Recovery of the dog myocardial contractile function in the diastolic period

Isolated canine heart has an expressed ability for autoregulation of mechanical restitution irrespective of the influence of neurohumoral factors and Frank-Starling law on the work of the heart. Mechanical restitution of canine heart in diastolic period starts after the end of mechanical refractory period of the heart and develops exponentially. The higher the heart rhythm the faster the speed of mechanical restitution. The higher the heart rhythm the shorter the mechanical refractory period. Mechanical refractory period of the heart is longer than bioelectrical refractory period.     

Assimilation of rhythm by the isolated dog heart during gradual raising of stimulation frequency

An ability for a forestalling regulation of contractility of the heart with calculation of the tendency of rhythm increasing was revealed under a gradual increasing of heart rhythm. A forestalling regulation of heart contractility occurs with rhythm assimilation at the cell level of the heart and irrespective of the influence of Frank-Starling law and neurohumoral factors on the work of the heart. A 5-10% increasing of heart rhythm is characterized by optimal rhythm assimilation. A 15-40% increasing of heart rhythm is not optimal and results in transformation of the rhythm. The following sequence of events take place in the process of transition from rhythm assimilation to rhythm transformation under a gradual increasing of heart rhythm: rhythm assimilation--rhythm by mechanical function--incomplete rhythm assimilation by electrical function-transformation of rhythm by electrical function.     

Instantaneous alteration of the dog heart contractility under instantaneous change in the stimulation rhythm

Isolated canine heart has an expressed ability for an instantaneous alteration in the sense of re-tuning, of contractility (of the speed of mechanical restitution in diastolic period) under instantaneous change of stimulation rhythm. Postextrasystolic potentiation reflects instantaneous rising of the speed of mechanical restitution under the influence of extrasystole in the condition of instantaneous transition to a higher rhythm. Depression of contractility reflects instantaneous decreasing of the speed of mechanical restitution under the influence of delayed stimulus in the condition of instantaneous transition to a slower rhythm. Alteration (re-tuning) of heart contractility occurred irrespective of the influence of neurohumoral factor and Frank-Starling law on the work of the heart. Alteration (re-tuning) of contractility occurs at an organ (cell) level.     

Thyroid effect on brain activity in adolescents during heart rhythm biofeedback session

Types of neurophysiologic and thyroid condition in 15-17-year old adolescents were studied for the purpose of heart rhythm biofeedback session effect by heart rhythm variability parameters. Changes of heart rhythm vegetative regulation activity modulate functional capacities of central vegetative regulation structures. The biofeedback training with heart rhythm variability parameters increases brain bioelectrical activity in different frequency ranges. The thyroid system modulates functional activity of vegetative regulation central structures uppermost at sympathotonic and thyreotropin increasing leads to increase of rhythm maker structure reactivity in brain.     

Mechanism of the discontinuance of work as a consequence of fatigue according to the change in the electromyogram in a hypnotic state]

A study was made of the changes in the bioelectrical activity of the muscles in the course of local static work up to "refusal" under the usual conditions and under condition of inhibition of the program-control function of the cortex (during the somnambulistic stage of hypnosis). Experimental results indicated that during the hypnotic state the time of persistence of the static effort doubled in comparison with control; the bioelectrical activity increased 1 1/2-2 times, and in individual experiments--3--4 times. In the light of the data obtained the mechanism of formation of "refusal" to work could be viewed as an active arrest of the activity of the central formations realizing the program-control functions.     

Molecular basis of the mammalian pressure-sensitive ion channels: focus on vascular mechanotransduction

Mechano-gated ion channels are implicated in a variety of neurosensory functions ranging from touch sensitivity to hearing. In the heart, rhythm disturbance subsequent to mechanical effects is also associated with the activation of stretch-sensitive ion channels. Arterial autoregulation in response to hemodynamic stimuli, a vital process required for protection against hypertension-induced injury, is similarly dependent on the activity of force-sensitive ion channels. Seminal work in prokaryotes and invertebrates, including the nematode Caenorhabditis elegans and the fruit fly drosophila, greatly helped to identify the molecular basis of volume regulation, hearing and touch sensitivity. In mammals, more recent findings have indicated that members of several structural family of ion channels, namely the transient receptor potential (TRP) channels, the amiloride-sensitive ENaC/ASIC channels and the potassium channels K2P and Kir are involved in cellular mechanotransduction. In the present review, we will focus on the molecular and functional properties of these channel subunits and will emphasize on their role in the pressure-dependent arterial myogenic constriction and the flow-mediated vasodilation.     

