Effects of strophanthin K and beta-acetyldigoxin in vitro on energy transformation of myocardial contractile protein system in toxic-allergic lesions of the cardiac muscle

Strophanthin K and beta-acetyldigoxin in vitro in concentration of 10(-6) M in TAM sharply increased the force generated by isolated myocardial contractile protein system (MCPS), and normalized the work performed by the system. This was accompanied by increase of ATP internal energy release (enthalpy) intensity, while a portion of energy, dissipating into heat did not increase proportionally. The mechanical efficiency of contractile process was normalized due to beta-acetyldigoxin, and exceeded the normal level due to strophanthin K effect. Strophanthin K proved a positive effect on quantitative and qualitative economy of MCPS energy utilization, while beta-acetyldigoxin effected, on the whole, extensively.     

The effects of cytochalasin B on the cytoplasmic contractile network revealed by whole-cell transmission electron microscopy

The ultrastructure of the contractile response to cytochalasin B (CB) has been studied using whole-cell electron microscopy. The actin-containing contractile network rapidly condenses into numerous stellate microfilament foci (SMF). These SMF punctuate the cytoplasm, and are frequently associated with an extensive persistent cytoskeleton containing microtubules and intermediate filaments. This association of SMF and persistent cytoskeleton appears to mediate the arborized morphology induced by CB. Eventually SMF aggregate and migrate towards the nucleus. Concomitantly the cell surface is differentiated into clusters of miniblebs which migrate to the nucleus. SMF loss from the periphery resulted in respreading to a flattened angular morphology within which the nucleus was frequently displaced. The role of the actin network, and the mechanism of these CB-induced contractile alterations are discussed.     

The action of strophanthin K and beta-acetyldigoxin in vitro on the energy transformation by the contractile protein system of the normal cardiomyocyte

It was shown in experiments on myocardial fiber bundles (MGFB) from normal heart that strophantin K and beta-acetildigoxin in vitro in concentration of 10(-6) M sharply increased the value of force generated by contractile protein system and its ability to perform work. In this case strophantin K significantly increased energy transformation efficiency. It was concluded that in myocardial contractile protein system a regulator of qualitative and quantitative energy transformation is functioning (a kind of economizer).     

Effects of strong static magnetic fields used in magnetic resonance imaging on insulin-secreting cells

The magnetic flux density of MRI for clinical diagnosis has been steadily increasing. However, there remains very little biological data regarding the effect of strong static magnetic fields (SMFs) on human health. To evaluate the effects of strong SMFs on biological systems, we cultured insulin-secreting cells under exposure to sham and SMF conditions (3-10 T of magnetic flux density, and 0-41.7 T/m of magnetic field gradient) for 0.5 or 1 h, and analyzed insulin secretion, mRNA expression, glucose-stimulated insulin secretion, insulin content, cell proliferation and cell number. Exposure to SMF with a high magnetic field gradient for 1 h significantly increased insulin secretion and insulin 1 mRNA expression. Exposure to SMF with a high magnetic flux density for 0.5 h significantly enhanced responsiveness to glucose stimulation. Exposure to SMF did not affect the insulin content, cell proliferation or cell number. Our results suggested that MRI systems with a higher magnetic flux density might not cause cell proliferative or functional damages on insulin-secreting cells, and that SMF with a high magnetic field gradient might be used clinically after thorough in vivo investigations are conducted.     

