Thermomechanical analysis of collagen crosslinking in the developing lamb pericardium

In a developing lamb model, we have used hydrothermal isometric tension (HIT) techniques to assess collagen crosslink stability and its contribution to the mechanical properties of the pericardium. Strip samples of tissue were either: (i) heated to a 90 degrees C isotherm or (ii) heated in 5 degrees C increments between 60-90 degrees C and then 93 and 97 degrees C isotherms. The half-life of stress relaxation associated with peptide bond hydrolysis (t1/2) was calculated at each isotherm. The activation energy, Eact, for the hydrolysis-associated relaxation process was also calculated using the data from the stepwise HIT tests--a technical improvement which significantly reduces the experimental time required to develop statistically valid measurements. Crosslinking in the pericardium increased during development and was demonstrated both by thermoelasticity and by resistance to enzymatic solubilization. We observed greater conversation to thermally stable crosslinks upon maturation, the ratio of the NaBH4-stabilized/unstabilized half-lives peaking at 21 days postnatal. Whereas tissue from lambs (119 day fetal, and 3 day and 21 day postpartum) showed an early maximum and rapid decay of force, NaBH4 stabilization significantly increased thermal stability and yielded profiles similar to those in adult tissue.     

Alpha 2(I) collagen deficient oim mice have altered biomechanical integrity, collagen content, and collagen crosslinking of their thoracic aorta.

Collagen and elastin are the primary determinants of vascular integrity, with elastin hypothesized to be the major contributor to aortic compliance and type I collagen the major contributor to aortic strength and stiffness. Type I collagen is normally heterotrimeric composed of two alpha1(I) and one alpha2(I) collagen chains, alpha1(I)(2)alpha2(I). Recent investigations have reported that patients with recessively inherited forms of Ehlers Danlos syndrome that fail to synthesize proalpha2(I) chains have increased risks of cardiovascular complications. To assess the role of alpha2(I) collagen in aortic integrity, we used the osteogenesis imperfecta model (oim) mouse. Oim mice, homozygous for a COL1A2 mutation, synthesize only homotrimeric type I collagen, alpha1(I)3. We evaluated thoracic aortas from 3-month-old oim, heterozygote, and wildtype mice biomechanically for circumferential breaking strength (Fmax) and stiffness (IEM), histologically for morphological differences, and biochemically for collagen content and crosslinking. Circumferential biomechanics of oim and heterozygote descending thoracic aortas demonstrated the anticipated reduced Fmax and IEM relative to wildtype mice. Histological analyses of oim descending aortas demonstrated reduced collagen staining relative to wildtype aortas suggesting decreased collagen content, which hydroxyproline analyses of ascending and descending oim aortas confirmed. These findings suggest the reduced oim thoracic aortic integrity correlates with the absence of the alpha2(I)collagen chains and in part with reduced collagen content. However, oim ascending aortas also demonstrated a significant increase in pyridinoline crosslinks/collagen molecule as compared to wildtype ascending aortas. The role of increased collagen crosslinks is uncertain; increased crosslinking may represent a compensatory mechanism for the decreased integrity.     

交联对胶原降解速率的影响

目的：研究交联反应对胶原降解速率的影响。方法：以热交联(DHT)、1-乙基-3-(3-二甲基氨丙基)-碳化二亚胺(EDC)化学交联以及EDC／DHT交联三种方法对胶原海绵材料进行处理,并测定材料在处理前后的降解速率。结果：各种交联反应均不同程度地提高了胶原的生物稳定性．降低了胶原的降解速率。     

Elastogenesis in the wall of the human thoracic aorta

The results of this study dealing with the human thoracic foetal aorta testify that even in the middle of the fifth month of development the internal elastic membrane is not yet completely continuous. Furthermore they show that elastogenesis in the tunica media of the human thoracic aorta does not begin directly below the internal elastic membrane, as it does in the foetal aorta of the laboratory rat, but, as it can be seen in our material, somewhat deeper in the developing tunica media. A thin layer of less differentiated tunica media cells persists for a long time in the vicinity of the internal elastic membrane. In the middle of the fifth month, the fusing elastic membrane segments in the tunica media still consist of very immature elastic tissue with a large proportion of the microfibrillar component. The collagen fibrils in the intercellular spaces in the whole depth of the wall of the developing aorta do not become a part of the elastic membranes. Their bundles merely accompany all the elastic membranes in the wall of the thoracic aorta, including the internal elastic membrane.     

