Viscoelastic properties of isolated rat colon smooth muscle cells

The measurement of the biomechanical properties of gastrointestinal smooth muscle cells is important for the basic understanding of digestive function and the interaction of muscle cells with the matrix. Externally applied forces will deform the cells depending upon their mechanical properties. Hence, the evoked response mediated through stretch-sensitive ion-channels in the smooth muscle cell membrane will depend upon membrane properties and the magnitude of the external force. The aim of this study was to test the hypothesis that gastrointestinal smooth muscle cells behave in a viscoelastic manner. Smooth muscle cells were dissociated from the muscle layers of the descending colon. The viscoelastic properties of the isolated cells were characterized by measuring the mechanical deflection response of the cell membrane to a negative pressure of 1cm H(2)O applied across the cell through a micropipette and fitting the response to a theoretical viscoelastic solid model. The viscoelastic mechanical constants of the isolated cells (N=9) were found to be as follows: k(1)=19.99+/-2.86 Pa, k(2)=7.19+/-1.21 Pa, mu=25.36+/-6.14 Pas and tau=4.84+/-0.95 s. This study represents, to the best of our knowledge, the first quantitative mechanical properties of isolated living smooth muscle cells from the gastrointestinal tract. The mechanical properties determined in this study will be of use in future analytical and numerical smooth muscle cell models to better predict the mechanism between the magnitude of mechanical stimuli, mechanosensitivity and the evoked afferent responses.     

Role of substance P in post-tetanic potentiation in myenteric plexus-longitudinal muscle preparations; the effect of substance P-antagonist

A role of substance P in post-tetanic potentiation in the myenteric plexus-longitudinal muscle preparation of the guinea-pig ileum was investigated by means of substance P-antagonist, (D-Pro2, D-Trp7,9)-substance P. After the addition of substance P-antagonist (10(-7)-10(-5) mol x l-1) a dose-dependent reduction of post-tetanic potentiation of neurogenic twitches was observed. Post-tetanic potentiation was actually abolished in the presence of 10(-5) mol x l-1 substance P-antagonist. It has been shown previously by our group that post-tetanic potentiation is reduced in preparations desensitized by substance P; this, together with our present results supported the hypothesis that the release of substance P-like compounds during tetanic stimulation played a key role in the mechanism of post-tetanic potentiation.     

Effect of a polarizing current on receptor potential of the isolated frog muscle spindle

The effect of a polarizing current on electrical activity of the isolated frog muscle spindle was studied. A depolarizing current increased the frequency and reduced the amplitude of afferent spike activity, both spontaneous and evoked by mechanical stimulation. A hyperpolarizing current produced the opposite effect. The amplitude of the receptor potential in response to a mechanical stimulus varied as a linear function of the intensity of the polarizing currentA. A. Ukhtomskii Physiological Institute, Leningrad State University. Translated from Neirofiziologiya, Vol. 5, No. 1, pp. 95–101, January–February, 1973.     

Stretch-reflex mechanical response to varying types of previous muscle activities.

This study was designed to examine the effects of varying types of background muscle activity on the stretch-reflex mechanical response. A rapid stretch was applied to the calf muscles after an isometric (pre-ISO), shortening (pre-SHO) and lengthening contraction (pre-LEN) with several pre-contraction levels, respectively. The stretch perturbation was applied with the tibio-tarsal joint angle at 90 degrees. The ankle joint torque elicited by the stretch showed a first peak (non-reflex torque: NRT), a transient drop and a second peak (reflex torque: RT). The muscle activities before the stretch clearly influenced the stretch-reflex mechanical response. The NRT reached the largest peak with the longest duration in pre-ISO. The peak NRT increased with the pre-contraction level in pre-ISO and pre-LEN, whereas it remained unchanged in pre-SHO. The RT responded to the stretch-reflex EMG response most quickly and reached the largest peak in pre-ISO. Pre-ISO generated the mechanical response most efficiently against the size of the stretch-reflex EMG response. Pre-SHO showed lower peak RT than pre-ISO in spite of the similar size of stretch-reflex EMG response. The peak RT was closely related to the peak NRT in all conditions. Consequently, the peak RT also increased with the pre-contraction level in pre-ISO and pre-LEN, whereas it remained unchanged in pre-SHO. In conclusion, a stretch after an isometric contraction evoked a larger stretch-reflex mechanical response more efficiently than that after phasic contractions when a given effort was being maintained.     

