A constitutive formulation of vascular tissue mechanics including viscoelasticity and softening behaviour

Nearly all soft tissues, among which the vascular tissue is included, present a certain degree of viscoelastic response. This behaviour may be attributed in part to fluid transport within the solid matrix, and to the friction between its fluid and solid constituents. After being preconditioned, the tissue displays highly repetitive behaviour, so that it can be considered pseudo-elastic, that is, elastic but behaving differently in loading and unloading. Because of this reason, very few constitutive laws accounting for the viscoelastic behaviour of the tissue have been developed. Nevertheless, the consideration of this inelastic effect is of crucial importance in surgeries—like vascular angioplasty—where the mentioned preconditioning cannot be considered since non-physiological deformation is applied on the vessel which, in addition, can cause damage to the tissue. A new constitutive formulation considering the particular features of the vascular tissue, such as anisotropy, together with these two inelastic phenomena is presented here and used to fit experimental stress–stretch curves from simple tension loading–unloading tests and relaxation test on porcine and ovine vascular samples.     

RF nonlinear interactions in living cells-I: nonequilibrium thermodynamic theory

Some biological experiments report effects that depend on low frequency modulation of a radiofrequency (RF) carrier. Such effects require nonlinear responses in biological preparations, which we show could be observed with great generality by the unique frequency signatures that would appear in the scattered RF energy. Following Illinger [Illinger (1982): Bioelectromagnetics 3:9-16], we considered a two part physical system. The greater part, dominated by the properties of water, interacts linearly with the RF field and is described by equilibrium thermodynamics. However, another, much smaller part, e.g., certain biological molecules and molecular subgroups, supports nonlinear interactions and is described by nonequilibrium thermodynamics. For example, a nonlinear interaction might result from scattering of RF photons from oscillators located in a region of strong field gradients, such as at membrane surfaces. A second nonlinear mechanism could appear if stress (elastic) waves were launched within the confines of the exposure vessel by RF heating. Amplitude modulation at angular frequency Omega of a carrier wave with angular frequency omega (omega < omega) produces two peaks in elastic stress in the cell structure during each period; that is, there is "full-wave demodulation." As a result of coherent nonlinear charge motion, modulation products could appear at frequencies omega +/- 2 omega and, in general, at omega +/- n 2 omega (n = 1, 2, em leader ) if vibrational harmonics at 2 n omega also are excited. Although in principle microwaves can alter the stability of a thermodynamic system by pumping a chemical transition, the degree of nonlinear coupling required for an observable instability is so great that its probability is effectively zero, unless field intensity is extremely high. A companion paper suggests an extremely sensitive method and the related instrumentation for detection of the spectrum scattered by living cells during exposure to amplitude modulated RF energy.     

DIGE analysis of proteome changes accompanying large resveratrol production by grapevine (Vitis vinifera cv. Gamay) cell cultures in response to methyl-β-cyclodextrin and methyl jasmonate elicitors

We had previously shown that Vitis vinifera cv. Gamay cell suspension accumulates extracellularly large amounts of the phytoalexin trans-resveratrol (tR) in response to elicitation with methylated cyclodextrins (MBCD), which can be triplicated when the elicitor is combined with methyl jasmonate (MeJA). In parallel, new pathogenesis-related proteins accumulated in the apoplast-like extracellular space. The aim of this study was to investigate changes in the grapevine cell proteome potentially related to tR accumulation in response to the above elicitors. The DIGE technique was used to detect statistically significant changes in the cell's proteome. A total number of 1031 unique spots were detected, 67 of which were de-regulated upon elicitation. Sixty-four spots were successfully identified by nLC-MS/MS database search analysis. The tR biosynthetic pathway enzymes were up-regulated by MBCD alone or combined with MeJA, but not by treatment with MeJA alone, in agreement with tR accumulation pattern. Seven spots contained stilbene synthase encoded by four different isogenes. Likewise, four glutathione-S-transferases, potentially involved in tR trafficking within the cell and across membranes, were up-regulated in the same fashion as stilbene synthases. The relation of other de-regulated proteins with other effects caused by elicitors on grapevine cells, namely defense response and cell growth inhibition, is discussed.     

