Influence of cognitive load on the body functional state in children aged 9 to 12 years during early stages of puberty

This article analyzes heart rate variability (HRV), the glucocorticoid function of adrenal glands, and brain electrical activity (EA) in children aged 9 to 12 years to study their functional state during early stages of puberty. The cognitive load (mental arithmetic) caused low-frequency waves in the heart rate spectrum in all subjects, regardless of the puberty stage and gender. With respect to the age range under study, the hormonal response to the arithmetic test, expressed in a decrease in the level of cortisol, was observed in boys only at the third stage of puberty. The visual analysis of the background electrical encephalogram showed frequent generalized bilateral and synchronous changes in the electrical activity (EA) in the form of diencephalic signs in children. The features of the relationship between the autonomic nervous system and the hypothalamic pituitary-adrenal system have been revealed in children aged 9 to 12 years during cognitive load. The closest correlations between HRV indices and cortisol levels have been found in girls at the first stage and boys at the third stage of puberty.     

Effects of brief starvation on brain protease activity

Changes in the activity of proteases (cathepsin D and calpains) caused by 48-h food withdrawal were studied in the brain, liver, kidney, spleen, and heart of 3-, 12-, and 24-month-old Fischer rats. Cathepsin D activity was similar in brain, liver, and heart of control animals; in kidney it was 5-fold higher and in spleen about 10-fold higher. With age, activity increased in all organs tested except spleen. Brief starvation caused no change of cathepsin D activity in brain, but caused an increase in liver and a decrease in spleen. Neutral proteolytic activity in control was highest in the pons-medulla-cerebellum fraction of brain, and activity in liver and heart was below that in brain. Activity increased with age in brain and decreased in other organs. Brief starvation in young animals caused an increase in activity in brain, and a decrease in liver and spleen. Isolated calpain II activity was high in control brain. It increased with age in the cerebrum. Brief starvation resulted in a decrease in the brain. The results indicate that the protease content of the brain is altered with age and in malnutrition, with changes not being the same for all proteases, and changes in brain being different from those in other organs.Special issue dedicated to Dr. Louis Sokoloff.     

Age-related changes in mitochondrial membrane composition of rainbow trout (Oncorhynchus mykiss) heart and brain

Membrane composition, particularly of mitochondria, could be a critical factor by determining the propagation of reactions involved in mitochondrial function during periods of high oxidative stress such as rapid growth and aging. Considering that phospholipids not only contribute to the structural and physical properties of biological membranes, but also participate actively in cell signaling and apoptosis, changes affecting either class or fatty acid compositions could affect phospholipid properties and, thus, alter mitochondrial function and cell viability. In the present study, heart and brain mitochondrial membrane phospholipid compositions were analyzed in rainbow trout during the four first years of life, a period characterized by rapid growth and a sustained high metabolic rate. Specifically, farmed fish of three ages (1-, 2- and 4-years) were studied, and phospholipid class compositions of heart and brain mitochondria, and fatty acid compositions of individual phospholipid classes were determined. Rainbow trout heart and brain mitochondria showed different phospholipid compositions (class and fatty acid), likely related to tissue-specific functions. Furthermore, changes in phospholipid class and fatty acid compositions with age were also tissue-dependent. Heart mitochondria had lower proportions of cardiolipin (CL), phosphatidylserine (PS) and phosphatidylinositol, and higher levels of phosphatidylcholine (PC) and phosphatidylethanolamine (PE) with age. Heart mitochondrial membranes became more unsaturated with age, with a significative increase of peroxidation index in CL, PS and sphingomyelin (SM). Therefore, heart mitochondria became more susceptible to oxidative damage with age. In contrast, brain mitochondrial PC and PS content decreased in 4-year-old animals while there was an increase in the proportion of SM. The three main phospholipid classes in brain (PC, PE and PS) showed decreased n-3 polyunsaturated fatty acids, docosahexaenoic acid and peroxidation index, which indicate a different response of brain mitochondrial lipids to rapid growth and maturation.     

Superoxide dismutase, glutathione peroxidase and catalase in developing rat brain.