Contribution of muscle short-range stiffness to initial changes in joint kinetics and kinematics during perturbations to standing balance: A simulation study

Simulating realistic musculoskeletal dynamics is critical to understanding neural control of muscle activity evoked in sensorimotor feedback responses that have inherent neural transmission delays. Thus, the initial mechanical response of muscles to perturbations in the absence of any change in muscle activity determines which corrective neural responses are required to stabilize body posture. Muscle short-range stiffness, a history-dependent property of muscle that causes a rapid and transient rise in muscle force upon stretch, likely affects musculoskeletal dynamics in the initial mechanical response to perturbations. Here we identified the contributions of short-range stiffness to joint torques and angles in the initial mechanical response to support surface translations using dynamic simulation. We developed a dynamic model of muscle short-range stiffness to augment a Hill-type muscle model. Our simulations show that short-range stiffness can provide stability against external perturbations during the neuromechanical response delay. Assuming constant muscle activation during the initial mechanical response, including muscle short-range stiffness was necessary to account for the rapid rise in experimental sagittal plane knee and hip joint torques that occurs simultaneously with very small changes in joint angles and reduced root mean square errors between simulated and experimental torques by 56% and 47%, respectively. Moreover, forward simulations lacking short-range stiffness produced unreasonably large joint angle changes during the initial response. Using muscle models accounting for short-range stiffness along with other aspects of history-dependent muscle dynamics may be important to advance our ability to simulate inherently unstable human movements based on principles of neural control and biomechanics.     

Effects of caffeine on the electrical and mechanical activity of guinea-pig ureter smooth muscle

The effects of caffeine on the electrical and mechanical activity of the guinea-pig ureter smooth muscle were studied. Under untreated conditions caffeine mainly showed inhibitory action on the ureter, inhibiting the evoked action potentials and phasic contractions as well as potassium contracture. Caffeine was also found to suppress the low-Na contracture of Na-loaded ureter muscle. It is established that Na-loaded tissue is able to generate transient contracture in response to caffeine application at 37 degrees C. These caffeine contractures could be evoked under completely removed [Ca2+]0 and in the presence of high doses of Ca-channel blockers (nifedipine, diltiazem, Mn ions) and could be reversibly blocked by tetracaine, procaine and benzocaine. Caffeine contractures could also be produced by the ureter muscle placed in isotonic K-solution. Cooling significantly potentiated low-Na, potassium and caffeine contractures of the ureter muscle. Filling of the store is totally dependent on the entry of Ca ions from the extracellular Ca2+ store sites which sequester Ca ions entering the cell on either Na-Ca exchange or via voltage operated Ca channels.     

Anisotropic effects of the levator ani muscle during childbirth

Pelvic floor dysfunction and pelvic organ prolapse have been associated with damage to the levator ani (LA) muscle, but the exact mechanisms linking them remain unknown. It has been postulated that factors such as vaginal birth and ageing may contribute to long-term, irreversible LA muscle damage. To investigate the biomechanical significance of the LA muscle during childbirth, researchers and clinicians have used finite element models to simulate the second stage of labour. One of the challenges is to represent the anisotropic mechanical response of the LA muscle. In this study, we investigated the effects of anisotropy by varying the relative stiffness between the fibre and the matrix components, whilst maintaining the same overall stress–strain response in the fibre direction. A foetal skull was passed through two pelvic floor models, which incorporated the LA muscle with different anisotropy ratios. Results showed a substantial decrease in the magnitude of the force required for delivery as the fibre anisotropy was increased. The anisotropy ratio markedly affected the mechanical response of the LA muscle during a simulated vaginal delivery. It is apparent that we need to obtain experimental data on muscle mechanics in order to better approximate the LA muscle mechanical properties for quantitative analysis. These models may advance our understanding of the injury mechanisms of pelvic floor during childbirth.     

