Warfare and hominid brain evolution.

This paper reviews literature on the evolutionary effects of warfare upon the hominid brain. Alexander &; Tinkle (1968) and Bigelow (1969) are found to be the first to propose that warfare was the principle evolutionary pressure that created the novel substance of the human brain, and that it acted at least from the early Pleistocene. These writers are distinguished from Darwin (1871), Keith (1947) and Wilson (1975) who saw warfare influencing the development of the brain only in historical or near-historical times.The warfare hypothesis of Alexander &; Tinkle is found to be an excellent explanation of the evolution of the human brain, but to be unsatisfactory from a biological viewpoint because they do not explain how warfare evolved in the first place, nor do they attempt to account for the apparent absence of warfare as a behavioral adaptation in species other than some eusocial insects.This author underpins the warfare hypothesis, arguing that it evolved as a necessary consequence of the circumstances of early hominids. Proficient tool use gave domination over predators and opened up new food resources, thereby diminishing two population controls. A population explosion resulted and, at critical densities, when starvation threatened, warfare was the genetically most successful behavioral adaptation. Alternative hypotheses are shown to be inadequate. Finally, the author asks why such an important hypothesis has been ignored for almost a decade.     

Wasp venom injected into the prey's brain modulates thoracic identified monoaminergic neurons

The wasp Ampulex compressa injects a cocktail of neurotoxins into the brain of its cockroach prey to induce an enduring change in the execution of locomotory behaviors. Our hypothesis is that the venom injected into the brain indirectly alters the activity of monoaminergic neurons, thus changing the levels of monoamines that tune the central synapses of locomotory circuits. The purpose of the present investigation was to establish whether the venom alters the descending control, from the brain, of octopaminergic neurons in the thorax. This question was approached by recording the activity of specific identified octopaminergic neurons after removing the input from the brain or after a wasp sting into the brain. We show that the activity of these neurons is altered in stung and "brainless" animals. The spontaneous firing rate of these neurons in stung and brainless animals is approximately 20% that in control animals. Furthermore, we show that an identified octopamine neuron responds more weakly both to sensory stimuli and to direct injection of current in all treated groups. The alteration in the activity of octopamine neurons is likely to be part of the mechanism by which the wasp induces a change in the behavioral state of its prey and also affects its metabolism by reducing the potent glycolytic activator fructose 2,6-bisphosphate in leg muscle. To our knowledge, this is the first direct evidence of a change in electrical activity of specific monoaminergic neurons that can be so closely associated with a venom-induced change in behavioral state of a prey animal.     

Imaging genetic influences in human brain function

The association between genes and brain function using functional brain imaging techniques is an emerging and promising area of research that will help to better characterize the influence of genes on cognition and behavior as well as the link between genetic susceptibility and neuropsychiatric disorders. Neurophysiological imaging provides information regarding the effect of genes on brain function at the level of information processing, and neurochemical imaging provides information on the intrinsic mechanisms on how these genes affect the brain response. In this review, we highlight recent studies that have begun to explore the influence of genetic mutations on brain function with these techniques. The results, even from these few studies, illustrate the potential of these techniques to provide a more sensitive assay than behavioral measures used alone. The results also show that neuroimaging techniques can elucidate the influence of genes on brain function in relatively small sample populations, sometimes even in the absence of significant differences in behavioral measures.     