Biologic effects of SMF and paclitaxel on K562 human leukemia cells

In this study, we evaluated the ability of 8.8 mT static magnetic fields (SMF) to enhance the in vitro action of a chemotherapeutic agent, paclitaxel, against K562 human leukemia cells. We analyzed the cell proliferation, cell cycle distribution, DNA damage and alteration of cell surface and cell organelle ultrastructure after K562 cells were exposed to paclitaxel in the presence or absence of 8.8 mT SMF. The results showed that in the presence of SMF, the efficient concentration of paclitaxel on K562 cells was decreased from 50 to 10 ng/ml. Cell cycle analysis indicated that K562 cells treated with SMF plus paclitaxel were arrested at the G2 phase, which was mainly induced by paclitaxel. Through comet assay, we found that the cell cycle arrest effect of paclitaxel with or without SMF on K562 cells was correlated with DNA damage. The results of atomic force microscopy and transmission electron microscopy observation showed that the cell ultrastructure was altered in the group treated with the combination of SMF and paclitaxel, holes and protuberances were observed, and vacuoles in cytoplasm were augmented. Our data indicated that the potency of the combination of SMF and paclitaxel was greater than that of SMF or paclitaxel alone on K562 cells, and these effects were correlated with DNA damage induced by SMF and paclitaxel. Therefore, the alteration of cell membrane permeability may be one important mechanism underlying the effects of SMF and paclitaxel on K562 cells.     

Effect of nifedipine on the contractile function of the rat diaphragm in vitro

The isometric contractile response of the directly-stimulated rat diaphragm was studied before and following addition of the calcium channel blocker, nifedipine. Nifedipine (10 micrograms/ml and 30 micrograms/ml bath concentrations) significantly increased isometric force output during twitch and unfused tetanic stimulation. Force potentiation during unfused tetanic stimulation was equivalent during either high or low voltage stimulation. Nifedipine had no effect on the time to peak force, half relaxation time, or relaxation time during twitch stimulation; thus, both activation and relaxation rates were increased. The force potentiating actions of nifedipine persisted in a calcium-free bathing solution and were enhanced by d-tubocurarine. In contrast to the force enhancing effects found with twitch and unfused tetanic stimulation, nifedipine caused a small but significant reduction in isometric force during maximal fused tetanic stimulation. It is concluded that the force potentiating effects of nifedipine on rat diaphragm are not due to fiber recruitment, enhancement of neuromuscular excitation, or altered inward trans-sarcolemmal calcium flux, but may result from a direct effect of the drug on the rate of activation of the contractile apparatus.     

Effects of a moderate-intensity static magnetic field and adriamycin on K562 cells

The aim of this study was to investigate whether a moderate‐intensity static magnetic field (SMF) can enhance the killing effect of adriamycin (ADM) on K562 cells, and to explore the effects of SMF combined with ADM on K562 cells. We analyzed the metabolic activity of cells, cell cycle distribution, DNA damage, change in cell ultrastructure, and P‐glycoprotein (P‐gp) expression after K562 cells were exposed continuously to a uniform 8.8 mT SMF for 12 h, with or without ADM. Our results showed that the SMF combined with ADM (25 ng/ml) significantly inhibited the metabolic activity of K562 cells (P < 0.05), while neither ADM nor the SMF alone affected the metabolic activity of these cells. Cell ultrastructure was altered in the SMF + ADM group. For example, cell membrane was depressed, some protuberances were observable, and vacuoles in the cytoplasm became larger. Cells were arrested at the G2/M phase and DNA damage increased after cells were treated with the SMF plus ADM. ADM also induced the P‐gp expression. In contrast, in the SMF group and SMF + ADM group, the P‐gp expression was decreased compared with the ADM group. Taken together, our results showed that the 8.8 mT SMF enhanced the cytotoxity potency of ADM on K562 cells, and the decrease in P‐gp expression may be one reason underlying this effect. Bioelectromagnetics 32:191–199, 2011. © 2010 Wiley‐Liss, Inc.     

Effect of strophanthin and digoxin on the activity of an experimental epileptogenic focus in the frog hippocampus

It has been shown on frogs with epileptogenic focus induced by the injection of penicillin (1000 U in 0.4 ml) into the hippocamp that preinjection (or injection on the background of the functioning epileptogenic focus) of strophanthin (1.8 and 0.18 microgram/g) or digoxin (1.2 micrograms/g) into spinal lymphaticus sac led to a sharp increase in interparoxysmal epileptiform discharges and electrographic correlates of fits on the ECG. The influence of cardiac glycosides upon the epileptized cerebral neurons is thought to be associated with the capacity of these drugs to inhibit Na+, K+-ATPase of neurons and their axons resulting in the disturbance of cerebral mediator activity.     

