培养大鼠搏动心肌细胞在缺氧和复氧时的电生理观察

应用细胞内微电极技术记录到37个培养大鼠搏动心肌细胞充氮前后和复氧后的电活动参数。结果提示:充氮10min后,最大舒张电位(MDP),最大除极速度(V_(max)),动作电位振幅(APA)和动作电位时程(APD)等参数明显降低;自发节律增快,并出现多种形式的节律失常。83.8％细胞在充氮后30min内停搏,16.2％在50min左右停搏。复氧后,86.5％细胞在5min内复跳,13.5％未能复跳;12.5％复跳细胞在复跳10min内再次停搏。复跳细胞的各项电活动参数在30min内未能恢复到充氮前水平(p<0.05),且呈现不同程度的各类异常电活动。本结果对进一步研究心肌细胞缺氧和复氧损伤有一定意义。     

Early homing of adult mesenchymal stem cells in normal and infarcted isolated beating hearts

Little is known on the early homing features of transplanted mesenchymal stem cells (MSCs). We used the isolated rat heart model to study the homing of MSCs injected in the ventricular wall of a beating heart. In this model all types of cells and matrix elements with their interactions are represented, while external interferences by endothelial/neutrophil interaction and neurohormonal factors are excluded. We studied the morphology and marker expression of MSCs implanted in normal hearts and in the border-zone of infarcted myocardium. Early morphological adaptation of MSC homing differs between normal and infarcted hearts over the first 6 hrs after transplantation. In normal hearts, MSCs migrate very early through the interstitial milieu and begin to show morphological changes. Yet, in infarcted hearts MSCs remain in the site of injection forming clusters of round-shaped cells in the border-zone of the infarcted area. Both in normal and infarcted hearts, immuno-histochemistry and confocal imaging showed that, besides the proliferative marker proliferating cell nuclear agent (PCNA), some transplanted cells early express myoblastic maker GATA-4, and some of them show a VWF immunopositivity. Moreover, a few hours after injection connexin-43 is well evident between cardiomyocytes and injected cells. This study indicates for the first time that the isolated beating heart is a good model to study early features of MSC homing without external interferences. The results show (i) that MSCs start to change marker expression few hours after injection into a beating heart and (ii) that infarcted myocardium influences transplanted MSC morphology and mobility within the heart.     

Beta-adrenergic regulation of contractility and protein phosphorylation in spontaneously beating isolated rat myocardial cells

Spontaneously beating heart myocytes were prepared from adult rat ventricular tissues to study the correlation between beta-adrenergic receptor-stimulated changes in contractile performance and protein phosphorylation in vitro. The plasma membrane of isolated myocardial cells was permeabilized by saponin in the presence of EGTA and Mg-ATP. The permeabilized myocytes, which formed a homogeneous cell population, retained the rod-cell morphology of heart cells in situ and showed spontaneous cyclic contractions. Their contractile activity in response to extracellularly added cAMP mimicked the effects caused by beta-adrenergic stimulation of the whole heart: both the frequency and longitudinal velocity of free contraction and relaxation of the cells increased. Similar increases were observed when beta-agonist, isoproterenol, and GTP were added to suspending medium. In addition, isoproterenol maximally enhanced the adenylate cyclase activity of the cells in the presence of GTP. Both of these effects of isoproterenol were completely blocked by the beta-antagonist propranolol. cAMP-mediated phosphorylation of proteins in the permeabilized myocytes was investigated under conditions in which the beating frequency increased. cAMP elevated the phosphorylation level of five proteins; three of them with apparent molecular masses of 24, 15, and 12 kDa were membrane proteins and the other two with apparent molecular masses of 150 and 28 kDa were myofibrillar proteins. The 24-kDa phosphoprotein dissociated into 12-kDa molecules when boiled in sodium dodecyl sulfate, suggesting that these proteins are oligomeric and monomeric forms of phospholamban. The phosphorylation of these five proteins was stimulated by isoproterenol. The effect of isoproterenol was enhanced by GTP but completely blocked by propranolol. The time course of their phosphorylation correlated well with that of the increase in the beating frequency of the cells; both were measured after the administration of isoproterenol and GTP. When propranolol was added after the start of the stimulation by isoproterenol, only phospholamban and the 15-kDa protein were rapidly dephosphorylated in close correlation with the decrease of the beating frequency. These results demonstrate for the first time that the permeabilized myocytes retain the functional beta-adrenergic receptor and cellular responses to beta-adrenergic stimulation. They also suggest that cAMP-mediated phosphorylation of proteins, possibly phospholamban and/or the 15-kDa protein, is involved in the increased contractile activity of permeabilized heart cells.     