Mesenchymal stem cells-based therapy of brain ischemic stroke in rat

Mesenchymal stem cells (MSCs)-based therapy is a promising modern attempt to improve the recovery after stroke. Experiments were carried out on inbred Wistar-Kyoto rats. MSCs were isolated, expanded in cultute and labeled with vital fluorescent dye PKH-26. Animals were subjected to middle cerebral artery occlusion (MCAO), followed by injection of 5 x 10(6) rat MSCs into the tail vein 3 days after MCAO. Control group animals received PBS injection (negative control). Therapy results were estimated by the following parameters: behavioral and neurological testing, the brain injure area, the state of damaged region "border" zone and the vessels quantity in the "borden" area. It was shown that control group animals (PBS injection) did not restore their initial behavioral and neurological state, while the experimental group animals (MSCs injection) showed the same parameters as intact rats at 2-3 weeks after MCAO. The size of the damaged region in the control group was approximately 1.5 as large as in the experimental group. The damage in the experimental group was limited to neocortex; caudate nucleus, capsula externa and piriform cortex remained uninjured. Small vessels quantity in the "border" regions was twine higher compared to control group and was approximately equal to an intact brain vessel number. Moreover, it was shown for the first time that after MSCs transplantation the vessels quantity in the neocortex and caudate putamen of contralateral hemisphere was twice as much as in control. We demonstrated that the MSCs transplantation definitely exerted a positive influence upon the brain tissue reparation after stroke.     

Importance of behavioral manipulations and measures in rat models of brain damage and brain repair

The relevance of careful behavioral measures and manipulations in animal research on neural plasticity and brain damage has become increasingly clear. Recent research in adult rats indicates that an understanding of neural restructuring after brain damage requires an understanding of how it is influenced by postinjury behavioral experiences. Other research indicates that optimizing pharmacological and other treatments for brain damage may require their combination with rehabilitative training. Assessing the efficacy of a treatment approach in animal models requires the use of sensitive behavioral measures of functional outcome. In research on restorative plasticity after brain damage, procedures for handling and housing rats should promote the quality of behavioral measures and manipulations.     

Reconstruction of behavior-relevant individual brain activity: an individualized fMRI study

Different patterns of brain activity are observed in various subjects across a wide functional domain.However,these individual differences,which are often neglected through the group average,are not yet completely understood.Based on the fundamental assumption that human behavior is rooted in the underlying brain function,we speculated that the individual differences in brain activity are reflected in the individual differences in behavior.Adopting 98 behavioral measures and assessing the brain activity induced at seven task functional magnetic resonance imaging states,we demonstrated that the individual differences in brain activity can be used to predict behavioral measures of individual subjects with high accuracy using the partial least square regression model.In addition,we revealed that behavior-relevant individual differences in brain activity transferred between different task states and can be used to reconstruct individual brain activity.Reconstructed individual brain activity retained certain individual differences which were lost in the group average and could serve as an individual functional localizer.Therefore,our results suggest that the individual differences in brain activity contain behavior-relevant information and should be included in group averaging.Moreover,reconstructed individual brain activity shows a potential use in precise and personalized medicine.     

A noncholinergic action of acetylcholinesterase (AChE) in the brain: From neuronal secretion to the generation of movement

1. In various brain regions, there is a puzzling disparity between large amounts of acetylcholinesterase and low levels of acetylcholine. One such area is the substantia nigra. Furthermore, within the substantia nigra, a soluble form of acetylcholinesterase is released from the dendrites of dopamine-containing nigrostriatal neurons, independent of cholinergic transmission. These two issues have prompted the hypothesis that acetylcholinesterase released in the substantia nigra has an unexpected noncholinergic function. 2. Electrophysiological studies demonstrate that this dendritic release is a function, not of the excitability of the cell from which the acetylcholinesterase is released, but of the inputs to it. In order to explore this phenomenon at the behavioral level, a novel system has been developed for detecting release of acetylcholinesterase "on-line." It can be seen that release of this protein within the substantia nigra can reflect, but is not causal to, movement. 3. Once released, the possible actions of acetylcholinesterase can be studied at both the cellular and the behavioral level. Independent of its catalytic site, acetylcholinesterase has a "modulatory" action on nigrostriatal neurons. The functional consequences of this modulation would be to enhance the sensitivity of the cells to synaptic inputs. 4. Many basic questions remain regarding the release and action of acetylcholinesterase within the substantia nigra and, indeed, within other areas of the brain. Nonetheless, tentative conclusions can be formulated that begin, in a new way, to provide a link between cellular mechanisms and the control of movement.     

