著的锯齿,才是鲶鱼的主要特征。我们曾函询瑞典的两个博物馆,据回信：“看来,保藏在瑞典的林奈的鲶鱼模式标本已经遗失了。”因而作者指定把我国黑龙江水系所产的10尾鲶鱼标本作为新的模式标本,存放于水生生物研究所鱼类标本室。本文还讨论了鲶科鱼类的起源与地理分布问题。     

应用于脑电场的新型等效源法的正演理论

将新型等效源法引入脑电场电位的计算,视激励源为偶极子,实现真实电源既可以在真实的头模型中产生电位,也可以在均质无界空间中产生电位.从无界空间中三维拉普拉斯方程解的球形等效源的有限级数项表达式可见,该半解析方法克服了头模型对电位分布的干扰,在无界空间中计算出的电位是电源的裸表现.本文利用等效分布源理论推导出无界空间中任意偶极子源的球形等效源的正演理论公式,为高分辨脑电地形图技术中的重构皮层电位提供了一种方法.     

长甲壳吃木头的怪鱼

<正>科学家在南美洲亚马逊雨林河流中发现一种鲶鱼新物种,它们以水中木头为食,身体上长有甲壳结构。被称为"吸盘嘴装甲"的鲶鱼物种使用独特的牙齿刮擦淹浸在水中木头表面的有机物质。     

鳜鱼视觉特性及其对捕食习性适应的研究III．视觉对猎物运动和形状的反应

作者采用行为学方法测定了伏击型凶猛鱼类鳜鱼视觉对猎物运动和形状特征的反应特性.鳜鱼对3种不同体形饵料鱼有最强的跟踪反应和攻击反应,对虾则有较强的跟踪反应而几乎没有攻击反应,对蜻蜒幼虫仅有不强的跟踪反应而完全没有攻击反应.它对低速(v≤5cm/s)一连续和等间歇不连续运动的饵料鱼有较强的跟踪反应和攻击反应,对中速和高速(v≥10cm/s)连续运动的饵料鱼有最强的跟踪反应而几乎没有或完全没有攻击反应,对中速和高速等间歇不连续运动的饵料鱼则有最强的跟踪反应和最强的攻击反应.它对不连续运动的a、b、c、d、e、f6种形状均有跟踪反应,但近距离跟踪反应的强度与形状特征有关系,对不连续运动的b、c、d3种形状完全没有攻击反应,而对不连续运动的a、e、f3种形状则有依次增强的攻击反应.鳜鱼视觉可对猎物运动进行远距离的识别,并决定其对猎物的远距离跟踪反应.且其视觉仅能对猎物的大致形状进行近距离识别,并决定其对猎物的近距离跟踪反应和攻击反应.       

蝇髓部细胞的运动敏感性

用细胞外记录方法研究了蝇髓部细胞的运动敏感性.实验证明,在蝇髓部有运动敏感型细胞,它们的主要特点是对运动敏感,但不具有方向选择性.其主要性质如下:1.有些细胞对闪光刺激给出超极化反应,有些则为去极化反应;2.对运动反应,但不具有方向性;3.有些对大视场的运动敏感,有些则对小视场的运动敏感;4.反应幅度与图形运动速度有关;5.感受野为简单型,并且不很大.对于可能对应的算法进行了讨论.     

Response properties of electrosensory neurons in the lateral mesencephalic nucleus of the paddlefish

Many fishes and amphibians are able to sense weak electric fields from prey animals or other sources. The response properties of primary afferent fibers innervating the electroreceptors and information processing at the level of the hindbrain is well investigated in a number of taxa. However, there are only a few studies in higher brain areas. We recorded from electrosensory neurons in the lateral mesencephalic nucleus (LMN) and from neurons in the dorsal octavolateral nucleus (DON) of the paddlefish. We stimulated with sine wave stimuli of different amplitudes and frequencies and with moving DC stimuli. During sinusoidal stimulation, DON units increased their firing rate during the negative cycle of the sine wave and decreased their firing rate to the positive cycle. Lateral mesencephalic nucleus units increased their rate for both half cycles of the sine wave. Lateral mesencephalic nucleus units are more sensitive than DON units, especially to small moving dipoles. Dorsal octavolateral nucleus units respond to a moving DC dipole with an increase followed by a decrease in spike rate or vice versa, depending on movement direction and dipole orientation. Lateral mesencephalic nucleus units, in contrast, increased their discharge rate for all stimuli. Any change in discharge rate of DON units is converted in the LMN to a discharge rate increase. Lateral mesencephalic nucleus units therefore appear to code the presence of a stimulus regardless of orientation and motion direction.     