Antagonism of biogenic amine-induced depression of cerebral cortical neurones by Na+, K+-ATPase in inhibitors.

The effects of iontophoretically applied Na+-, K+-dependent adenosinetriphosphatase (Na+,K+-ATPase) (EC 3.6.1.3) inhibitors (ouabain, digitoxin, digitoxigenin, strophanthin K, strophanthidin, thevetin A and B, ethacrynate, and harmaline) on the depression of rat cerebral cortical neurones by noradrenaline, 5-hydroxytryptamine, and histamine have been studied. The inhibitors antagonized depressions of spontaneously active neurones evoked by these amines, but not those evoked by gamma-aminobutyric acid, adenosine, adenosine 5'-monophosphate, or calcium. The antagonistic potencies of the various inhibitors appeared to be proportional to their known potencies as inhibitors of Na+, K+-ATPase. The data therefore support the hypothesis that amines depress central neurones by activating an electrogenic sodium pump.     

Assessment of the cyto- and genotoxic effects of a nanoferromagnetic and a static magnetic field in vivo

The cyto- and genotoxic effects of ferromagnetic nanoparticles (FNs), a static magnetic field (SMF), or their combination were comparatively studied in Ehrlich ascites carcinoma (EAC) cells, bone marrow (BM) erythroid series cells, and peripheral blood lymphocytes at definite time intervals, using the MN test and the DNA-comet assay. The MN test and the DNA-comet assay were used as markers of genotoxic exposure. It has been shown that the limit value of insignificantly expressed changes in the EAC cell architectonics (due to FNs) is an FN concentration of 3 mg/kg. The FN concentration increases in tumor cells, because the expressed blebbing in the cytoplasmic membrane increases the amount of micronuclei and the percentage of DNA in the comet tail in EAC cells, BM erythroid series cells, and peripheral blood lymphocytes. It has also been demonstrated that an SMF alone, as an independent factor, does not produce cytogenotoxic effects on the studied cells. When SMF and FN were used in combination, we could observe the phenomenon of SMF induction by FNs, which manifested itself as an increased total effect of these factors on cells. The MN-test and the DNA-comet assay can be used for assessing the genomic stability of both tumor cells and somatic nonmalignized cells when testing the genotoxic effect of nanomaterials used in the design of vector systems. As was established, the DNA-comet method demonstrated a higher sensitivity in the assessment of the genotoxicity produced by the studied factors.     

SNAIL NEURON BIOELECTRIC ACTIVITY INDUCED UNDER STATIC OR SINUSOIDAL MAGNETIC FIELDS REPRODUCES MAMMAL NEURON RESPONSES UNDER TRANSCRANIAL MAGNETIC STIMULATION

We have applied static (SMF) or alternating magnetic fields (AMF) to snail (Helix aspersa) single-unit neurons, in the range of those applied in magnetic stimulation (MS)/transcranial magnetic stimulation (TMS). From the experiments we have performed during the past 10 years, we have collected a blind selection of neurons and their responses to either SMF or AMF. Blind selection means that we do not know the nature of neurons. We do not know whether they are sensitive, motor, secretory, pacemaker, or inter-neurons. We have seen that the behavior of single-unit neurons under SMF/AMF exposure (SMF range: 3 mT–0.7 T; AMF range: 1–15 mT) fits well with the electrophysiologic activity described for mammals and human whole brain under MS/TMS (pulsed magnetic field range: 0.3 mT–2.4 T). The neuron experiments shown here have been aleatorily selected from a collection of about 200 neurons studied. Our results could explain some of the effects described induced in mammal neurons under MS/TMS for clinical purposes.     

