Propagation of shear waves in the muscle tissue

A mathematical model of the propagation of acoustic shear waves in muscle tissue is considered. The muscle is modelled by an incompressible transversely isotropic viscoelastic continuum with quasi-one-dimensional active tension. Two types of shear waves in an infinite medium have been established. The waves of the second type (transverse) propagate without attenuation even when myofibril viscosity is taken into account. A problem of standing transverse waves in a rectangular layer has been investigated numerically. The values of the problem parameters have been found for which the active tension or muscle tonus is easily estimated from the characteristics of standing waves. This value is informative for the diagnosis of muscle state.     

Electrophysiological recording from parasitic nematode muscle

Infection of man and animals with parasitic nematodes is recognized as a significant global problem (McLeod in Int J Parasitol 25(11):1363–1367, 1994; Hotez et al. in N Engl J Med 357(10):1018–1027, 2007). At present control of these infections relies primarily on chemotherapy. There are a limited number of classes of anthelmintic compounds and the majority of these act on ion-channels of the parasite (Martin et al. in Parasitology 113:S137–S156, 1996). In this report, we describe electrophysiological recording techniques as applied to parasitic nematodes. The aim of this report is: (1) to promote the study of ion channels in nematodes to help further the understanding of antinematodal drug action; (2) to describe our recording equipment and experimental protocols; and (3) provide some examples of the information to be gleaned from this approach and how it can increase our understanding of these important pathogens.     

Propagation of shear waves in muscle tissue

A mathematical model of the propagation of acoustic shear waves in muscle tissue is considered. Muscle is modeled as an incompressible transversely isotropic viscoelastic continuum with quasi-one-dimensional active tension. There are two types of shear waves in an infinite medium. Waves of the second type (transverse) propagate without decay even when myofibril viscosity is taken into account. A problem of standing transverse waves in a rectangular layer was investigated numerically. The values of the problem parameters are found for which one can easily estimate the active tension (or muscle tone) from the characteristics of standing waves. This value is informative for diagnostics of the muscle state.     

Study of acoustic waves in stressed muscle

The spectral characteristics of mechanical vibrations generated by stressed human biceps, referred to as "muscle sounds", were studied. Attempts were made to establish a relationship between these vibrations and conformational rearrangements of muscle proteins during contraction. It was found experimentally that the steepness of the spectral amplitudes of vibrations varies with muscle load. The method proposed made it possible to quantitatively study vibrations of frequencies up to 1 kHz.     

Establishment of a recording method for surface electromyography in the iliopsoas muscle

We examined the availability and reliability of surface electromyography (EMG) signals from the iliopsoas muscle (IL). Using serial magnetic resonance images from fifty healthy young males, we evaluated whether the superficial region of IL was adequate for attaching surface EMG electrodes. Subsequently, we assessed EMG cross-talk from the sartorius muscle (SA)—the nearest to IL—using a selective cooling method in fourteen subjects. The skin above SA was cooled, and the median frequencies of EMG signals from IL and SA were determined. The maximum voluntary contraction during isometric hip flexion was measured before and after selective cooling, and surface EMG signals from SA and IL were measured. The superficial area of IL was adequately large (13.2 ± 2.7 cm²) for recording surface EMG in all fifty subjects. The maximum perimeter for the medial–lateral skin facing IL was noted at a level 3–5 cm distal to the anterior superior iliac spine. Following cooling, the median frequency for SA decreased significantly (from 70.1 to 51.9 Hz, p < 0.001); however, that for IL did not alter significantly. These results demonstrated that EMG cross-talk from SA was negligible for surface EMG signals from IL during hip flexion.     

Shear velocity of muscle tissues

Investigations on shear wave velocities in a large number of elastoplastic muscle tissues of dead animals (ox, sheep, and goat) were carried out at 1 MHz frequency by the ultrasonic pulse transmission technique and their rigidity and stiffness modulus estimated after determining the density due to displacement in mercury. Information on compressional wave velocity and acoustic impedance, together with the alastic properties and some results on shear velocity anisotropy are also presented. It is interesting to note that irrespective of organ, species and direction of measurement, the results of velocity, rigidity and stiffness fall within very narrow limits owing to their nearly identical amino acid composition.     

Use of micromachined probes for the recording of cardiac electrograms in isolated heart tissues