The specific activities of Cu,Zn- and Mn-superoxide dismutases, of glutathione peroxidase and of catalase, the enzymes considered to be specifically involved in the defence of the cell against the partially reduced forms of oxygen, were determined as the function of postnatal age in the early (up to 60 days) period of rat brain development. The enzymes were assayed in the cytoplasmic fraction, in the crude mitochondrial fraction including peroxisomes, and in the mitochondria. The results show that the temporal changes of these enzymes cannot be correlated with each other, thus indicating that they do not concertedly parallel the increasing activity of aerobic brain metabolism during development. Specifically the cytoplasmic fraction shows a gradual increase of the Cu,Zn-superoxide dismutase activity with age, whereas the glutathione peroxidase activity is constant from birth. Furthermore the increase of the mitochondrial Mn-superoxide dismutase as a function of postnatal age is more remarkable than that of the cytoplasmic Cu,Zn-enzyme. Higher activities of catalase in adult animals are detectable only in the subcellular fraction containing peroxisomes, because of the modest catalase activity of the brain. These results indicate independent regulation of the expression of these enzyme activities in the process of brain differentiation and point to a relative deficiency of enzymic protection of the brain differentiation and point to a relative deficiency of enzymic protection of the brain against potentially toxic oxygen derivatives. This situation is similar to the pattern already described in the rat heart and in rat and mouse ascites-tumour cells, at variance with the much more efficient enzyme pattern present in rat hepatocytes.     

δ-Aminolevulinic acid synthetase: Regulation of activity in various tissues of the aging rat

The basal and ethanol-induced activities of the rate-limiting enzyme of heme biosynthesis, δ-aminolevulinic acid (ALA) synthetase were measured in the liver, heart, kidney, and brain of young, adult, and aged Sprague-Dawley rats. When assayed in whole mitochondria derived from either fed or 24-h fasted animals, the basal levels of hepatic ALA synthetase activity decreased dramatically as a function of age. An equivalent decrease was seen in the ethanol-induced activity although the ratio of induced to basal activities did not change with age. In the heart, ALA synthetase activity also decreased significantly during aging. The activity was not induced by ethanol and was decreased markedly by fasting. By contrast, kidney ALA synthetase activity showed no age-related changes. The activity was unaffected by fasting and showed a variable induction response to ethanol. Brain ALA synthetase activity displayed a significant age-dependent decrease in its activity which was neither affected by fasting nor sensitive to induction by ethanol. The data presented are consistent with the hypothesis that ALA synthetase activity is subject to metabolic regulation. Further, they indicate that while the enzyme activity is regulated in a tissuespecific manner, a time-dependent decrease is a general feature of the aging animal.     

Mutational fingerprints of aging

Using a lacZ plasmid transgenic mouse model, spectra of spontaneous point mutations were determined in brain, heart, liver, spleen and small intestine in young and old mice. While similar at a young age, the mutation spectra among these organs were significantly different in old age. In brain and heart G:C→A:T transitions at CpG sites were the predominant mutation, suggesting that oxidative damage is not a major mutagenic event in these tissues. Other base changes, especially those affecting A:T base pairs, positively correlated with increasing proliferative activity of the different tissues. A relatively high percentage of base changes at A:T base pairs and compound mutants were found in both spleen and spontaneous lymphoma, suggesting a possible role of the hypermutation process in splenocytes in carcinogenesis. The similar mutant spectra observed at a young age may reflect a common mutation mechanism for all tissues that could be driven by the rapid cell division that takes place during development. However, the spectra of the young tissues did not resemble that of the most proliferative aged tissue, implying that replicative history per se is not the underlying causal factor of age-related organ-specific differences in mutation spectra. Rather, differences in organ function, possibly in association with replicative history, may explain the divergence in mutation spectra during aging.     

Oxidative damage and antioxidant enzyme activities in experimental hypothyroidism

Free radicals are now well known to damage cellular components. To investigate whether age and thyroid level affect peroxidation speed, we examined the levels of malondialdehyde and antioxidant enzyme activities in different age groups of hypothyroid rats. Hypothyroidism was induced in 30- and 60-day-old Wistar Albino rats by the i.p. administration of propylthiouracil (10 mg kg(-1) body weight) for 15 days. While malondialdehyde levels of 30- or 60-day-old hypothyroid rats were increased in liver, they were decreased in the tissues of the heart and thyroid. While glucose-6-phosphate dehydrogenase activity levels did not change in heart, brain and liver tissues of 30-day-old rats, they increased in brain and heart tissues of 60-day-old experimental groups, but decreased in the liver. Catalase activities decreased in the liver and heart of rats with hypothyroidism, but increased in erythrocytes. In control groups while malondialdehyde levels increased in brain, heart and thymus with regard to age, they decreased in plasma. Glucose-6-phosphate dehydrogenase and catalase activities were not affected by age in tissues of the thymus, thyroid and brain, but they were decreased in the heart tissue. The changes in the levels of lipid peroxidation and antioxidant enzyme activities which were determined in different tissues of hypothyroid rats indicate a cause for functional disorder of these tissues. Moreover, there may be changes depending on age at lipid peroxidation and antioxidant enzyme activity levels.     