Halteria grandinella: a rapid swimming ciliate with a high frequency of ciliary beating

A ciliated protozoan, Halteria grandinella, swam backward rapidly with a migration distance per second attaining 100 times the cell size. This high swimming velocity was accompanied by a high frequency of ciliary beating. Recordings with a high-speed digital video (10(3) frames/s) revealed that the frequency during forward and backward swimming was, respectively, 105 +/- 10 Hz and 260 +/- 30 Hz. These frequencies are the highest among cilia and flagella reported to date. Electron microscopic observation of the ciliary structure confirmed normal 9 + 2 arrangements of the axoneme except that cilia for migration are bundled into membranelles. Ciliary beating of saponin-treated cells was reactivated by the addition of Mg2+ -ATP, although the beating amplitude was smaller than that of intact cells. Kinetic analysis of the ATP-dependent increase of beating frequency revealed that the maximal frequency in the presence of free Ca2+ and 0.9 microM Ca2+ was approximately 60 and 110 Hz, respectively. A possible mechanism to increase beating frequency with Ca2+ is discussed.     

Beyond Bowditch: the convergence of cardiac chronotropy and inotropy

The ability of the heart to acutely beat faster and stronger is central to the vertebrate survival instinct. Released neurotransmitters, norepinephrine and epinephrine, bind to beta-adrenergic receptors (beta-AR) on pacemaker cells comprising the sinoatrial node, and to beta-AR on ventricular myocytes to modulate cellular mechanisms that govern the frequency and amplitude, respectively, of the duty cycles of these cells. While a role for sarcoplasmic reticulum Ca(2+) cycling via SERCA2 and ryanodine receptors (RyR) has long been appreciated with respect to cardiac inotropy, recent evidence also implicates Ca(2+) cycling with respect to chronotropy. In spontaneously beating primary sinoatrial nodal pacemaker cells, RyR Ca(2+) releases occurring during diastolic depolarization activate the Na(+)-Ca(2+) exchanger (NCX) to produce an inward current that enhances their diastolic depolarization rate, and thus increases their beating rate. beta-AR stimulation synchronizes RyR activation and Ca(2+) release to effect an increased beating rate in pacemaker cells and contraction amplitude in myocytes: in pacemaker cells, the beta-AR stimulation synchronization of RyR activation occurs during the diastolic depolarization, and augments the NCX inward current; in ventricular myocytes, beta-AR stimulation synchronizes the openings of unitary L-type Ca(2+) channel activation following the action potential, and also synchronizes RyR Ca(2+) releases following depolarization, and in the absence of depolarization, both leading to the generation of a global cytosolic Ca(i) transient of increased amplitude and accelerated kinetics. Thus, beta-AR stimulation induced synchronization of RyR activation (recruitment of additional RyRs to fire) and of the ensuing Ca(2+) release cause the heart to beat both stronger and faster, and is thus, a common mechanism that links both the maximum achievable cardiac inotropy and chronotropy.     

