Effects of ionic environment on viscosity of Triton-extracted catch connective tissue of a sea cucumber body wall

Mechanical properties of catch connective tissue are greatly affected by its ionic environment. In order to understand the role of ions, a preparation was developed in which cellular activities were suppressed by treatment with 1% Triton X-100.The material used was body-wall dermis of the sea cucumber Holothuria leucospilota Brandt.The effects of the main cations in seawater (H⁺, Na⁺, K⁺, Ca²⁺, Mg²⁺) on the creep viscosity of the Triton model were compared with those of intact dermis.The comparison distinguished the site of action of ions. K⁺ had its main effect on cells that control the catch mechanism, whereas Ca²⁺ worked directly on extracellular materials. H⁺, Na⁺ and Mg²⁺ had both effects.     

Mechanical mutability in connective tissue of starfish body wall

Stiffness changes in response to mechanical and chemical stimulation were studied in muscle-free dermal samples from the body wall of the starfish Linckia laevigata. The ultrastructural study showed that the dermis was packed with collagen fibrils between which only a small number of cells were observed. Muscles were found only in the walls of coelomic extensions leading to papulae. Stress-strain tests were performed on isolated dermis containing no muscles. The tangent modulus was 27.5 MPa at 0.04% strain rate in the stress-strain tests. It was increased to 40.7 MPa by mechanical stimulation, which also increased the tensile strength and breaking-strain energy density. Dynamic mechanical tests showed that the increase in stiffness in response to mechanical stimulation was transient. Acetylcholine (10(-6)-10(-3) mol l(-1)) and artificial seawater with an elevated potassium concentration (KASW) stiffened the dermis. Mechanical stimulation caused a 12% mass loss. KASW also caused mass loss, which was inhibited by anesthesia. These results clearly showed that the stiffness changes in the starfish dermis were based on a non-muscular mechanism that was similar to that of other echinoderm connective tissues with mechanical mutability.     

The mechanical properties of the rabbit carpal tunnel subsynovial connective tissue

The rabbit model is commonly used to study carpal tunnel syndrome (CTS). It has been proposed that the subsynovial connective tissue (SSCT) in the carpal tunnel may play a role in the etiology of CTS, but the material properties of the rabbit SSCT are unknown. The purpose of this study was to develop a method to measure the shear properties of the rabbit SSCT. In six rabbit cadaver forepaws, the excursion of the third digit flexor digitorum superficialis (FDS) and load to failure of the SSCT were measured in a custom device. The mean excursion to full flexion in this model was 7.08 mm (S.D. 0.77). The mean shearing force at full flexion was 317 mN (S.D. 166). At full flexion percentage of maximum shear force in the SSCT was 54.5% (S.D. 19.4). The mean energy absorbed at full flexion was 0.29 mJ (S.D. 0.31). The mean excursion needed to reach 5% of the maximum shear force was 3.04 mm (S.D. 0.99). The testing model presented in this study demonstrates structural parameters to evaluate the shear properties of the SSCT in a rabbit model. The data presented could be used for estimating sample sizes in a more comprehensive study of the effect of CTS on the SSCT properties.     

Viscosity increase of holothurian body wall in response to photic stimulation

• 1.1. The dermis of body wall of Holothuria leucospilota Brandt rapidly increased in viscosity in response to a flashlight.
• 2.2. The response was inhibited in a preparation from which the epidermis had been removed or in a preparation anaesthetized with menthol.
• 3.3. The results strongly suggest that the viscosity of the connective tissue is controlled through nervous activities.

     

Use of enzymolysis techniques in studying the mechanical properties of connective tissue components.

The optimum conditions for the selective removal of elastin from connective tissues are described. The process, elastolysis, consists of incubating small samples of connective tissue in buffered saline at ph=8.6 containing 300 microgram/me of a 50-50% mixture of elastase with trypsin inhibitor, for 5-6 hours at room temperature. This process, complimented with other processes for selective removal of lipids, or mucopolysaccharides, or collagen, enables one to examine the contribution of the various components of the connective tissue to its mechanical function. The elastolysis was tested with aortic, valvular and tendon tissues from human, bovine and canine species and it was found that in tensile stress experiments, collagen was unaffected while the low-stress contribution of elastin disappeared.     

Stiffness of starfish arm and involvement of catch connective tissue in the stiffness change

• 1.1. Bending tests were performed on intact arms of two starfishes of different orders to obtain stiffness of the arm.
• 2.2. Linckia laevigata without stimulation showed a wide variety of arm stiffness of 2.24–51.3 MPa (average: 8.0 MPa). Mechanical stimulation increased the stiffness by 2.5 times.
• 3.3. In Asterias forbesii, isolated arms were 23 times stiffer than intact ones. Anesthesia with 0.1% MS-222 or menthol-saturated sea water increased the stiffness by 7–170 times.
• 4.4. Ion dependence of stiffness suggests that the catch connective tissue was involved in the stiffness change.