Expression of muscle creatine kinase gene of mice and interaction of nuclear proteins with MEF-2, E boxes and A/T-rich elements during aging

The changes in the expression of muscle creatine kinase (MCK) gene in the heart and skeletal muscle of mice during aging were studied. Its expression declines as a function of age in the heart, however, no age-related change is observed in the skeletal muscle. The cis-acting elements, MEF-2, E boxes and A/T rich elements present in the enhancer region of the mouse MCK gene are known to regulate the expression of the gene. Hence, these elements were subcloned and electrophoretic mobility shift assay was carried out to investigate the changes in the binding of the nuclear trans-acting protein factors of the heart with these elements as a function of age. These factors showed specificity for the respective cis-acting elements. Furthermore, the binding of these factors was found to decrease during aging which may contribute to the age-related decline in the expression of the MCK gene and activity of the heart.     

Intracellular distribution of creatine kinase isoenzymes in the brains and hearts of rats at different stages of postnatal development]

The total activity and range of the creatine kinase (CK) isozymes have been studied in the homogenate and subcellular fractions (nuclei, mitochondria, cytoplasm) of the rat brain and heart during postnatal ontogenesis. The total activity of CK in the brain and heart of newborn rats was found to be 4 and 2 times less, resp., than in those of adults. The age patterns were established in the activity of cytoplasmic (CK-1, CK-2 and CK-3) and mitochondrial (CK-4) isozymes. During the whole postnatal development the rat brain contains only one cytoplasmic isozyme, CK-1. In the heart of newborn rats, as compared with adults, the content of CK-1 and CK-2 is much higher and that of CK-3 lower. On the 12-15th day of life the range of the CK isozymes approaches that characteristic of adult animals. The activity of CK-4 was found in the brain on the 5-7th day of life and in the heart on 12-15th day. In the range of the CK isozymes in the adult brain the content of mitochondrial CK amounts to 19.3% and in the heart to 16.5%. The data obtained complement the literary ones suggesting the low level of energy-forming processes in the brain and heart cells at the early stages of the rat postnatal development.     

小鼠组织中过氧化氢酶的活性与年龄的关系

为观察小鼠组织中过氧化氢酶的活性与年龄的关系,采用高锰酸钾滴定法测定不同年龄(1、4、18月龄)小鼠肝、肾、肺、心、脾、胃、脑组织中过氧化氢酶的活性。结果显示:小鼠过氧化氢酶在不同组织中活性不同,活性高低顺序基本表现为:肝>肾>肺>心、脾、胃>脑;小鼠肺、心、脾、胃、脑各组织中过氧化氢酶的活性在1～4月龄间随年龄增加而增加,在4～18月龄间随年龄增加而降低;小鼠肝、肾组织中过氧化氢酶的活性在1～4月龄间与年龄相关性不显著,在4～18月龄间随年龄增加而降低。结果表明,小鼠肝、肾、肺、心、脾、胃、脑等组织中过氧化氢酶的活性随年龄变化而变化,机体过氧化氢酶活性的降低与机体衰老密切相关。     

Monitoring Cerebral Function: Clinical Experience with New Device for Continuous Recording of Electrical Activity of Brain

A device, the cerebral function monitor, provides a continuous record of the electrical activity of the brain occurring at frequencies from 2 to 15 Hz. It is relatively cheap, portable, and easy to use and interpret. The apparatus has proved of value in three circumstances: firstly, when the cerebral circulation is likely to be vulnerable during open heart surgery; secondly, as a measure of recovery or deterioration following brain damage or drug overdose; and thirdly, where information about more physiological changes in cerebral function is required, for instance when testing anaesthetic and hypnotic drugs.     

Age-Related Changes in Task Related Functional Network Connectivity

Aging has a multi-faceted impact on brain structure, brain function and cognitive task performance, but the interaction of these different age-related changes is largely unexplored. We hypothesize that age-related structural changes alter the functional connectivity within the brain, resulting in altered task performance during cognitive challenges. In this neuroimaging study, we used independent components analysis to identify spatial patterns of coordinated functional activity involved in the performance of a verbal delayed item recognition task from 75 healthy young and 37 healthy old adults. Strength of functional connectivity between spatial components was assessed for age group differences and related to speeded task performance. We then assessed whether age-related differences in global brain volume were associated with age-related differences in functional network connectivity. Both age groups used a series of spatial components during the verbal working memory task and the strength and distribution of functional network connectivity between these components differed across the age groups. Poorer task performance, i.e. slower speed with increasing memory load, in the old adults was associated with decreases in functional network connectivity between components comprised of the supplementary motor area and the middle cingulate and between the precuneus and the middle/superior frontal cortex. Advancing age also led to decreased brain volume; however, there was no evidence to support the hypothesis that age-related alterations in functional network connectivity were the result of global brain volume changes. These results suggest that age-related differences in the coordination of neural activity between brain regions partially underlie differences in cognitive performance.     