Dynamic Model for Characterizing Contractile Behaviors and Mechanical Properties of a Cardiomyocyte

Studies on the contractile dynamics of heart cells have attracted broad attention for the development of both heart disease therapies and cardiomyocyte-actuated micro-robotics. In this study, a linear dynamic model of a single cardiomyocyte cell was proposed at the subcellular scale to characterize the contractile behaviors of heart cells, with system parameters representing the mechanical properties of the subcellular components of living cardiomyocytes. The system parameters of the dynamic model were identified with the cellular beating pattern measured by a scanning ion conductance microscope. The experiments were implemented with cardiomyocytes in one control group and two experimental groups with the drugs cytochalasin-D or nocodazole, to identify the system parameters of the model based on scanning ion conductance microscope measurements, measurement of the cellular Young’s modulus with atomic force microscopy indentation, measurement of cellular contraction forces using the micro-pillar technique, and immunofluorescence staining and imaging of the cytoskeleton. The proposed mathematical model was both indirectly and qualitatively verified by the variation in cytoskeleton, beating amplitude, and contractility of cardiomyocytes among the control and the experimental groups, as well as directly and quantitatively validated by the simulation and the significant consistency of 90.5% in the comparison between the ratios of the Young’s modulus and the equivalent comprehensive cellular elasticities of cells in the experimental groups to those in the control group. Apart from mechanical properties (mass, elasticity, and viscosity) of subcellular structures, other properties of cardiomyocytes have also been studied, such as the properties of the relative action potential pattern and cellular beating frequency. This work has potential implications for research on cytobiology, drug screening, mechanisms of the heart, and cardiomyocyte-based bio-syncretic robotics.     

Further studies on preservation of the beating rhythm of myocardial cells in culture

1. 1. Single myocardial cells from fetal mouse heart beat spontaneously in monolayer culture. In standard medium they maintained a constant beating rate for at least 5 h. After the beating rate of individual cells had been accelerated for a short time by electrical stimulation, the original beating rate could be immediately restored by interrupting the stimulation. Quiescent myocardial cells from neonatal mouse atrium could be induced to beat by electrical stimulation and most of them ceased to beat again immediately by interrupting the stimulation.

2. 2. After the spontaneous beating of individual myocardial cells had been stopped or slowed down for a short time by incubation in medium of low temperature or high potassium or low calcium concentration, the original beating rate could be restored by replacing the cells in the original, normal medium.

3. 3. After the spontaneous beating of individual myocardial cells had been stopped by adding a metabolic inhibitor, such as 2,4-dinitrophenol or 2-deoxyglucose, the original beating rate could be restored by replacing the cells in the original, normal medium.

4. 4. Both single myocardial cells and cell clusters showed arrhythmia, including flutter and fibrillation, in medium of low potassium or high calcium concentration. After a short period of arrhythmia, the original beating rate could be restored by replacing the cells in the original, normal medium. The arrhythmia of cell clusters produced in either low potassium or high calcium medium was also corrected immediately by addition of quinidine sulfate.

     

A study on the preservation of the beating rhythm of single myocardial cells in vitro

Single myocardial cells from fetal mouse heart beat spontaneously in monolayer culture. In standard medium they maintained constant beating rates for at least 5 h at 37 °C. When the beats of single myocardial cells were stopped for a short time by treatment with EGTA, or slowed down by incubating the cells in medium of low pH, the original beating rates could be restored by replacing the cells in the original medium. The same procedure also restored the rates after they had been disturbed by incubating the cells in medium of low sodium and high potassium ion content. Moreover, the original beating rates could be restored after keeping the cells at 10 °C for 22–24 h, but not after keeping them at 37 °C for 22–24 h.     

Proliferation,differentiation and ciliary beating of human respiratory ciliated cells in primary culture

Summary The growth, differentiation, ciliary beating pattern and frequency of human respiratory ciliated cells in primary culture were studied by scanning and transmission electron microscopy and by videomicroscopy. The epithelial cells were obtained as outgrowth from explants of adult nasal polyps. When the explants were grown on type-I and type-IV collagen substrates in a standard serum-free, hormone-supplemented medium, a high percentage of ciliated cells (range 29±5% to 37±6%) was present within 2 days of culture. After 5 days of culture, the percentage of ciliated cells near the explant was 51±5%. Most of the cultured ciliated cells (85%) were characterized by individual cilia showing a coordinated movement during the beat cycle and a beating frequency (13.3±1.3 Hz) similar to that reported in vivo. In the other 15% of the ciliated cells, the dyskinetic cilia were aggregated into clumps and characterized by a rigid and planar bending movement and a lower (P<0.01) beating frequency (10.7±1.4 Hz). It is suggested that the latter type of cell, already described during fetal development, might be an intermediate type of ciliated cell which appears temporarily during the surface respiratory epithelial differentiation.     