Special feature for the Olympics: effects of exercise on the immune system: effects of exercise on the immune system in the elderly population

Immunosenescence is characterized by impaired cellular immune function concomitant with increased inflammatory activity. Immune dysfunction is associated with increased mortality risk in elderly people. An important part of human ageing is characterized by a decline in the ability of individuals to adapt to environmental stress. Exercise has been suggested as a prototype for studying the effects of stress factors on the cellular immune system. Studies of interactions between an acute bout of exercise and immune function may be a useful and an ethically acceptable tool to investigate cell trafficking, immune mobilization/deficiency and the acute phase response during physical stress situations in relation to human ageing. Elderly humans have a preserved ability to recruit T lymphocytes and NK cells in response to an acute bout of exercise. Physical exercise training programs do not result in major restoration of the senescent immune system in humans. However, highly conditioned elderly humans seem to have a relatively better preserved immune system, although it is not possible to conclude if this is linked to training or other lifestyle-related factors.     

The Role of Salicylic Acid Signal in Plant Growth,Development and Abiotic Stress

In nature, plants are constantly affected by adverse conditions. Unlike animals, plants can resist these adverse stresses only by insisting on their original positions. Stress can be divided into biological stress and abiotic stress, abiotic stress directly affects the growth, development and yield of plants, it spans all developmental stages from seed germination to senescence. In order to adapt to changing environment, plants have evolved well-developed mechanisms that help to perceive the stress signals and enable optimal growth response. Salicylic acid (SA) is an important endogenous signal molecule in plants, which not only regulate some plant growth and development processes, but also plays an important part in plant stress resistance. Much work about salicylic acid has been done on the immunity of plants to pathogens, and the synthesis and signal transduction of SA are clearly understood, its function in plant growth, development and abiotic stress is also well learned, we systemically summarized the multiple function of SA signal in non-pathogen-related response, such review should help us understand the common but essential function of SA signal in modulating plant growth, development and abiotic stress.     

General continuum analysis of transport through pores. II. Nonuniform pores.

A general continuum derivation of the nonelectrolyte (Js) and volume (Jv) flux through a pore whose cross section is a function of axial position (nonuniform) is given. In general, the flux equations cannot be reduced to the same form as for a uniform pore and it is not possible to characterize the pore kinetics by three constants as in the uniform pore case. However, it is shown that under certain conditions, the nonuniform pore equations can be approximated by the uniform pore form and can be characterized by three constants (omega, sigma, Lp). The only condition needed to reduce the Jv equation to the uniform form is that the solution be dilute. The deviation of the Js equation from the uniform form is characterized by an asymmetrical function of Jv whose maximum value is estimated. It is shown that the maximum posible fractional deviation of the Js equation from the uniform form is given by the parameter: 0:5sigmaJv/omegaRT. Since this parameter is less then 0.15 for most membrane studies, the nonuniform Js equation can usually be approximated by the uniform pore form. The general results are illustrated by explicit calculations on several models of nonuniform pores. It is shown, for example, that the "equivalent pore radius" defined in the usual way is a function of the experimental parameter that is measured and is not unique.     

A frame-invariant formulation of Fung elasticity

Fung elasticity refers to the hyperelasticity constitutive relation proposed by Fung and co-workers for describing the pseudo-elastic behavior of biological soft tissues undergoing finite deformation. A frame-invariant formulation of Fung elasticity is provided for material symmetries ranging from orthotropy to isotropy, which uses Lamé-like material constants. In the orthotropic case, three orthonormal vectors are used to define mutually orthogonal planes of symmetry and associated texture tensors. The strain energy density is then formulated as an isotropic function of the Lagrangian strain and texture tensors. The cases of isotropy and transverse isotropy are derived from the orthotropic case. Formulations are provided for both material and spatial frames. These formulations are suitable for implementation into finite element codes. It is also shown that the strain energy function can be naturally uncoupled into a dilatational and a distortional part, to facilitate the computational implementation of incompressibility.     

Stress intensity variations in bone microcracks during the repair process

Microscopic cracks form and grow in compact bone in vivo due to cyclic loading. Their growth can cause stress fractures and has been implicated in the processes of remodelling and adaptation. These cracks are repaired by the actions of BMUs which are mobile resorption cavities. In this work, we studied the interaction between cracks and BMUs by making finite element models representing different stages in the repair process. The tendency of the crack to grow was measured by its stress intensity factor, K. We found that K changes in a complex manner during the repair process, both decreasing and increasing depending on the size of the crack and the type of loading applied. For loading conditions similar to those that exist in vivo, the presence of the BMU can cause K to rise significantly, in some cases by more than 20%, implying a substantial increase in crack growth rate. This information is important for our general understanding of the complexities of the repair process, and especially for the development of theoretical models to simulate damage and repair in bone.     