Enzyme levels in chick embryo heart and brain from 1 to 21 days of development

Enzyme activity levels were measured in chick embryo brain and heart during development, beginning with medullary plate and cardiogenic mesentoderm.To study heart and brain during the period of morphogenesis (1–4 days) a method for freezedrying whole chick embryos was developed. In three divisions of brain—diencephalon, telencephalon, and hindbrain-hexokinase, glyceraldehyde-3-P dehydrogenase, and 6-P-gluconic dehydrogenase maintained approximately constant levels of activity during this period. Brain glucose-6-P dehydrogenase levels fell somewhat, but contrary to earlier reports showed no wide fluctuations. In heart, glucose-6-P dehydrogenase activity fell to one-half between 1 and 4 days, 6-P-gluconic dehydrogenase activity remained constant, while hexokinase activity doubled in atrium from 1 to 2 days, and tripled in ventricle from 1 to 4 days.From 6 to 21 days of development, homogenates of hearts and brains were used. Hexokinase activity in brain increased four-fold during this period, while in heart the specific activity did not change. Glyceraldehyde-3-P dehydrogenase activity showed no change in either organ. NAD-dependent isocitric dehydrogenase increased in both heart and brain, fourfold in brain, nearly twofold in heart. α-Ketoglutaric dehydrogenase increased 50% in brain and 250% in heart.The increasing levels of citric acid cycle enzymes probably reflect an increasing energy demand in both organs during the last 2 weeks before hatching. Since adult brain depends primarily upon glucose for energy, it seems reasonable that the hexokinase activity continued to increase. Adult heart, however, obtains its energy from substrates other than glucose, which may account for the fact that during the last 2 weeks no change in heart hexokinase activity was seen.     

Seasonality of glycogen phosphorylase activity in crucian carp (<Emphasis Type="Italic">Carassius carassius</Emphasis> L<Emphasis Type="Italic">.</Emphasis>)

Seasonal changes in the activity of glycogen phosphorylase (GP), a rate-limiting enzyme of glycogen degradation, were examined in an anoxia-tolerant fish species, the crucian carp (Carassius carassius L.). In muscle and brain, the activity of GP remained constant throughout the year when tested at 25°C. In contrast, the activities of liver and heart GP displayed striking increases in summer. When seasonal temperature changes are taken into account, the activity of GP during the anoxic mid-winter is only 4–6% of its summer time activity in the muscle, heart and liver, and 13% in brain. In winter-acclimatized fish, experimental anoxia (1–6 weeks) caused sustained depression of the GP activity in heart and gills. In liver and muscle, a transient depression of GP activity occurred during the first week of anoxia but later GP activity recovered back to the normoxic level. GP of the brain was completely resistant to anoxia. In all studied tissues, the constitutive activity of GP is more than sufficient to degrade glycogen deposits during winter anoxia without anoxia-induced activation of GP. The seemingly paradoxical summer-time increase in the activity of liver and heart GP could be related to active life-style of the summer-acclimatized fish (growth, reproduction), the increased demand of energy and molecular precursors of anabolic metabolism being satisfied by preferential degradation of glycogen. The high glycogen content of winter-acclimatized crucian carp is not associated with the elevated GP activity or anoxic activation of GP.     

Photoperiodism and changes in brain bioelectric activity in schoolchildren in the arctic zone

The dynamics of the main electroencephalographic patterns and their relationship with natural illumination periods have been described in this study. We have determined periods, which are the most favorable for brain functioning and development of cognitive function in northerner schoolchildren. We have found that adaptive changes in bioelectric activity of the brain take place during transitional seasons. An increase in the activity of all EEG rhythms in spring and predominance of the slow-wave Δ and θ activity in autumn have been found. The discovered dynamics of amplitude and spectral parameters of EEG are not dependent on age-related changes. The formation of bioelectric activity of the brain in northerner schoolchildren was mostly affected by the sex of a child and changes in the daytime duration.     