Muscle dynamics: Dependence of muscle length on changes in external load

A phenomenological theory of muscle dynamics has been elaborated on the basis of data obtained in experiments on hind limb extensor muscles of narcotized cat. Functional dependence of muscle length on external load was explored in conditions of a constant frequency of the efferent stimulation. It was shown that the system under study could be presented for a rather wide class of input signals as a system with nonlinear statics and linear dynamics. The nonlinear statics was shown to be determined mainly by the hysteretical effects of muscle contraction, whereas dynamic element was described by the first order linear differential equation corresponding to the traditional three-component mechanical model of the muscle. A hypothesis was proposed to explain the hysteresis in active muscle on the basis of functioning of the troponin-tropomyosin regulatory complex. Elaborated mathematical model of muscle dynamics can be used to predict and evaluate changes in the muscle length evoked by arbitrary changes in the external load.     

Action of FMRFamide on longitudinal muscle of the leech,Hirudo medicinalis

1. Nerve terminals associated with longitudinal muscle in the leech show FMRFamide-like immunoreactivity. 2. Structure-activity studies using FMRFamide analogs show that the C-terminal RFamide portion of the molecule is crucial for biological activity on leech longitudinal muscle. 3. The putative protease inhibitor FA (Phe-Ala) increases the peak tension produced by longitudinal muscle in response to superfused FMRFamide and the majority of its analogs, suggesting the presence of peripheral proteases capable of degrading RFamide peptides. 4. FMRFamide decreases the relaxation rate of neurally evoked contractions of longitudinal muscle. FA also decreases the relaxation rate of neurally evoked contractions. 5. Intact and isolated muscle cells respond to superfused FMRFamide with a conductance increase, that leads to depolarization and often with a delayed conductance decrease as the membrane potential is restored to resting levels. 6. The depolarizing response of isolated muscle cells to FMRFamide is dependent on external calcium.     

Mechanical and electrophysiological effects of isoprostanes on bronchial arterial smooth muscle

We investigated the mechanical and electrophysiological responses of human and porcine bronchial arterial smooth muscle to isoprostanes (metabolites of membrane lipid peroxidation). These evoked a constrictor response which was sensitive to blockade of thromboxane receptors, as well as to a non-specific tyrosine kinase inhibitor and an inhibitor of Rho-kinase. The patch clamp technique was used to characterize the K+ and Ca2+ currents in these tissues, and to show that isoprostanes caused a brief enhancement of K+ currents followed by prolonged and marked suppression of the same.     

The effects of H2O2 on electromechanical activity of the ileum longitudinal muscle

The effects of H2O2 on electrical and mechanical activity of the longitudinal layer from the guinea-pig ileum were studied using sucrose-gap technique and the influence of H2O2 on ionic current was investigated in single smooth muscle cells by the patch-clamp method. In most of the preparations tested, the spontaneous activity observed was composed of slow waves with superimposed action potentials (APs). Both were resistant to tetrodotoxin and atropine. H2O2 (1 mmol/l) evoked sustained 3-5 mV membrane depolarisation, doubled the amplitude of the slow waves and increased their frequency, augmented the APs and reduced their splitting. These changes were accompanied with significant contraction, which had an amplitude comparable to that of the tonic component of 50 mmol/l K+-induced contraction. Calcium-free solution caused membrane depolarisation, reduction of the slow wave amplitude and frequency, disappearance of APs and decreased the mechanical tension of the preparations. Application of H2O2 (1 mmol/l) into the zero-calcium bath solution recovered the APs, which was accompanied by a low amplitude contraction. H2O2 (up to 1 mmol/l) increased the L-type calcium current (I(Ca)) both under conventional whole-cell patch-clamp configuration and under amphotericin-perforated patches by 16 +/- 3%. These data demonstrated that contractile response of the ileum longitudinal smooth muscle preparation evoked by H2O2 was mainly due to the enhanced electrical activity.     