Depression-like changes in behavior and c-fos gene expression in dopaminergic brain structures in WAG/Rij rats

In WAG/Rij rats with genetic absence epilepsy, inborn changes in behavior were observed such as decreased level of locomotion, exploratory activity, and grooming reactions in the open-field test, increased immobility in the forced-swimming test, and decreased sucrose consumption (anhedonia) as compared to Wistar rats completely lacking in seizure pathology. These behavioral alterations in WAG/Rij rats resemble the symptoms of human depression (psychomotor retardation, depressed mood, and anhedonia). No significant behavioral changes were found in the light-dark choice, social interaction, and elevated plus-maze tests. This suggests the absence of increased anxiety in WAG/Rij rats. In contrast to Wistar, WAG/Rij rats were sensitive only to chronic treatment with antidepressant imipramine like depressive patients. Behavioral "despair" induced by forced swimming led to C-fos gene expression in three brain structures (frontal cortex, nucleus accumbens, and striatum), which are, respectively, terminal regions of three dopaminergic brain systems (mesocortical, mesolimbc, and nigrostriatal). c-fos gene expression in the brain of WAG/Rij rats was substantially different from that in the brain of Wistar rats in both intensity (in WAG/Rij the c-fos gene expression was higher than in Wistar rats in all involved brain structures) and its distribution between the structures. The results suggest that WAG/Rij strain is a new experimental (genetic) model of absence epilepsy-related depression unassociated with increased anxiety.     

Decoding lifespan changes of the human brain using resting-state functional connectivity MRI

The development of large-scale functional brain networks is a complex, lifelong process that can be investigated using resting-state functional connectivity MRI (rs-fcMRI). In this study, we aimed to decode the developmental dynamics of the whole-brain functional network in seven decades (8-79 years) of the human lifespan. We first used parametric curve fitting to examine linear and nonlinear age effect on the resting human brain, and then combined manifold learning and support vector machine methods to predict individuals' "brain ages" from rs-fcMRI data. We found that age-related changes in interregional functional connectivity exhibited spatially and temporally specific patterns. During brain development from childhood to senescence, functional connections tended to linearly increase in the emotion system and decrease in the sensorimotor system; while quadratic trajectories were observed in functional connections related to higher-order cognitive functions. The complex patterns of age effect on the whole-brain functional network could be effectively represented by a low-dimensional, nonlinear manifold embedded in the functional connectivity space, which uncovered the inherent structure of brain maturation and aging. Regression of manifold coordinates with age further showed that the manifold representation extracted sufficient information from rs-fcMRI data to make prediction about individual brains' functional development levels. Our study not only gives insights into the neural substrates that underlie behavioral and cognitive changes over age, but also provides a possible way to quantitatively describe the typical and atypical developmental progression of human brain function using rs-fcMRI.     

Understanding stem cell-mediated brain repair through neuroimaging

Transplantation of stem cells into the damaged brain can lead to behavioral recovery. However, at present, the mechanisms by which these cells exert their beneficial effects are still poorly understood. Survival, migration and differentiation are but a few of the factors that are thought to be involved in stem cell-mediated brain repair. It is hoped that neuroimaging, by MRI and PET, will provide serial in vivo assessments of transplanted cells that can lead to a greater understanding of the mechanisms involved in brain repair.     

Transplantation of fetal brain tissue. Some possibilities for neurobehavioral toxicology

Fetal brain tissue transplanted to the brain of an adult mammalian host is known to develop within this environment. The grafted tissue also forms connections with the host brain and can produce recovery from behavioral deficits associated with destruction of parts of the host brain. The ability of grafts of fetal brain tissue to both develop in and form electrophysiologically viable connections with brains previously exposed to neurotoxins is discussed in this review. Restoration of neurotoxin-induced behavioral dysfunction by fetal brain grafts is also discussed. Finally, several uses for neural transplantation in neurotoxicological research are suggested. These uses include restoration of behavioral function, identification of the particular structures responsible for observed behavioral deficits, from among several structures damaged by an environmental neurotoxin, and identification of mechanisms underlying neurotoxicity.     

Structure-activity-relationships of certain hallucinogenic substances based on brain levels.