Ultradian oscillation in the heart rate of rainbow trout (Oncorhynchus mykiss)

• 1.1. Ultradian oscillations in the min and hr range on long-term (24-hr) computerized recordings of heart rate in rainbow trout Oncorhynchus mykiss, acclimated to 5, 10 and 15°C water temperature, were investigated. Eight-hour duration time series derived from the heart rate recordings were analysed for their harmonic content in the ultradian band by spectral analysis.
• 2.2. A significant ultradian rhythm at around 0.011 cycles/min (approximately 91-min period) was detected in the power spectral density functions of all the 8-hr duration time series derived from the heart rate recordings at the three experimental water temperatures.
• 3.3. The spectral power of the ultradian oscillation detected in heart rate of trout was found to increase significantly with increasing temperature.
• 4.4. The possible endogenous origin of the ultradian rhythm detected in heart rate of Oncorhynchus mykiss is discussed.

     

Evidence for Multiple Rhythmic Skills

Rhythms, or patterns in time, play a vital role in both speech and music. Proficiency in a number of rhythm skills has been linked to language ability, suggesting that certain rhythmic processes in music and language rely on overlapping resources. However, a lack of understanding about how rhythm skills relate to each other has impeded progress in understanding how language relies on rhythm processing. In particular, it is unknown whether all rhythm skills are linked together, forming a single broad rhythmic competence, or whether there are multiple dissociable rhythm skills. We hypothesized that beat tapping and rhythm memory/sequencing form two separate clusters of rhythm skills. This hypothesis was tested with a battery of two beat tapping and two rhythm memory tests. Here we show that tapping to a metronome and the ability to adjust to a changing tempo while tapping to a metronome are related skills. The ability to remember rhythms and to drum along to repeating rhythmic sequences are also related. However, we found no relationship between beat tapping skills and rhythm memory skills. Thus, beat tapping and rhythm memory are dissociable rhythmic aptitudes. This discovery may inform future research disambiguating how distinct rhythm competencies track with specific language functions.     

云南松同化器官数量垂直分布的规律

植物的同化器官一般是指制造和积累有机物质并用于满足植物生长发育需要的叶片(叶束)。它是植物的重要组成成分。同化器官吸收光能,在叶绿体和酶的作用下将二氧化碳和水合成为碳水化合物。它的数量的多少决定了植株制造有机物质的能力,直接关系到森林生态系统第一性生产力的高低。因此,研究植物群体和单株同化器官数量垂直分布的规律及其与     

Effect of ectopic excitation on pump function of the hen and dog right heart ventricle

The pump function of the right heart ventricle has been studied in anesthetized dogs and hens at sinus rhythm, supraventricular rhythm, and subepicardial ectopic excitation of base and apex of the right and left ventricles. Dynamics of the ventricle intracavital pressure was recorded by transmural catheterization. In hens, the pump function of the right ventricle (as compared with sinus rhythm) was preserved to the greater degree at stimulation of the left ventricle apex and deteriorated significantly at stimulation of the right ventricle, whereas in dogs, it retained to the greater degree (as compared with supraventricular rhythm) at stimulation of the left ventricle base and deteriorated at stimulation of the right ventricle apex. Changes of the pump function of the right heart ventricle at ectopic ventricle stimulation are similar in birds and mammals. Differences in changes of dog and hen pump functions under effect of location of the ectopic excitation seem to be due to morphofunctional peculiarities of heart ventricles.     

The Circadian Rhythm of Cardiac Frequency in Crayfish: a Multioscillator System?

The aim of this work was to study the humoral regulation of the circadian rhythm of cardiac frequency in crayfish and explore the possibility that isolated heart has a circadian-like oscillation. Sinus glands are the main source of neurohormones in crayfish, and their excision dampens the rhythm, lengthens the period and induces high frequency oscillations. Isolated crayfish hearts show a circadian-like rhythm of frequency with two peaks. These results suggest the participation of several oscillators in the generation and/or expression of the circadian rhythm.     

The Circadian Rhythm of Cardiac Frequency in Crayfish: a Multioscillator System?