Mechanical properties of a slow muscle in the cockroach

The mechanical properties of the metacoxal muscle, 177d, in the cockroach, Periplaneta americana, was investigated. The muscle exhibited a mean resting tension of 2.6 ± 1.3g SD. Neurally evoked tension summed with the resting tension and the relaxation phase of the evoked tension varied from less than 1 s to several minutes. This residual tension varied not only in duration but also in amplitude. Stimulation of inhibitory axons increased the rate of relaxation and thereby abolished the residual tension. However, inhibitory stimulation never reduced the resting tension. Stimulation of the main leg nerve at several times the threshold of the inhibitory axons could evoke residual tension. Recording of synaptic potentials from the two histochemically different fiber types (dorsal and ventral groups) revealed large hyperpolarizations in the ventral fibers and decreased duration and amplitude of excitatory potentials in the dorsal fibers. These results suggest that there are a variety of ways in which tension can be evoked, maintained, and controlled in these muscles.     

Synaptic potentials of motoneurons of the masseter muscle

Postsynaptic potentials of 93 motoneurons of the masseter muscle evoked by stimulation of different branches of the trigeminal nerve were studied. Stimulation of the most excitable afferent fibers of the motor nerve of the masseter muscle evoked monosynaptic EPSPs with a latent period of 1.2–2.0 msec, changing into action potentials when the strength of stimulation was increased. A further increase in the strength of stimulation produced an antidromic action potential in the motoneurons with a latent period of 0.9 msec. In some motoneurons polysynaptic EPSPs and action potentials developed following stimulation of the motor nerve to the masseter muscle. The ascending phase of synaptic and antidromic action potentials was subdivided into IS and SD components, while the descending phase ended with definite depolarization and hyperpolarization after-potentials. Stimulation of cutaneous branches of the trigeminal nerve, and also of the motor nerve of the antagonist muscle (digastric) evoked IPSPs with a latent period of 2.7–3.5 msec in motoneurons of the masseter muscle. These results indicate the existence of functional connections between motoneurons of the masseter muscle and its proprioceptive afferent fibers, and also with proprioceptive afferent fibers of the antagonist muscle and cutaneous afferent fibers.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 1, No. 3, pp. 262–268, November–December, 1969.     

Nitrendipine blocks high potassium contractures but not twitches in rat skeletal muscle

The effects of the organic calcium channel blocker nitrendipine was tested on electrically evoked twitches and on potassium depolarization-induced contractures of rat lumbricalis muscles. Nitrendipine (10(-7) to 5 X 10(-5) M) blocked only the potassium contractures. It was concluded that blocking calcium uptake through the slow voltage-sensitive calcium channels during potassium depolarization blocks the mechanical response of the muscle. Thus extracellular calcium ions are required for the excitation-contraction (E-C) coupling during depolarization contractures. On the other hand, electrically evoked twitches were not affected by nitrendipine; therefore, extracellular calcium ions entering via the slow voltage-sensitive channels are not required for E-C coupling during the twitch.     

Model of the firing frequency of the chelonian muscle spindle

A model is proposed for the frequency of firing of the chelonian muscle spindle in response to mechanical stretches. First an attempt is made to fit the response to a first and second order model and, after incorporating the encoding properties of the spindle, a simulation is obtained which predicts in terms of the instantaneous frequency of firing the response of the spindle to ramp and sinusoidal mechanical stretches.     

Vasomotor control in arterioles of the mouse cremaster muscle.

Recent advances in transgenic mouse technology provide novel models to study cardiovascular physiology and pathophysiology. In light of these developments, there is an increasing need for understanding cardiovascular function and blood flow control in normal mice. To this end we have used intravital microscopy to investigate vasomotor control in arterioles of the superfused cremaster muscle preparation of anesthetized C57Bl6 mice. Spontaneous resting tone increased with branch order and was enhanced by oxygen. Norepinephrine and acetylcholine (ACh) caused concentration-dependent vasoconstriction and vasodilation, respectively. Microiontophoresis of ACh evoked vasodilation that conducted along arterioles; the local (direct) response was inhibited by N(omega)-nitro-L-arginine (LNA), and both local and conducted responses were inhibited by 17-octadecynoic acid (17-ODYA). Microejection of KCl evoked a biphasic response: a transient conducted vasoconstriction (inhibited by nifedipine), followed by a conducted vasodilation that was insensitive to LNA, indomethacin, and 17-ODYA. Phenylephrine evoked focal vasoconstriction that did not conduct. Perivascular sympathetic nerve stimulation evoked constriction along arterioles that was inhibited by tetrodotoxin. These findings indicate that for arterioles in the mouse cremaster muscle, nitric oxide and endothelial-derived hyperpolarizing factor (as shown by LNA and 17-ODYA interventions, respectively) mediate vasodilatory responses to ACh but not to KCl, and that vasomotor responses spread along arterioles by multiple pathways of cell-to-cell communication.     