Effects of carbenoxolone on heart rhythm, contractility and intracellular calcium in streptozotocin-induced diabetic rat

Cardiac dysfunction is a frequently reported complication of clinical and experimental diabetes mellitus. Streptozotocin (STZ) – induced diabetes in rat is associated with a variety of cardiac defects including disturbances to heart rhythm and prolonged time-course of cardiac muscle contraction and/or relaxation. The effects of carbenoxolone (CBX), a selective gap junction inhibitor, on heart rhythm and contractility in STZ-induced diabetic rat have been investigated. Heart rate was significantly (P < 0.05) reduced in Langendorff perfused spontaneously beating diabetic rat heart (171±12 BPM) compared to age-matched controls (229± 9 BPM) and further reduced by 10⁻⁵ M CBX in diabetic (20%) and in control (17%) hearts. Action potential durations (APDs), recorded on the epicardial surface of the left ventricle, were prolonged in paced (6 Hz) diabetic compared to control hearts. Perfusion of hearts with CBX caused further prolongation of APDs and to a greater extent in control compared to diabetic heart. Percentage prolongation at 70% from the peak of the action potential amplitude after CBX was 18% in diabetic compared to 48% in control heart. CBX had no significant effect on resting cell length or amplitude of ventricular myocyte shortening in diabetic or control rats. However, resting fura-2 ratio (indicator for intracellular Ca²⁺ concentration) and amplitude of the Ca²⁺ transient were significantly (P < 0.05) reduced by CBX in diabetic rats but not in controls. In conclusion the larger effects of CBX on APD in control ventricle and the normalizing effects of CBX on intracellular Ca²⁺ in ventricular myocytes from diabetic rat suggest that there may be alterations in gap junction electrophysiology in STZ-induced diabetic rat heart.     

Effects of prolonged quiescence on neuclei and chromatin of WI-38 fibroblasts.

DNA synthesis and cell division are markedly reduced in confluent mono-layers of WI-38 diploid fibroblasts, but resume again if the depleted medium is replaced by fresh medium containing 10% fetal calf serum. If the cells are kept quiescent for prolonged periods of time after confluence (1 or 2 weeks), the fraction of cells that can be stimulated to proliferate by fresh serum decreases and the length of the prereplicative phase increases. The template activity of isolated nuclei decreases with increasing time of quiescence, and parallel changes occur in chromatin as evidenced by circular dichroism spectra and capacity to bind the intercalating dye, ethidium bromide. When WI-38 cells are stimulated to proliferate after prolonged quiescence, the increase in template activity of nuclei is delayed by several hours in comparison to cells stimulated after short periods of quiescence. Two distinct steps, both requiring serum, can be identified in the prereplicative phase of cells stimulated to proliferative after prolonged quiescence. We interpret the results as indicating that, during prolonged quiescence, WI-38 fibroblasts go into a deeper GO state from which they can be rescued only after prolonged stimulation. In this respect, prolonged quiescence may bear some resemblance to the process of aging.     

EFFECTS OF CORTISOL ON CULTURED RAT HEART CELLS : Lipase Activity, Fatty Acid Oxidation, Glycogen Metabolism, and ATP Levels as Related to the Beating Phenomenon

This paper reports the determination of the ability of rat heart cells in culture to release [¹⁴C]palmitate from its triglyceride and to oxidize this fatty acid and free [¹⁴C]palmitate to ¹⁴CO₂ when the cells are actively beating and when they stop beating after aging in culture. In addition, the levels of glucose, glycogen, and ATP were determined to relate the concentration of these metabolites with beating and with cessation of beating. When young rat heart cells in culture are actively beating, they oxidize free fatty acids at a rate parallel with cellular ATP production. Both fatty acid oxidation and ATP production remain constant while the cells continue to beat. Furthermore, glucose is removed from the growth medium by the cells and stored as glycogen. When cultured cells stop beating, a decrease is seen in their ability to oxidize free fatty acids and to release them from their corresponding triglycerides. Concomitant with decreased fatty acid oxidation is a decrease in cellular levels of ATP until beating ceases. Midway between initiation of cultures and cessation of beating the cells begin to mobilize the stored glycogen. When the growth medium is supplemented with cortisol acetate and given to cultures which have ceased to beat, reinitiation of beating occurs. Furthermore, all decreases previously observed in ATP levels, fatty acid oxidation, and esterase activity are restored.     