A structure-activity-relationship of a variety of behaviorally active and inactive compounds which are naturally occuring or closely related structurally to putative neurotransmitters has been assembled. For the first time comparisons of activity are based on actual brain levels instead of doses administered.A different and new SAR is obtained if minimal effective brain levels (MEBL), instead of administered doses, are used. Differences are due to the fate of the substance in the body and its availability to the CNS. Predictions of brain levels based on $\text{in}$$\text{vitro}$ data, blood levels and/or lipid solubility can be misleading.It is suggested that the “minimal effective brain level (MEBL)” or that concentration of a substance in the brain in moles/g at which time the first significant behavioral effect in a particular test situation can be detected, be used as the basis of comparison in SAR studies of behaviorally active substances. This is, of course, not the ultimate parameter which might be the number of molecules of a substance at a particular receptor, but it would eliminate a great number of “artifacts” which can be controlled with the present state of the art.The use of MEBLs will allow more valid correlations between behavioral activity and certain physico-chemical parameters of the compounds, and an attempt to use MEBLs was recently made by Houk and co-workers (53). Also, MEBLs in animals can serve as a better base for the interpretation of human studies and can make these behavioral studies in man more meaningful; for instance, the lack of behavioral activity in bufotenin in man observed recently (54) could perhaps be due to the fact that at the doses tested the compound did not reach the CNS in sufficient concentrations because of its extreme difficulty in crossing the BBB. Similarly, 3,4-dimethoxyphenylethylamine has been found to be inactive in man after oral administration (55); based on our studies (27) the compound would actually not be expected to be active by this route since it is too quickly metabolized and cannot reach the MEBL, thus, the behavioral activity of this compound in man remains unknown.Based on the criteria applied in this review, LSD and 5-methoxytryptamine are the most potent psychoactive substances followed by tryptamine (after MAO-inhibition) and pentamethoxyphenylethylamine. It is of interest to note that tryptamine and 5-methoxytryptamine are known to occur naturally in the mammalian brain. It remains to be determined what role, if any, these substances may play in the pathogenesis of abnormal behavior in man.     

The circadian clock in the brain: a structural and functional comparison between mammals and insects

The circadian master clocks in the brains of mammals and insects are compared in respect to location, organization and function. They show astonishing similarities. Both clocks are anatomically and functionally connected to the optic system and possess multiple output pathways allowing synchronization with the environmental light-dark cycles as well as the control of diverse endocrine, autonomic and behavioral functions. Both circadian master clocks are composed of multiple neurons, which are organized in populations with different morphology, physiology and neurotransmitter content and appear to subserve different functions. In the hamster and in the cockroach, the master clock consists of a core region that gets input from the eyes, and a shell region from which the majority of output projections originate. Communication between core and shell, between all other populations of clock neurons as well as between the master clocks of both brain hemispheres is a prerequisite of normal rhythmic function. Phenomena like rhythm splitting and internal desynchronization can be observed under constant light conditions and are caused by the uncoupling of the master clocks of both brain hemispheres.     

艾灸对缺氧缺血性脑损伤新生小鼠的治疗作用*

目的: 探讨艾灸对缺氧缺血性脑损伤新生小鼠行为学表现、脑组织形态结构的影响及作用机制。方法: 将106只出生7 d小鼠随机分为三组:假手术组(23只)、模型组(46只)和艾灸组(37只)。采用左侧颈总动脉结扎后再置于37℃密闭舱内进行低氧处理(氧气浓度为8%,100 min),制备新生儿缺氧缺血性脑病动物模型。艾灸组同模型组,并于造模后2 h开始艾灸“大椎”进行治疗,以后每日1次,每次35 min,连续治疗4 d。采用行为学测试评价小鼠的行为学表现;HE染色观察小鼠脑组织形态结构;Western blot技术检测小鼠脑组织超氧化物歧化酶2(SOD2)蛋白表达;比色法测定小鼠脑组织丙二醛(MDA)含量。结果: 假手术组小鼠行为表现正常,脑组织细胞排列致密整齐,脑组织SOD2蛋白表达量和MDA含量正常。与假手术组相比,模型组小鼠翻正反射、趋地反射、悬崖躲避试验时间延长(P＜0.05),抓力试验时间缩短(P＜0.05);脑组织细胞大量坏死脱落;脑组织SOD2蛋白表达量明显减少(P＜0.05)、MDA含量增加。与模型组相比,艾灸组小鼠翻正反射、趋地反射、悬崖躲避试验时间缩短(P＜0.05),抓力试验时间增长(P＜0.05);脑组织细胞排列较致密、整齐;脑组织SOD2蛋白表达量增多(P＜0.05)、MDA含量降低(P＜0.05)。结论: 艾灸能减轻缺氧缺血性脑病新生小鼠脑损伤、改善行为学表现,这可能与其增加脑组织SOD2蛋白的表达、降低MDA含量,从而提高抗氧化应激能力有关。     