Allosteric activation of brain hexokinase by magnesium ions and by magnesium-ion–adenosine triphosphate complex

1. The highest blood concentrations of ketone bodies were found at 5 days of age, after which time the concentration fell to reach the adult value by 30 days of age. 2. Both mitochondrial and cytoplasmic hydroxymethylglutaryl-CoA synthase activities were detected, with highest activities being found in the mitochondria at all stages of development. Activity of the mitochondrial enzyme increases rapidly immediately after birth, showing a maximum at 15 days of age, thereafter falling to adult values. The cytoplasmic enzyme, on the other hand, increased steadily in activity after birth to reach a maximum at 40 days of age, after which time activity fell to adult values. 3. Both mitochondrial and cytoplasmic aceto-acetyl-CoA thiolase activities were detected, with the mitochondrial enzyme having considerably higher activities at all stages of development. The developmental patterns for both enzymes were very similar to those for the corresponding hydroxymethylglutaryl-CoA synthases. 4. The activity of heart acetoacetyl-CoA transferase remains constant from late foetal life until the end of the suckling period, after which time there is a gradual threefold increase in activity to reach the adult values. The activity of brain 3-oxo acid CoA-transferase increases steadily after birth, reaching a maximum at 30 days of age, thereafter decreasing to adult values, which are similar to foetal activities. Although at all stages of development the specific activity of the heart enzyme is higher than that of brain, the total enzymic capacity of the brain is higher than that of the heart during the suckling period.     

Changes in some indices of the cardiovascular system in different mental tasks

In order to study the effects of the type of mental activity on the function of the cardiovascular system in humans, the following indices were used: the heart rate (HR), RR interval, variation magnitude (VM), systolic wave amplitude (SWA), and pulse wave transit time (PWTT). These indices were recorded when the subjects solved verbal-logical or spatial mental tasks. The HR was substantially increased during solving of the spatial tasks as compared to solving of the verbal-logical tasks, whereas the SWA showed the opposite changes. The latencies of the performance of the tasks of various types were similar in the subjects; therefore, the changes in the autonomic indices did not depend on the difficulties of the mental tasks. They rather depended on specific features of the mental processes involved in the performance of the tasks of different types. Thus, changes in the HR and the decreased SWA, which was related to elevated blood pressure, represent the effect of the sympathetic nervous system on the heart function during solving verbal-logical tasks. Our data demonstrate that the HR and blood pressure can be used as additional indices for the development of new techniques for assessment of different types of mental processes together with the indices of electrical brain activity.     

Phospholipid exchange activity in developing rat brain

Phospholipid exchange activity has been determined in the supernatant fraction of rat brain from birth through to maturity by measuring the protein-catalysed transfer of total and individual 32P-labelled phospholipids from microsomal membranes to mitochondria, and the transfer of [14C]phosphatidylcholine from liposomes to mitochondria. Transfer activity has also been compared in brain and liver supernatant. Overall phospholipid exchange activity in the brain increased only slightly with age. The activity at birth was 75% of the adult value. However, the transfer of individual phospholipids showed markedly different trends during postnatal brain development. The transfer of phosphatidylinositol (PI) and ethanolamine phospholipids increased postnatally to a maximum at 9 days of age, with lowest values in adult brain. Phosphatidylcholine (PC) transfer increased from 9 days to reach maximum values in the mature brain. The transfer of sphingomyelin was highest immediately after birth. PI transfer activity was higher in brain than liver, while PC and ethanolamine phospholipid transfer activity was higher in liver. The heterogeneity of phospholipid exchange proteins in central nervous system tissue is reflected in the developmental changes in exchange activity towards individual phospholipids. The various exchange proteins appear to have separate induction mechanisms. The presence of exchange-protein activity from birth in the rat indicates the functional importance of phospholipid transport during cell acquisition and membrane proliferation. Activity is not primarily associated with membrane formation such as the formation of the myelin sheath, and therefore is more likely to be involved in the process of phospholipid turnover.     

Age-Related Changes in Electroencephalographic Signal Complexity

The study of active and healthy aging is a primary focus for social and neuroscientific communities. Here, we move a step forward in assessing electrophysiological neuronal activity changes in the brain with healthy aging. To this end, electroencephalographic (EEG) resting state activity was acquired in 40 healthy subjects (age 16–85). We evaluated Fractal Dimension (FD) according to the Higuchi algorithm, a measure which quantifies the presence of statistical similarity at different scales in temporal fluctuations of EEG signals. Our results showed that FD increases from age twenty to age fifty and then decreases. The curve that best fits the changes in FD values across age over the whole sample is a parabola, with the vertex located around age fifty. Moreover, FD changes are site specific, with interhemispheric FD asymmetry being pronounced in elderly individuals in the frontal and central regions. The present results indicate that fractal dimension well describes the modulations of brain activity with age. Since fractal dimension has been proposed to be related to the complexity of the signal dynamics, our data demonstrate that the complexity of neuronal electric activity changes across the life span of an individual, with a steady increase during young adulthood and a decrease in the elderly population.