Asynchronous swimmeret beating during defense turns in the crayfish, Procambarus clarkii

Swimmeret beating was monitored in freely moving specimens of the crayfish Procambarus clarkii as they exhibited defense turn responses to tactile stimuli. Analysis of videotape records revealed alterations in swimmeret beating during turning responses compared to straight, forward walking. During turns, swimmerets beat with shorter periods and smaller amplitude power strokes than during straight walking. Coordination between swimmerets also changed. Swimmerets on the side toward which the animal turned tended to lag behind their contralateral partners, rather than beat in synchrony as in straight walking, and ipsilateral coordination was loosened relative to straight walking. Asynchronous swimmeret beating accompanied asymmetric motions of the uropods in a manner similar to that observed during statocyst-dependent equilibrium reactions in P. clarkii, but removal of the statoliths did not eliminate turn-associated responses of the swimmerets. The coordinated action of the swimmerets and uropods may contribute to the torque that rotates the animal in the yaw plane. Implications of the observed changes in swimmeret coordination for understanding the underlying neuronal control system are discussed.     

微电极矩阵研究小鼠胚胎心脏电生理活动

本实验采用一种新方法——微电极矩阵技术从整体水平研究小鼠胚胎离体整体心脏电生理活动。我们用微电极矩阵记录与60个电极相接触的心肌细胞的电活动(细胞外记录),称为场电位(field potentials,FPs),并与全细胞膜片钳记录的动作电位(action potentials,APs)(细胞内记录)进行比较,发现心房、心室处场电位形态类似于负向的细胞动作电位,场电位时程亦与动作电位时程类似。为研究兴奋的传导,我们比较了不同电极处场电位发生时间,发现在房室结构还未形成的胚胎发育第9．5天(E9．5)已经观察到明显的房室传导延迟(A-V delay)[(50．21±9．7)ms],而心室不同部位兴奋几乎是同步的。在发育晚期(E16．5),房室传导延迟为(82．21±10．50)ms。进一步研究基本的神经体液因素对心脏兴奋的调控,表明: 在E9．5,异丙肾上腺素(isoproterenol,Iso)使胚胎兴奋频率加快(34．04±7．31)％,房室传导延迟缩短(20．00±6．44)％,同时场电位时程增宽;相反,卡巴唑(carbachol,CCh)则使兴奋频率降低(42．32±5．36)％,房室传导缩短(26．00±4．81)％, 场电位时程减小。而在E16．5,Iso的作用显著增强,兴奋频率加快(101．54±10．23)％,房室传导延迟缩短(56．62±6．43)％, 而CCh则几乎使所有晚期心脏兴奋完全消失。所以,心脏的传导系统在胚胎发育早期4个腔室还未形成时已经建立,神经体液因子对心脏基本电生理活动的调控是在发育过程中逐渐成熟的。     

Differential effects of culture media on normal and foreign differentiation pathways followed by chick embryo neuroretinal cells in vitro