Fatigue of isolated rat diaphragm: role of impaired neuromuscular transmission

We compared the contributions of impaired neuromuscular transmission (transmission fatigue) and impaired muscle contractility (contractile fatigue) to fatigue of the isolated rat diaphragm. To make this comparison, we measured the differences in active tension elicited by direct muscle stimulation and by indirect (phrenic nerve) stimulation before and after fatigue induced by indirect supramaximal stimulation at varying frequencies and durations. Transmission fatigue was observed after all experimental protocols. Although significant contractile fatigue was not demonstrated after brief periods of low-frequency stimulation (6 min, 15 Hz, 25% duty cycle), it was present after longer or higher frequency stimulation. We repeated the direct stimulation in the presence of neuromuscular blockade with 6 microM d-tubocurarine to demonstrate that a reduced response to stimulation of intramuscular branches of the phrenic nerve during direct stimulation was not responsible for the apparent contractile fatigue. Since we found significant decreases in the response to direct stimulation even after neuromuscular blockade, we could verify the presence of contractile fatigue. We conclude that both contractile and transmission fatigue can occur in the isolated rat diaphragm and that transmission fatigue is a much more important factor after brief periods of fatiguing contractions.     

Effects of marinobufagenin on electrophysiological and contractile characteristics of the rat diaphragm

Effects of Na+,K(+)-ATPase inhibitor: marinobufagenin, on contractile and electric characteristics of isolated rat diaphragm were studied for the first time. Marinobufagenin induced dose-dependent (EC50 = 0.3 +/- 0.1 nM) increase in the contraction force (positive inotropic effect). At 1-2 nM, it slowed down the fatigue induced by continuous direct stimulation (2/s) of the muscle. Marinobufagenin at the same concentrations did not affect resting membrane potential or parameters of action potentials of muscle fibers, while at 10 and 20 nM it induced hyperpolarization by approximately 2 mV. Marinobufagenin blocked dose-dependently (IC50 = 2.9 +/- 2.0 nM) hyperpolarizing effect of acetylcholine (100 nM) mediated by increase in electrogenic contribution of alpha2 isoform of the Na+,K(+)-ATPase. This result suggests a capability of marinobufagenin to inhibit this isoform of the Na+,K(+)-ATPase. Possible mechanisms of marinobufagenin effects in skeletal muscle are discussed.     

Direct effect of complement factor C5a on the contractile state of isolated smooth muscle cells

The complement-(C) derived factor C5a has long been recognized as a potent contractile agonist in smooth muscle (1,2); however, controversy remains as to whether the effects of this anaphylatoxin are direct or secondary to the release of histamine (3) and/or other mediators (4-8) from nonmuscle cells within the tissue. To resolve this controversy, we have assessed the contractile effects of purified human C5a and C5a des Arg in a homogeneous preparation of enzymatically dispersed smooth muscle cells derived from the stomach of the toad, Bufo marinus. This preparation, which is insensitive to histamine at concentrations as high as 10(-4) M, responds normally to a variety of electrical (9), mechanical (10), and pharmacologic (11, 12) stimuli. These smooth muscle cells also respond to purified human anaphylatoxin; exposure to the cells to purified human C5a or C5a des Arg produce contractions of the smooth muscle cells that are accompanied by increased Ca2+ influx. The contractile response was unaffected by antagonists to histamine or acetylcholine but was reduced by 30% by pretreatment with the leukotriene antagonist FPL55712. A direct contractile effect of C5a on amphibian smooth muscle cells is suggested.     

Evidence for a role of prostaglandins in atropine-resistant transmission in the mammalian urinary bladder

It has been known for many years that atropine and other anti-cholinergic drugs readily inhibit the contractile responses of the detrusor portion of the mammalian urinary bladder to exogenous acetylcholine, but only partially inhibit responses to nerve or transmural stimulation (1,2). These findings suggest that the excitatory innervation to the bladder consists not only of cholinergic nerves but also of non-cholinergic nerves. The possibility that such a second excitatory transmitter could be a catecholamine, 5-hydroxytryptamine, bradykinin or histamine has not been supported by experimentation (2). Burnstock, Dumsday and Smythe (3) have presented evidence that ATP might be the second transmitter in the bladder. In the present study we are investigating the role, if any, of prostaglandins in the non-cholinergic responses of urinary bladder to transmural stimulation. For this purpose, we have studied the effects of indomethacin, an inhibitor of prostaglandin synthesis, on responses to transmural stimulation.     