Confusion and controversy in the stress field.

An attempt is made to further clarify present areas of controversy in the stress field, in response to a two-part article by Dr. John W. Mason which concludes in this issue of the Journal of Human Stress. The author tries to elucidate each source of confusion enumerated by Dr. Mason. The continued use of the word "stress" for the nonspecific response to any demand is deemed most desirable. The once vague term can now be applied in a well-defined sense and is accepted in all foreign languages as well, including those in which no such word existed previously in any sense. Subdivision of the stress concept has become necessary as more recent work has led to such notions as "eustress," "distress," "systemic stress" and "local stress." Confusion between stress as both an agent and a result can be avoided only by the distinction between "stress" and "stressor". It is explained that the stress syndrome is--by definition--nonspecific in its causation. However, depending upon conditioning factors, which can selectively influence the reactivity of certain organs, the same stressor can elicit different manifestations in different individuals.     

Force recovery after activated shortening in whole skeletal muscle: transient and steady-state aspects of force depression.

The depression of isometric force after active shortening is a well-accepted characteristic of skeletal muscle, yet its mechanisms remain unknown. Although traditionally analyzed at steady state, transient phenomena caused, at least in part, by cross-bridge kinetics may provide novel insight into the mechanisms associated with force depression (FD). To identify the transient aspects of FD and its relation to shortening speed, shortening amplitude, and muscle mechanical work, in situ experiments were conducted in soleus muscle-tendon units of anesthetized cats. The period immediately after shortening, in which force recovers toward steady state, was fit by using an exponential recovery function (R2 > 0.99). Statistical analyses revealed that steady-state FD (FD(ss)) increased with shortening amplitude and mechanical work. This FD(ss) increase was always accompanied by a significant decrease in force recovery rate. Furthermore, a significant reduction in stiffness was observed after all activated shortenings, presumably because of a reduced proportion of attached cross bridges. These results were interpreted with respect to the two most prominent proposed mechanisms of force depression: sarcomere length nonuniformity theory (7, 32) and a stress-induced inhibition of cross-bridge binding in the newly formed actin-myosin overlap zone (14, 28). We hypothesized that the latter could describe both steady-state and transient aspects of FD using a single scalar variable, the mechanical work done during shortening. As either excursion (overlap) or force (stress) is increased, mechanical work increases, and cross-bridge attachment would become more inhibited, as supported by this study in which an increase in mechanical work resulted in a slower recovery to a more depressed steady-state force.     

Partial purification of "omega" protein from calf thymus.

Proteins which relax supercoiled DNA, called "omega" proteins, are thought to be involved in DNA replication. Calf thymus is a plentiful source of "omega" protein activity. It has been extensively purified and has been characterized as behaving similarly to other eukaryotic "omega" proteins in completely relaxing either positively or negatively supercoiled DNA, requiring a salt concentration of about 0.2 M NaCl or KCl, and not requiring Mg2+. A transient nick must occur but could not be detected. A new assay for "omega" activity is described which is rapid and sensitive, and depends on the fluorescence enhancement of ethidium intercalating duplex DNA.     

The dependence of impulse propagation speed on firing frequency, dispersion, for the Hodgkin-Huxley model.

Propagation speed of an impulse is influenced by previous activity. A pulse following its predecessor too closely may travel more slowly than a solitary pulse. In contrast, for some range of interspike intervals, a pulse may travel faster than normal because of a possible superexcitable phase of its predecessor's wake. Thus, in general, pulse speeds and interspike intervals will not remain constant during propagation. We consider these issues for the Hodgkin-Huxley cable equations. First, the relation between speed and frequency or interspike interval, the dispersion relation, is computed for particular solutions, steadily propagating periodic wave trains. For each frequency, omega, below some maximum frequency, omega max, we find two such solutions, one fast and one slow. The latter are likely unstable as a computational example illustrates. The solitary pulse is obtained in the limit as omega tends to zero. At high frequency, speed drops significantly below the solitary pulse speed; for 6.3 degrees C, the drop at omega max is greater than 60%. For an intermediate range of frequencies, supernormal speeds are found and these are correlated with oscillatory swings in sub- and superexcitability in the return to rest of an impulse. Qualitative consequences of the dispersion relation are illustrated with several different computed pulse train responses of the full cable equations for repetitively applied current pulses. Moreover, changes in pulse speed and interspike interval during propagation are predicted quantitatively by a simple kinematic approximation which applies the dispersion relation, instantaneously, to individual pulses. One example shows how interspike time intervals can be distorted during propagation from a ratio of 2:1 at input to 6:5 at a distance of 6.5 cm.     