Micromachined probes, with iridium (Ir) microelectrodes on silicon shanks, were evaluated to assess their suitability for cardiac electrogram recording. The electrochemical activation (anodic oxidation) procedure for the circular Ir microelectrode was investigated using the square wave potential according to the electrode size, number of cycles, and cathodic-anodic potential level of the square wave. Increase in the charge storage capacity was pronounced either in smaller electrodes or with higher potential level of the square wave. The electrode impedance reduced in a similar manner with increasing number of cycle irrespective of the electrode size. With either lower potential level (-0.70/+0.60 V) or smaller number of cycle (200 cycles) than those for the activation of stimulating electrode, the likelihood of overactivation of the recording microelectrode can be minimized. These anodic IrOx film (AIROF) microelectrodes were used for the recording of extracellular electrograms in two different ex vivo cardiac tissue preparations. A single-shank microprobe was applied to the left ventricle of a mouse heart. Both the spontaneous and paced transmural responses propagating between epicardium and endocardium were obtained. Longitudinal cardiac wavefronts propagating along the rabbit papillary muscle were also recorded with a unique multiple-shank design. The measured mean amplitude and the propagation velocity of the extracellular voltage were 12.2 +/- 1.8 mV and 58.9 +/- 2.2 cm/s, respectively (n = 27). These microprobes with precisely defined electrode spacing make a useful tool for the spatial and temporal mapping of electrical properties in isolated heart tissues ex vivo.     

Asynchronous calcium waves in smooth muscle cells

Asynchronous Ca2+ waves or wave-like [Ca2+]i oscillations constitute a specialized form of agonist-induced Ca2+ signaling that is observed in a variety of smooth muscle cell types. Functionally, it is involved in the contractile regulation of the smooth muscle cells as it signals for tonic contraction in certain smooth muscle cells while causing relaxation in others. Mechanistically, repetitive Ca2+ waves are produced by repetitive cycles of sarcoplasmic reticulum Ca2+ release followed by Ca2+ uptake. Plasmalemmal Ca2+ entry mechanisms are important for providing the additional Ca2+ necessary to maintain proper refilling of the sarcoplasmic reticulum Ca2+ store and support ongoing Ca2+ waves. In this paper, we will review the phenomenon of asynchronous Ca2+ waves in smooth muscle and discuss the scientific and clinical significance of this new understanding.     

cav-p60 expression in rat muscle tissues

Caveolae are plasmalemmal invaginations of uncertain function. In view of the large number of hypotheses on caveolar functions, it is important to identify which components of caveolae are tissue specific and which are general. The only well-characterized major protein of caveolae is caveolin, which exists in three tissue-specific isoforms: caveolin-1, -2, and -3. Recently cav-p60 was characterized as a 60-kDa caveola-specific protein in adipocytes. The distributions of cav-p60 and caveolin isoforms in different rat muscle tissues were examined by immunofluorescence and immunoelectron microscopy. Cav-p60 was present in caveolae of skeletal and heart muscle, in vascular and intestinal smooth muscle, and in adipocyte caveolae. Furthermore cav-p60 was present in endothelial cells and cells of perineural sheaths. Caveolin-1 and -2 were present in adipocytes, endothelial cells, and cells of perineural sheaths. In all kinds of vascular and intestinal smooth muscle, caveolin-1 and -2 were present at high levels, whereas caveolin-3 expression was low or undetectable, depending on the specific smooth muscle subtype. High levels of caveolin-3 were found only in caveolae and T tubules of skeletal and heart muscle. We conclude that cav-p60 is a highly specific marker of caveolae in many if not all cell types having caveolae.     

Sympathetic action in skeletal muscle studied by recording mitogenetic radiation

The reaction of sarcoplasmic molecular organization on the irritation of the sympathetic system was studied in tired frog muscles. The molecular changes have been determined by registration of mitogenic irradiation. The intensive irradiation recorded at the phase of highest sympathetic effect indicated the reinforcement of the regulation process it is suggested that structural and energetic substrate changes associated with irradiation are directly involved in the modulating influences of the sympathetic system.     

Microwave-induced pressure waves in a model of muscle tissue

Microwave-induced mechanical stress waves were studied in simulated muscle tissue. Pulsed microwave energy at 5.655 GH_z induced pressure waves that were recorded with a hydrophone transducer. Each pulse produced a peak power density greater than 1.5 kW/cm². Microwave absorption measurements within the model showed energy deposition to be mostly confined to a region within 2 cm of the irradiated surface. The average specific absorption rate (SAR) at the surface of the sample was about 100 W/kg. The microwave-induced stress wave propagated at a velocity of 1,600 m/sec with peak pressures of approximately 300 pascals and was detectable after having traveled a total distance of 0.61 m on a path that included two reflections at model-container interfaces.     

Extracellular recording of localized electrical activity in denervated frog slow muscle fibres

Pyriformis muscles of Rana temporaria were denervated by cutting the sciatic nerve in the pelvis. Slow muscle fibres were depolarized with intracellular current pulses, and the electrical activity was recorded simultaneously with intracellular and extracellular recording electrodes. When the extracellular electrode was moved along the fibre surface, outward and inward currents of variable amplitude were recorded. Inward currents coincided with the fast rising phase of the intracellularly recorded action potential; up to four inward current peaks could be detected in single fibres investigated over 3.4--8 mm of their length. The distance between inward current peaks was generally 1--2 mm, but greater distances were also observed. Composite action potentials could be shown to be due to inward currents arising in separate areas of the slow fibre membrane. It is concluded that after denervation Na-channels are incorporated into spatially limited areas of the membrane of slow muscle fibres.