Three different culture media, Ham's F-12, medium 199, and Eagle's minimal essential medium (MEM), were compared with respect to the expression of neuronal (choline acetyl transferase activity: CAT) and glial (hydrocortisone-induced glutamine synthetase activity; GSase) markers of normal differentiation in cultures of 9-day chick embryo neuroretinal cells, and also with respect to the accumulation of a lens marker (delta crystallin) during so-called 'transdifferentiation' in these cultures. MEM allows transient expression of both CAT and GSase activities in early cultures, but also permits extensive delta crystallin accumulation at later stages. F-12 medium gives somewhat higher levels of CAT and GSase activities, the former being noticeably prolonged as compared with parallel MEM cultures; delta crystallin accumulation, however, is largely inhibited in F-12 cultures. By contrast, medium 199 permits only low levels of CAT and GSase activities, perhaps because the neuronal cells are distributed individually over the glial cell sheet in 199 cultures, rather than forming aggregates as in MEM or F-12 cultures. Medium 199 also blocks delta crystallin accumulation. The results of medium changeover between 'transdifferentiation'-permissive (MEM) and non-permissive (199, F-12) conditions suggest: (a) that potential lens precursor cells (whatever their nature) survive in F-12 medium for prolonged periods without extensive expression of the lens phenotype; (b) that such precursor cells become committed to subsequent differentiation as lens cells between 10 and 20 days of culture in permissive MEM medium (as judged by the accumulation of delta crystallin following transfer into F-12); and (c) that medium 199 can block expression of the lens phenotype even in cells already committed (by the above criteria) to lens differentiation, as for instance after 30 days of preculture in MEM.     

Monolayer co-culture of rat heart cells and bovine adrenal chromaffin paraneurons

Summary This paper describes a method for the preparation of co-cultures of rat heart cells and bovine adrenal chromaffin paraneurons. The most suitable condition for heart cell isolation was when a combination of paraneurons. The most suitable condition for heart cell isolation was when a combination of trypsin-DNAse I in Locke's solution was used for digestion. The best co-culture conditions were obtained when 10⁶ heart cells were plated on 7- to 8-d-old adrenal chromaffin paraneuron cultures containing 0.5×10⁶ cells per 35-mm diameter culture dishes. Measurements of DNA (heart cells and chromaffin paraneurons), monitoring of beating frequency (heart cells), and catecholamine (chromaffin paraneurons) levels and release indicated that both cell types remain viable and functional, for several weeks. Heart cells started their characteristic contractile activity 24 h earlier when plated either on viable or lysed chromaffin paraneurons, an effect apparently due to faster surface adhesion of heart cells. The beating frequency of heart cells increased after treatment of co-cultures with either noradrenaline or nicotine, with the latter agent acting indirectly through, the release of chromaffin paraneuron catecholamines. Propranolol produced a dose-related inhibition of the responses to either noradrenaline or nicotine, thus suggesting that the increase in myocyte's beating activity was mediated through β-receptors. Anti-myosin and anti-dopamine-β-hydroxylase immunostaining was used for cell type identification and for the demonstration of body-to-body and process-to-process contacts between adrenal chromaffin paraneurons and heart cells. This co-culture system will serve as a starting point of further studies directed to understand a) the influence of a cell type on the development and on the phenotypic characteristics of a second cell type and b) the interaction of cells derived from different organs and species. This study was supported by grant PG-20 from Medical Research Council of Canada and a grant from the Ontario Heart and Stroke Foundation. M. L. N. is a postdoctoral fellow of the MRC.     

Studies of in vitro cultivated cells from the smooth muscle organs. 3. Effectiveness of some drugs on pulsation frequency of isolated smooth muscle cells of the chicken amnion]

The effects of some drugs on the beating frequency of isolated cells of the chick amnion cultivated on cover slips were investigated. Cholinergic and adrenergic agonists and antagonists, serotonine, antispasmodics, coronary dilatants and local anesthetics influenced the beating frequency significantly. The isolated chick amnion cells equal in their pharmacological behaviour the intact chick amnion and smooth muscle cells of mammals but differ from isolated beating heart cells.     