Stable hydrogel adhesion to polydimethylsiloxane enables cyclic mechanical stimulation of 3D-bioprinted smooth muscle constructs

During normal urination, smooth muscle cells (SMCs) in the lower urinary tract (LUT) are exposed to mechanical signals that have a critical impact on tissue structure and function. Nevertheless, the mechanisms underlying the maintenance of the contractile phenotype of SMCs remain poorly understood. This is due, in part, to a lack of studies that have examined the effects of mechanical loading using three-dimensional (3D) models. In this study, surface modifications of polydimethylsiloxane (PDMS) membrane were evaluated to investigate the effects of cyclic mechanical stimulation on SMC maturation in 3D constructs. Commercially available cell stretching plates were modified with amino or methacrylate groups to promote adhesion of 3D constructs fabricated by bioprinting. After 6 days of stimulation, the effects of mechanical stimulation on the expression of contractile markers at the mRNA and protein levels were analyzed. Methacrylate-modified surfaces supported stable adhesion of the 3D constructs to the membrane and facilitated cyclic mechanical stimulation, which significantly increased the expression of contractile markers at the mRNA and protein levels. These effects were found to be mediated by activation of the p38 MAPK pathway, as inhibition of this pathway abolished the effects of stimulation in a dose-dependent manner. These results provide valuable insights into the role of mechanical signaling in maintaining the contractile phenotype of bladder SMCs, which has important implications for the development of future treatments for LUT diseases.     

Age-dependent magnetosensitivity of heart muscle hydration

The reason for hyper magnetosensitivity of young animals compared to older ones remains unclear. It has been suggested that age-induced tissue dehydration (decreased water content) could be a basis for the aging-related decrease in the organism's magnetosensitivity. To test this hypothesis, the effect of a 0.2 T static magnetic field (SMF) exposure on heart muscle hydration in three age groups of rats (young, adult, and older) was studied, with and without ouabain poisoning. The SMF exposure resulted in heart muscle dehydration of young (21%) and adult (6.2%) rats but had no effect on older animals. In young animals without ouabin poisoning, SMF exposure caused dehydration of the heart muscle while in the ouabain-poisoned animals it led to hydration (29.6%). These hydration effects were more pronounced in young animals than in adult and older animals. The increased hydration (5.7%) of heart muscles in older animals was evoked by providing distilled water for seven days, which elevated (by 12%) the SMF-induced heart muscle hydration effect. These results suggest that the hyper magnetosensitivity of the young heart muscle and the lower sensitivity of older animals are due to initial high (83.5%) and low (75.3%) tissue hydration levels, respectively. Therefore, the age-induced decrease in the magnetosensitivity of heart muscle is likely to be a result of Na(+)/K(+) pump dysfunction.     

The Influence of a gradient static magnetic field on an unstirred Belousov-Zhabotinsky reaction

It is believed that static magnetic fields (SMF) cannot affect the pattern formation of the Belousov-Zhabotinsky (BZ) reaction, which has been frequently studied as a simplified experimental model of a nonequilibrium open system, because SMF produces no induced current and the magnetic force of SMF far below 1 T is too low to expect the effects on electrons in the BZ reaction. In the present study, we examined whether the velocity of chemical waves in the unstirred BZ reaction can be affected by a moderate-intensity SMF exposure depending on the spatial magnetic gradient. The SMF was generated by a parallel pair of attracting rectangular NdFeB magnets positioned opposite each other. The respective maximum values of magnetic flux density (B(max)), magnetic flux gradient (G(max)), and the magnetic force product of the magnetic flux density its gradient (a magnetic force parameter) were 206 mT, 37 mT/mm, and 3,000 mT(2)/mm. The ferroin-catalyzed BZ medium was exposed to the SMF for up to 16 min at 25 degrees C. The experiments demonstrated that the wave velocity was significantly accelerated primarily by the magnetic gradient. The propagation of the fastest wave front indicated a sigmoid increase along the peak magnetic gradient line, but not along the peak magnetic force product line. The underlying mechanisms of the SMF effects on the anomalous wave propagation could be attributed primarily to the increased concentration gradient of the paramagnetic iron ion complexes at the chemical wave fronts induced by the magnetic gradient.