Moving toward a generalizable application of central thalamic deep brain stimulation for support of forebrain arousal regulation in the severely injured brain

This review considers the challenges ahead for developing a generalizable strategy for the use of central thalamic deep brain stimulation (CT/DBS) to support arousal regulation mechanisms in the severely injured brain. Historical efforts to apply CT/DBS to patients with severe brain injuries and a proof-of-concept result from a single-subject study are discussed. Circuit and cellular mechanisms underlying the recovery of consciousness are considered for their relevance to the application of CT/DBS, to improve consciousness and cognition in nonprogressive brain injuries. Finally, directions for development, and testing of generalizable criteria for CT/DBS are suggested, which aim to identify neuronal substrates and behavioral profiles that may optimally benefit from support of arousal regulation mechanisms.     

Effects of prenatal disturbance in the brain testosterone metabolism on anxiety level and behavior of rats in a novel environment

The effects of maternal administration of the aromatase inhibitor 1,4,6-androstatrien-3,17-dione (ATD) during the last week of gestation on formation of behavior in a novel environment were studied in male and female offspring. The "open field" and the elevated plus-maze tests were used. The results showed that there were a significant elevation of the anxiety level and emotionality in ATD-treated 30-day-old female rats, whereas at the age of 90 days, the elevation of these behavioral parameters was observed both in males and females. There was no a sexual dimorphism in behavioral response to a novel environment such as locomotor activity, time of immobilization, total duration of grooming reaction, and anxiety level between adult control male and treated female rats. These data suggest that prenatal inhibition of the brain testosterone metabolism alters the formation of sexual dimorphism of the anxiety and behavioral response to a novel environment in adulthood.     

Effect of tuftsin on the orientation-exploratory behavior of normal white rats and against a background of pharmacologically induced disorders of the brain biogenic amine system

The application of "hole board" method showed that the endogenic immunostimulator tetrapeptide tuftsin injected intraperitoneally in dose 0.3 mg/kg has a short-time stimulating action on the orienting reaction of rats in 5 min, though in 24 hours it suppresses the registered behavioral indexes. The pharmacological analysis of the above studied phenomenon showed that catecholaminergic and especially dopaminergic brain systems played the leading role in tuftsin effect. Tuftsin can normalize animals' behaviour disturbed by the pharmacological agents, which slightly influence the functioning of the brain dopaminergic system.     

Influence of aging on brain and web characteristics of an orb web spider

In animals, it is known that age affects the abilities of the brain. In spiders, we showed that aging affects web characteristics due to behavioral alterations during web building. In this study, we investigated the effects of age on the associations between morphological changes to the spider brain and changes in web characteristics. The orb web spider Zygiella x-notata (Araneae, Araneidae) was used to test these relationships. Experiments were conducted on young (19 ± 2 days after adult molt, N = 13) and old (146 ± 32 days, N = 20) virgin females. The brain volume decreased with age (by 10%). Age also had an impact on the number of anomalies in the capture area generated during web building. The statistical relationships between the volume of the brain and web characteristics showed that there was an effect of age on both. Our results showed that in spiders, aging affects the brain volume and correlates with characteristics (anomalies) of the web. As web building is the result of complex behavioral processes, we suggest that aging affects spider behavior by causing some brain alterations.