The aim of this work was to study the humoral regulation of the circadian rhythm of cardiac frequency in crayfish and explore the possibility that isolated heart has a circadian-like oscillation. Sinus glands are the main source of neurohormones in crayfish, and their excision dampens the rhythm, lengthens the period and induces high frequency oscillations. Isolated crayfish hearts show a circadian-like rhythm of frequency with two peaks. These results suggest the participation of several oscillators in the generation and/or expression of the circadian rhythm.     

The coronary bed and its role in the cardiovascular system: a review and an introductory single-branch model

To investigate cardiovascular haemodynamics under normal and pathological conditions, a closed-loop model of the cardiovascular system already presented in the literature¹, has been complemented by a model of the coronary bed. Oxygen available to the myocardium is strictly related to the coronary blood flow; we have developed threshold criteria which correlate cardiac output with the coronary flow. The system utilizes control systems related to the cardiac contractility and frequency, and imitates feedback mechanisms peculiar to the heart. The work exemplifies the autoregulation of events that occur when the equilibrium of the system is disturbed. It is suggested that the heart plays an active role in trying to restore the haemodynamic parameters to their physiological values.     

对吸附式电极记录装置的技术改进

本文介绍一种用吸附式电极记录合体细胞组织生物电位的改进装置。它的特点是在建造负压的注射器和吸附式电极之间设置一分离的小室。这一小室既保障了放大器与实验标本之间的电路连系,又可直接放置在实验标本附近,负压由改进的注射器经过充有空气的塑料管抽吸,注射器可以放在任何方便的位置上。该方法在记录小动物,如蜗牛、青蛙、等的心脏、消化道等组织器官的生物电位时都能获得比较理想的效果,对研究小动物合体细胞组织的正常机能及药物作用等都具有较好的适用价值,并具有定位准确、操作方便的优点。     

Circadian Rhythms in Photosynthesis : Oscillations in Carbon Assimilation and Stomatal Conductance under Constant Conditions

Net carbon assimilation and stomatal conductance to water vapor oscillated repeatedly in red kidney bean, Phaseolus vulgaris L., plants transferred from a natural photoperiod to constant light. In a gas exchange system with automatic regulation of selected environmental and physiological variables, assimilation and conductance oscillated with a free-running period of approximately 24.5 hours. The rhythms in carbon assimilation and stomatal conductance were closely coupled and persisted for more than a week under constant conditions. A rhythm in assimilation occurred when either ambient or intercellular CO₂ partial pressure was held constant, demonstrating that the rhythm in assimilation was not entirely the result of stomatal effects on CO₂ diffusion. Rhythms in assimilation and conductance were not expressed in plants grown under constant light at a constant temperature, demonstrating that the rhythms did not occur spontaneously but were induced by an external stimulus. In plants grown under constant light with a temperature cycle, a rhythm was entrained in stomatal conductance but not in carbon assimilation, indicating that the oscillators driving the rhythms differed in their sensitivity to environmental stimuli.     

Circadian Rhythms in Stomatal Responsiveness to Red and Blue Light

Stomata of many plants have circadian rhythms in responsiveness to environmental cues as well as circadian rhythms in aperture. Stomatal responses to red light and blue light are mediated by photosynthetic photoreceptors; responses to blue light are additionally controlled by a specific blue-light photoreceptor. This paper describes circadian rhythmic aspects of stomatal responsiveness to red and blue light in Vicia faba. Plants were exposed to a repeated light:dark regime of 1.5:2.5 h for a total of 48 h, and because the plants could not entrain to this short light:dark cycle, circadian rhythms were able to "free run" as if in continuous light. The rhythm in the stomatal conductance established during the 1.5-h light periods was caused both by a rhythm in sensitivity to light and by a rhythm in the stomatal conductance established during the preceding 2.5-h dark periods. Both rhythms peaked during the middle of the subjective day. Although the stomatal response to blue light is greater than the response to red light at all times of day, there was no discernible difference in period, phase, or amplitude of the rhythm in sensitivity to the two light qualities. We observed no circadian rhythmicity in net carbon assimilation with the 1.5:2.5 h light regime for either red or blue light. In continuous white light, small rhythmic changes in photosynthetic assimilation were observed, but at relatively high light levels, and these appeared to be attributable largely to changes in internal CO2 availability governed by stomatal conductance.