     

Evidence for calcium translocation in catch connective tissue of the sea cucumber Stichopus chloronotus

Summary Catch connective tissue is collagenous connective tissue that changes its mechanical properties rapidly. Calcium has been assumed to play a key role in the catch mechanism because calcium concentration profoundly affects the mechanical properties. We have found a calcium-storage cell, the vacuole cell, in the dermis of the sea cucumber Stichopus chloronotus a wellstudied catch connective tissue. The processes of this cell are packed with vacuoles measuring 0.1–1.5 m in diameter. The ultrastructure was compared in a relaxed state and in a catch (stiff) state induced by high-potassium artificial sea water. When fixed with pyroantimonate, the vacuoles contained precipitates in the relaxed state but not in the catch state. Analysis with an energy-dispersive X-ray microanalyzer suggested that the precipitate contains calcium. The release of calcium ions from the vacuole cell is proposed to induce connective tissue catch.     

The glycosaminoglycans of pig colonic wall connective tissue

Colon wall from pig, stripped of most of the mucosal layer to leave material largely composed of muscle, basement membrane, and extracellular matrix, was subjected to procedures for isolation of glycosaminoglycans. A total ethanol precipitate from a papain digest was fractionated by selective ethanol precipitation in the presence of Ca²⁺. Glycosaminoglycan fractions, freed proteolytically from a high molecular weight glycoprotein component, were further purified by Sepharose CL-6B gel-filtration or DE-52 anion-exchange chromatography. Glycosaminoglycans were identified by chemical composition, ¹³C-NMR spectroscopy and response to chondroitinase and nitrous acid degradations. The content of glycosaminoglycan in the tissue is low (0.05% dry weight) being comprised of dermatan sulphate (38%), heparin (34%), heparan sulphate (18%) and chondroitin sulphates (10%) as a percentage of total glycosaminoglycan content. Hyaluronic acid and keratan sulphate have not been detected. The composition is generally typical of a high muscle content tissue.     

The fine structure and development of calcified skeletal elements in the body wall of holothurian echinoderms

The calcareous ossicles and iron-rich calcified granules in the integument of sea cucumbers (Echinodermata: Holothuroida) have been examined by light and electron microscopy. Most ossicles are perforated, platelike structures that measure 100–500 μm long and consist of magnesium-rich calcite. The formation of ossicles occurs within multinucleated syncytia of sclerocytes that are situated in the dermal layer of the body wall. Sclerocytes possess fairly large numbers of mitochondria and are characteristically enveloped by an external lamina. Each ossicle arises as a minute rodlike spicule that branches and develops into a fenestrated skeletal element. When viewed by SEM, fully developed ossicles appear non-crystalline. Following decoration with synthetically grown calcite seeds, however, each ossicle reveals an ordered array of crystallites that seem to be aligned perpendicular to the ossicle's original plane of growth. Examinations of sectioned ossicles indicate that the mineral phase in each skeletal element lacks a well developed matrix of EDTA-insoluble organic substances. Ossicles first arise in the ciliated, lecithotrophic larvae of Eupentacta quinquesimita at about 1 week postfertilization. Two-week-old specimens adopt an epibenthic existence and subsequently become enveloped by imbricated ossicles that are secreted by sclerocytes resembling those found in adults. In molpadiid holothurians, the adult body wall contains numerous reddish-brown granules that are chiefly composed of iron-rich subunits. The dermal granules differ from calcitic ossicles in developing extracellularly in association with finely filamentous material.     

Innervation of holothurian body wall muscle: inhibitory effects and localization of 5-HT

We investigated innervation to body wall muscles as well as distribution of 5-HT (serotonin) and its effects on longitudinal muscles of body wall (LMBW) of the sea cucumber Apostichopus japonicus. With serial sections we found neural branches and fibers extending from hyponeural part of radial nerve towards LMBW and circular muscles of body wall. With the aqueous aldehyde (Faglu) method yellow fluorescence indicating indolamines was observed in LMBW and in the mesentery connecting LMBW to the body wall. With indirect immunohistochemistry 5-HT-like immunoreactivity was observed in LMBW and in mesentery. These results strongly suggested that both LMBW and mesentery contained 5-HT. The effects of monoamine neurotransmitters were studied in LMBW. Putative neurotransmitters tested were 5-HT, adrenaline, noradrenaline, dopamine, and DOPA at the concentration of 10(-6) M. The application of 5-HT caused no contraction or relaxation, but it inhibited the contraction induced by 10(-6)-10(-5) M acetylcholine (ACh). Catecholamines were ineffective by themselves and had no effects on the contraction induced by ACh. The present histological, histochemical, and pharmacological studies strongly suggested that holothurian LMBW was innervated by inhibitory serotonergic neurons of the hyponeural nervous system.     