Electric field detection in sawfish and shovelnose rays

In the aquatic environment, living organisms emit weak dipole electric fields, which spread in the surrounding water. Elasmobranchs detect these dipole electric fields with their highly sensitive electroreceptors, the ampullae of Lorenzini. Freshwater sawfish, Pristis microdon, and two species of shovelnose rays, Glaucostegus typus and Aptychotrema rostrata were tested for their reactions towards weak artificial electric dipole fields. The comparison of sawfishes and shovelnose rays sheds light on the evolution and function of the elongated rostrum ('saw') of sawfish, as both groups evolved from a shovelnose ray-like ancestor. Electric stimuli were presented both on the substrate (to mimic benthic prey) and suspended in the water column (to mimic free-swimming prey). Analysis of around 480 behavioural sequences shows that all three species are highly sensitive towards weak electric dipole fields, and initiate behavioural responses at median field strengths between 5.15 and 79.6 nVcm(-1). The response behaviours used by sawfish and shovelnose rays depended on the location of the dipoles. The elongation of the sawfish's rostrum clearly expanded their electroreceptive search area into the water column and enables them to target free-swimming prey.     

基于模拟退火法由脑磁图推测电流偶极子参数

利用模拟退火（Ｓｉｍｕｌａｔｅｄ Ａｎｎｅａｌｉｎｇ） 算法,由脑磁图（ ＭＥＧ） 数据反演脑内作为磁源的单电流偶极子参数,可以得到理想的结果。在上述工作的基础上,对脑内多电流偶极子参数的反演,则呈现如下状况：即以少于实际源数目的偶极子为源假设反演,目标函数得不到极小优化。反之,目标函数可以得到极小优化, 但出现多余的伪偶极子, 且这些伪偶极子在多次不同条件的反演结果中,处于不稳定状态。若将多次反演结果中处于不稳定状态的偶极子作为伪偶极子的判据而将其排除,则可以得到一种判断磁源偶极子数目的方法     

Dipole models of alpha-rhythm generators

Different hypothesis of the alpha rhythm origin were tested by dipole simulation of the alpha rhythm sources. EEG was recorded during driving photic stimulation in order to increase the signal-to-noise ratio. Models with fixed and moving dipoles were analyzed. Dipole sources were compared with magnetic resonance imaging (MRI) scans to find the exact location of oscillations in brain anatomical structures. A two-level multiple dipole model was found to fit the EEG most adequately. The first level was represented by two oscillators localized in the thalamic reticular nuclei, and the second level is associated with two modality-specific oscillators localized in the respective cortical areas.     

Dipole source analysis of auditory P300 response in depressive and anxiety disorders

This paper is to study auditory event-related potential P300 in patients with anxiety and depressive disorders using dipole source analysis. Auditory P300 using 2-stimulus oddball paradigm was collected from 35 patients with anxiety disorder, 32 patients with depressive disorder, and 30 healthy controls. P300 dipole sources and peak amplitude of dipole activities were analyzed. The source analysis resulted in a 4-dipole configuration, where temporal dipoles displayed greater P300 amplitude than that of frontal dipoles. In addition, a right-greater-than-left hemispheric asymmetry of dipole magnitude was found in patients with anxiety disorder, whereas a left-greater-than-right hemispheric asymmetry of dipole magnitude was observed in depressed patients. Results indicated that the asymmetry was more prominent over the temporal dipole than that of frontal dipoles in patients. Patients with anxiety disorder may increase their efforts to enhance temporal dipole activity to compensate for a deficit in frontal cortex processing, while depressed patients show dominating reduction of right temporal activity. The opposite nature of results observed with hemispheric asymmetry in depressive and anxiety disorders could serve to be valuable information for psychiatric studies.     

Sensitivity to electricity in the catfish, Parasilurus asotus

The Japanese catfish (Parasilurus asotus) responded in its respiratory reflex to weak electric field not less sensitively than Gymnarchus niloticus. A sensitivity peak was found at about 1-30 Hz. The threshold voltage gradient of the electroreceptive system was determined to be about 0.05 microV/cm. High sensitivity to electric field fluctuating in low frequency being common to Siluriformes, the role of the sensory systems may be common beyond the difference of habitats among species.     