Regulation of the ubiquitin proteasome system in mechanically injured human skeletal muscle

Metabolic consequences of direct muscle trauma are insufficiently defined. Their effects on the ubiquitin-proteasome pathway (UPP) of protein degradation in human skeletal muscles are as yet unknown. Thus, we investigated whether the UPP is involved in the metabolic response evoked in directly traumatized human skeletal muscles. Biopsies were obtained from contused muscles after fractures and from normal muscles during elective implant removal (control). As estimated by western blot analyses, concentrations of free ubiquitin and ubiquitin protein conjugates were similar in extracts from injured and uninjured muscles. Ubiquitin protein ligation rates were reduced after injury (1.5+/-0.2 vs. 1.0+/-0.15 fkat/microg; p=0.04). Chymotryptic-, tryptic- and caspase-like proteasome peptidase activities (total activity minus activity in the presence of proteasome inhibitors) increased significantly after trauma (p=0.04 - 0.001). Significant increases in total chymotryptic- and caspase-like activities were attributable to proteasome activation. Our results extend the possible role of the UPP in muscle wasting to direct muscle trauma. They further suggest that the effects of direct mechanical trauma are not limited to the proteasome and imply that ubiquitin protein ligase systems are also involved. Based on the potential role of the UPP in systemic diseases, it might also be a therapeutic target to influence muscle loss in critically ill blunt trauma patients, in which large proportions of muscle are exposed to direct trauma.     

Testing biological activity of model Maillard reaction products: studies on gastric smooth muscle tissues

Water-soluble Maillard reaction products obtained from five different model systems were investigated for their effects upon the mechanical activity of rat gastric smooth muscle. Most of the total Maillard reaction products applied at concentration of 1.5 mg/ml evoked contractions; among them the product obtained from arginine and glucose (Arg-Glc) produced the most powerful contractions. The product obtained from glycine and ascorbic acid (Gly-AsA) was the only one that brought about relaxation response. The high molecular weight fractions (>3,500 Da) isolated from the reaction systems Arg-Glc and Gly-AsA demonstrated effects similar in type and amplitude to those evoked by non-fractioned reaction products. The results obtained suggest that moieties of molecules acting upon the muscle tonus originate mainly from lysine and arginine residues; that these structures are available in both low and high molecular pools in similar concentrations, and most likely these fragments act upon membrane-located cellular structures involved in calcium transport.     

Length-dependence of isometric twitch tension potentiation and myosin phosphorylation in mouse skeletal muscle

The effect of changes in muscle length on post-tetanic isometric twitch tension potentiation and myosin P-light chain phosphorylation-was studied at 23°C in the mouse extensor digitorum longus muscle. The length-tension relationship was determined for the same muscles after a 30 min period of quiescence and between 30 s and 3 min after a 1.5 s tetanus at L₀. Isometric twitch tension is increased at all muscle lengths after the tetanus; however, the fractional increase in twitch tension rises from 0.2 at L₀ to a maximum of 0.3 at 1.2 L_0. The fractional increase in twitch tension measured at any fixed muscle length is constant between 30 s and 3 min post-tetanus. P-light chain phosphorylation remains constant between 30 s and 3 min post-tetanus followed by a slow decline to basal values. Under fixed length conditions, there is linear relationship between the relative magnitude of the twitch tension and the extent of P-light chain phosphor-ylation. Net myosin phosphorylalion measured after a 1.5 s tetanus at 1.23 L₀ is 35% less than that obtained under the same conditions at L_0. Thus, contraction-induced phosphorylation of P-light chain decreases with increased muscle length and post-tetanic potentiation at a constant level of P-light chain phosphorylation increases with increasing muscle length. These observations may be consistent with alterations in the sarcoplasmic Ca²⁺ ion transient as the muscle is lengthened.