Cellular control of connective tissue matrix tension

The biomechanical behavior of connective tissue in response to stretching is generally attributed to the molecular composition and organization of its extracellular matrix. It also is becoming apparent that fibroblasts play an active role in regulating connective tissue tension. In response to static stretching of the tissue, fibroblasts expand within minutes by actively remodeling their cytoskeleton. This dynamic change in fibroblast shape contributes to the drop in tissue tension that occurs during viscoelastic relaxation. We propose that this response of fibroblasts plays a role in regulating extracellular fluid flow into the tissue, and protects against swelling when the matrix is stretched. This article reviews the evidence supporting possible mechanisms underlying this response including autocrine purinergic signaling. We also discuss fibroblast regulation of connective tissue tension with respect to lymphatic flow, immune function, and cancer. J. Cell. Biochem. 114: 1714–1719, 2013. © 2013 Wiley Periodicals, Inc.     

The molecular and fibrillar structure of collagen and its relationship to the mechanical properties of connective tissue

The conformation of type I collagen molecules has been refined using a linked-atom least-squares procedure in conjunction with high-quality X-ray diffraction data. In many tendons these molecules pack in crystalline arrays and a careful measurement of the positions of the Bragg reflections allows the unit cell to be determined with high precision. From a further analysis of the X-ray data it can be shown that the highly ordered overlap region of the collagen fibrils consists of a crystalline array of molecular segments inclined by a small angle with respect to the fibril axis. In contrast, the gap region is less well ordered and contains molecular segments that are likely to be inclined by a similar angle but in a different vertical plane to that found in the overlap region. The collagen molecule thus has a D-periodic crimp in addition to the macroscopic crimp observed visually in the collagen fibres of many connective tissues. The growth and development of collagen fibrils have been studied by electron microscopy for a diverse range of connective tissues and the general pattern of fibril growth has been established as a function of age. In particular, relationships between fibril size distribution, the content and composition of the glycosaminoglycans in the matrix and the mechanical role played by the fibrils in the tissue have been formulated and these now seem capable of explaining many new facets of connective tissue structure and function.     

Close apposition of muscle cells in the longitudinal bands of the body wall of a holothurian,Isostichopus badionotus

Summary Electron microscopy reveals that sarcolemmata of adjacent muscle cells form pentalaminar junctions by fusion of apposed trilaminar double leaflet membranes. These junctions appear to be candidates for low resistance pathways between muscle fibers. The muscles depolarize slowly when bathed in solutions containing elevated concentrations of KCl, and the sucrose gap method can then be used to measure the potential difference between polarized and depolarized regions. Thus the junctions which we have observed may provide the structural basis for electrical transmission through the sucrose gap.Contribution No. 916 from the Bermuda Biological Station for Research, Inc. Supported by N.S.F. Grant POM 7613459 to the Bermuda Biological Station     

Development of the connective tissue in the wall of the rabbit aorta in experimental atherosclerosis

Structural and functional characteristics of cells involved in collagen synthesis have been studied in experimental hypercholesterolemia in rabbits. Autoradiographic studies, using 3H-proline and 14C-hydroxyproline have demonstrated that collagen synthesis takes place only in the intima in the area of cellular proliferation. At earlier stages of experimental atherosclerosis collagen synthesis predominantly involves synthetic GABA phenotype, while at progressing stages fibroblasts are predominantly involved.     

Electrical properties of the body wall of Hydra

If the hydrostatic pressure in the enteron of Hydra is made more than 2–4 mm of water greater than the outside pressure, the animal becomes distended, indicating that the normal enteron pressure is less than this. Positive enteron pressure attenuates the spontaneous, negative-going electrical spikes across the body wall, which are called contraction pulses (CP''s) because of their relation to column contraction. Pressure has little effect on the transepithelial resting potential. The low frequency electrical impedance of the column is nonlinear. The impedance tends to increase as the transepithelial potential is made more negative. The nonlinearity has both initial and delayed components. The DC impedance of the column near the resting potential averages 100 kohms (approximately 5 kohms-cm²). The phase between transepithelial potential and imposed sinusoidal current approaches -90° with increasing current frequency. Bode plots of the column impedance and the phase lag indicate that the column has three or more time constants. CP''s show several unusual features: (a) their amplitude and frequency are essentially independent of the transepithelial potential when the latter is altered by imposed current; (b) there is practically no change in column impedance during CP firing; (c) when the transepithelial potential is clamped at zero, CP''s continue to appear spontaneously as current spikes. These features are consistent with the hypothesis that the CP-generating membrane forms but a small fraction of the total transverse impedance of the column.     

Flexibility of type I collagen and mechanical property of connective tissue

The hierarchical organization of the connective tissue, more specifically, the musculoskeletal soft tissue, has been extensively studied. With advancements in experimental methodology, investigation of the structure-function relationship has provided more insight into how the mechanical integrity of the tissue is created. Such information is essential in the linking the macroscopic loading environment of the tissue to the microscopic level of the tissue to be experienced by the cell. The flexibility and elastic modulus of gross connective tissue, the fascicle, the fiber and then the collagen molecule are compared based on the data available in the literature.