Photoselection studies of the P-800 band in the photoreaction center of Rhodospirillum rubrum

Polarization measurements of light-induced absorption changes in photoreaction center prepared from Rhodospirillum rubrum indicate that the 870 nm band is most likely due to a single transition dipole. The 800 nm band appears to be formed by transition dipoles with at least three different orientations. In photoreaction center from strain G9, none of the transition dipoles of the 800 nm band appears to form an angle larger than 70° with the 870 nm transition dipole.     

Steady-state fluorescence polarization studies of the orientation of myosin regulatory light chains in single skeletal muscle fibers using pure isomers of iodoacetamidotetramethylrhodamine.

The regulatory light chain (RLC) from chicken gizzard myosin was covalently modified on cysteine 108 with either the 5- or 6-isomer of iodoacetamidotetramethylrhodamine (IATR). Labeled RLCs were purified by fast protein liquid chromatography and characterized by reverse-phase high-performance liquid chromatography (HPLC), tryptic digestion, and electrospray mass spectrometry. Labeled RLCs were exchanged into the native myosin heads of single skinned fibers from rabbit psoas muscle, and the ATR dipole orientations were determined by fluorescence polarization. The 5- and 6-ATR dipoles had distinct orientations, and model orientational distributions suggest that they are more than 20 degrees apart in rigor. In the rigor-to-relaxed transition (sarcomere length 2.4 microm, 10 degrees C), the 5-ATR dipole became more perpendicular to the fiber axis, but the 6-ATR dipole became more parallel. This orientation change was absent at sarcomere length 4.0 microm, where overlap between myosin and actin filaments is abolished. When the temperature of relaxed fibers was raised to 30 degrees C, the 6-ATR dipoles became more parallel to the fiber axis and less ordered; when ionic strength was lowered from 160 mM to 20 mM (5 degrees C), the 6-ATR dipoles became more perpendicular to the fiber axis and more ordered. In active contraction (10 degrees C), the orientational distribution of the probe dipoles was similar but not identical to that in relaxation, and was not a linear combination of the orientational distributions in relaxation and rigor.     

The evolution of electroreception and bioelectrogenesis in teleost fish: a phylogenetic perspective

According to current phylogenetic theory, both electroreceptors and electric organs evolved multiple times throughout the evolution of teleosts. Two basic types of electroreceptors have been described: ampullary and tuberous electroreceptors. Ampullary‐type electroreceptors appeared once in the common ancestor of the Siluriformes+Gymnotiformes (within the superorder Ostariophysi), and on two other occasions within the superorder Osteoglossomorpha: in the African Mormyriformes and in the African Notopteriformes. Tuberous receptors are assumed to have evolved three times; all within groups that already possessed ampullary receptors. With the exception of a single catfish species, for which studies are still lacking, all fish with tuberous electroreceptors also have an electric organ. Tuberous electroreceptors are found in the two unrelated electrogenic teleost lineages (orders Gymnotiformes and Mormyriformes) and in one non‐electrogenic South American catfish species (order Siluriformes). Electric organs evolved eight times independently among teleosts: five of them among the ostariophysans (once in the gymnotiform ancestor and in four siluriform lineages), once in the common ancestor of Mormyriformes, and in two uranoscopids. With the exception of two uranoscopid genera, for which no electroreceptive capabilities have been discovered so far, all electric organs evolved as an extension of a pre‐existing electroreceptive (ampullary) condition. It is suggested that plesiomorphic electric organ discharges (EODs) possessed a frequency spectrum that fully transgressed the tuning curve of ampullary receptors, i.e. a signal such as a long lasting monophasic pulse. Complex EOD waveforms appeared as a derived condition among electric fish. EODs are under constant evolutionary pressure to develop an ideal compromise between a function that enhances electrolocation and electrocommunication capabilities, and thereby ensures species identity through sexual and behavioural segregation, and minimizes the risk of predation.     

Source modeling of esophageal evoked potentials

Evoked potentials can be recorded from the scalp after stimulation of the esophagus by balloon distension. The purpose of this study was to estimate the number and localization of sources contributing to the esophageal evoked potential (EEP). The EEP was recorded from 32 scalp electrodes in 5 healthy subjects. Spatio-temporal dipole modeling was performed in the time interval from 185 msec to 525 msec after stimulation (mean values). The EEP was best explained by the combined activity of 1 dipole located relatively high in the midline and 2 lateral dipoles. Given the anatomical projection of esophageal sensory fibers and the location of these dipoles, the sources were probably located in the cingulate gyri and insular cortex. There was no evidence that sources in the lower brain-stem contributed to the scalp recorded EEP.