Differential effects of culture media on normal and foreign differentiation pathways followed by chick embryo neuroretinal cells in vitro

Abstract. Three different culture media, Ham's F-12, medium 199, and Eagle's minimal essential medium (MEM), were compared with respect to the expression of neuronal (choline acetyl transferase activity: CAT) and glial (hydrocortisone-induced glutamine synthetase activity; GSase) markers of normal differentiation in cultures of 9-day chick embryo neuroretinal cells, and also with respect to the accumulation of a lens marker (δ crystallin) during so-called 'transdifferentiation' in these cultures.
MEM allows transient expression of both CAT and GSase activities in early cultures, but also permits extensive δ crystallin accumulation at later stages. F-12 medium gives somewhat higher levels of CAT and GSase activities, the former being noticeably prolonged as compared with parallel MEM cultures; δ crystallin accumulation, however, is largely inhibited in F-12 cultures. By contrast, medium 199 permits only low levels of CAT and GSase activities, perhaps because the neuronal cells are distributed individually over the glial cell sheet in 199 cultures, rather than forming aggregates as in MEM or F–12 cultures. Medium 199 also blocks δ crystallin accumulation.
The results of medium changeover between 'transdifferentiation'-permissive (MEM) and non-permissive (199, F-12) conditions suggest: (a) that potential lens precursor cells (whatever their nature) survive in F-12 medium for prolonged periods without extensive expression of the lens phenotype; (b) that such precursor cells become committed to subsequent differentiation as lens cells between 10 and 20 days of culture in permissive MEM medium (as judged by the accumulation of δ crystallin following transfer into F-12); and (c) that medium 199 can block expression of the lens phenotype even in cells already committed (by the above criteria) to lens differentiation, as for instance after 30 days of preculture in MEM.     

Hemodynamics-driven mathematical model of first and second heart sound generation

We propose a novel, two-degree of freedom mathematical model of mechanical vibrations of the heart that generates heart sounds in CircAdapt, a complete real-time model of the cardiovascular system. Heart sounds during rest, exercise, biventricular (BiVHF), left ventricular (LVHF) and right ventricular heart failure (RVHF) were simulated to examine model functionality in various conditions. Simulated and experimental heart sound components showed both qualitative and quantitative agreements in terms of heart sound morphology, frequency, and timing. Rate of left ventricular pressure (LV dp/dt_max) and first heart sound (S1) amplitude were proportional with exercise level. The relation of the second heart sound (S2) amplitude with exercise level was less significant. BiVHF resulted in amplitude reduction of S1. LVHF resulted in reverse splitting of S2 and an amplitude reduction of only the left-sided heart sound components, whereas RVHF resulted in a prolonged splitting of S2 and only a mild amplitude reduction of the right-sided heart sound components. In conclusion, our hemodynamics-driven mathematical model provides fast and realistic simulations of heart sounds under various conditions and may be helpful to find new indicators for diagnosis and prognosis of cardiac diseases.New & noteworthyTo the best of our knowledge, this is the first hemodynamic-based heart sound generation model embedded in a complete real-time computational model of the cardiovascular system. Simulated heart sounds are similar to experimental and clinical measurements, both quantitatively and qualitatively. Our model can be used to investigate the relationships between heart sound acoustic features and hemodynamic factors/anatomical parameters.     

Electrophysiological studies on embryonic heart cells in culture. Scorpion toxin as a tool to reveal latent fast sodium channel

Trypsin-dispersed heart cells were obtained from 11-day-old chick embryos. After culture as unstirred suspensions in dimethylsulfoxide-containing medium, spherical aggregates of cells beating spontaneously and apparently synchronously for months were obtained. Two kinds of cell were characterized by electrophysiological recordings: (1) cells with a slow rate of depolarizing phase showing tetrodotoxin-resistant action potential and blocked by D 600 (‘slow’ cells); (2) cells with high value of rising phase which was strongly decreased by tetrodotoxin and in which D 600 provoked uncoupling of excitation-contraction (‘fast’ cells).Toxin II from Androctonus australis scorpion venom increased the duration of action potential, which was ascribed to a slowing down of Na⁺ current inactivation and enhance the maximum rate of depolarization, especially in slow cells. Effects were antagonized by tetrodotoxin in both fast and slow cells. Washing experiments confirmed the results of previous studies, namely that tetrodotoxin and scorpion toxin bind to different receptors. It is concluded that slow cells with tetrodotoxin-resistant action potential contain latent fast Na⁺ channels that are revealed (activated) by toxin binding to the membrane.