High-efficiency gene knockdown using chimeric ribozymes in fish embryos

We report an effective gene knockdown technique in rainbow trout embryos using additional RNA components combined with ribozymes (R(z)s). Chimeric R(z)s (tR(z)Cs) containing tRNA(Val), R(z) against GFP, and a constitutive transport element were microinjected into transgenic embryos. tR(z)Cs induced greater gene interference than R(z)s alone. Control tR(z)Cs did not affect unpaired bases of target RNA, and the tR(z)C did not interfere with non-relevant gene expression, suggesting that the tR(z)C-mediated gene-interference effects were sequence-specific. Furthermore, the tR(z)C-containing expression vector specifically suppressed target GFP expression in transgenic trout. tR(z)Cs enhance R(z) cleavage and could therefore be powerful tools for studying unknown gene function in vertebrates.     

Comparison of voice stress reactivity under psychological stress test and simulated Mir docking manoeuvre

The relation between the results of laboratory tests and results of the interesting professional work is a very difficult one. The same is true for the relation between training and real performance. The pilot controlled MIR-docking manoeuvre is in reality a very seldom but very important one. The training of this manoeuvre is a very special professional work and only for cosmonauts available. But the objective estimation of the performance and the used objective and subjective needs is nevertheless necessary. Even for the subjective "stress"-feelings during task solving it is often impossible to get reliable data without any physiological measurements. The use of electrodes, cables and equipments is hardly limited during real work. Sometimes only the voice is available over more or less quality communication channels. So it is the case during the training and the real pilot controlled MIR-docking manoeuvre. Based on findings in the literature and own experiments analyzing the relation between fundamental voice frequency (F0) and subjective stress feelings we tested the hypothesis that a on-line measurement of F0 can be used for stress evaluation during standardised training sessions of MIR-docking manoeuvres.     

Neurochemistry of Stress. An Overview

Stress is a word that is used very commonly. It is generally employed to design unpleasant phenomena, although it is related to a function necessary to our life. Stress in itself is not a disease. Stress is not an aggression. It is an adaptative response of our body to any demand. Nothing can be done without stress. Stress gives rise to a mobilization of our body to succeed in a group of activities necessary to individual and social life. It favors our dynamism and creativity. But this aptitude can attain its limits, when the solicitations we receive are above what we are able to perform, both in relation to our mental and physical capabilities. The brain controls the systems involved in stress. The main areas are the prefrontal cortex, the limbic system (which comprises the hippocampus and the amygdala) and the hypothalamus. Relations between the prefrontal cortex and the limbic system are important for the planification of action. The main systems of regulation are the sympathetic and parasympathetic systems, the neuro-endocrine system and last but not least the immune system. There is a relation between all our organs and the brain. The genetic aspects and the influences of our past experiences, both during childhood and in adult life, are envisaged.     

Sympathetic nervous system and bone adaptive response to its mechanical environment

While bone adaptive response to its mechanical environment was considered to be controlled locally by cytokines and systemic hormones, some recent work suggests that it could also be neuronally regulated. Bone is indeed very densely innervated and many experimental and clinical studies have previously shown the involvement of the nervous system in the control of bone metabolism. The demonstration that the central nervous system regulates bone mass via the sympathetic nervous system (SNS) has prompted recent studies aimed to investigate the role of the SNS in the bone mechano-adaptive response. This review will focus on this work and summarize the evidence for a contribution of the beta-adrenergic signalling in the response of bone cells to mechanical loading. The apparent conflicting results obtained in diverse experimental models of loading and unloading, at different skeletal sites, and in relation to various hormonal levels, will be discussed. While those studies do not support a major influence of the SNS on the bone mechano-adaptive response, there is nevertheless strong evidence that the SNS is part of a complex system which contributes to the metabolic regulation of bone.