Influence of bleomycin on the crosslinking of dermal collagen in rat

The effect of bleomycin on dermal collagen crosslinking was studied in male albino rats. The skin samples were taken on the 28th day in both groups. Results showed that the percent reversibilities of neutral salt soluble collagen gels and the solubility of insoluble collagen in KCNS, urea or pronase were decreased in bleomycin treated animals whereas the aldehyde content was significantly increased in bleomycin treated animals compared to controls. The electrophoretic pattern of neutral salt soluble collagen on SDS-polyacrylamide gels revealed a marked decrease of alpha/beta ratio in bleomycin treated group. These results indicated that both the intra and inter molecular crosslinks of collagen were increased in the bleomycin treated group.     

Characterization of the collagen chains synthesized by cultured smooth muscle cells derived from rhesus monkey thoracic aorta.

Five different collagen chains and one smaller collagenous fragment have been isolated from the collagens found in the combined cell layer and medium of rhesus monkey aortic smooth muscle cell cultures. The collagen chains which can be identified are alpha1 (III), alpha1(I), alpha2, A and B. The smaller collagenous peptide exhibits an apparent molecular weight of 45 000 and has been designated CP45 (Mayne, R., et al. (1977), Arch. Biochem. Biophys. 181, 462). Smooth muscle cells continue to synthesize the collagens from which these components are derived for at least eight passages in culture. At each passage the alpha1 (III) chain consistently represents about one-half of the total collagen which is recovered after initial fractionation by agarose gel chromatography. The results show that smooth muscle cells derived from rhesus monkey thoracic aorta are phenotypically stable for many generations in vitro.     

Contribution of elastin and collagen to the inflation response of the pig thoracic aorta: assessing elastin's role in mechanical homeostasis

This study was undertaken to understand elastin's role in the mechanical homeostasis of the arterial wall. The mechanical properties of elastin vary along the aorta, and we hypothesized this maintained a uniform mechanical environment for the elastin, despite regional variation in loading. Elastin's physiological loading was determined by comparing the inflation response of intact and autoclave purified elastin aortas from the proximal and distal thoracic aorta. Elastin's stretch and stress depend on collagen recruitment. Collagen recruitment started in the proximal aorta at systolic pressures (13.3 to 14.6 kPa) and in the distal at sub-diastolic pressures (9.3 to 10.6 kPa). In the proximal aorta collagen did not contribute significantly to the stress or stiffness, indicating that elastin determined the vessel properties. In the distal aorta, the circumferential incremental modulus was 70% higher than in the proximal aorta, half of which (37%) was due to a stiffening of the elastin. Compared to the elastin tissue in the proximal aorta, the distal elastin suffered higher physiological circumferential stretch (29%, P=0.03), circumferential stress (39%, P=0.02), and circumferential stiffness (37%, P=0.006). Elastin's physiological axial stresses were also higher (67%, P=0.003). These findings do not support the hypothesis that the loading on elastin is constant along the aorta as we expected from homeostasis.     

Postnatal development of collagen structure in ovine articular cartilage

Background  

Articular cartilage (AC) is the layer of tissue that covers the articulating ends of the bones in diarthrodial joints. Across species, adult AC shows an arcade-like structure with collagen predominantly perpendicular to the subchondral bone near the bone, and collagen predominantly parallel to the articular surface near the articular surface. Recent studies into collagen fibre orientation in stillborn and juvenile animals showed that this structure is absent at birth. Since the collagen structure is an important factor for AC mechanics, the absence of the adult Benninghoff structure has implications for perinatal AC mechanobiology. The current objective is to quantify the dynamics of collagen network development in a model animal from birth to maturity. We further aim to show the presence or absence of zonal differentiation at birth, and to assess differences in collagen network development between different anatomical sites of a single joint surface. We use quantitative polarised light microscopy to investigate properties of the collagen network and we use the sheep (Ovis aries) as our model animal.     

Stretch-elicited calcium responses in the intact mouse thoracic aorta

Stretch-elicited intracellular calcium ([Ca(2+)](i)) changes in individual smooth muscle cells in a ring of aorta were measured simultaneously with the force developed by the ring. A phasic increase in [Ca(2+)](i) was observed in 30% of the cells and a sustained one in 10%. Depletion of intracellular calcium store by thapsigargin and caffeine decreased phasic and increased sustained calcium responses. The inhibition of calcium entry either by stretching the aorta in a calcium-free medium or by the inhibition of stretch-activated, non-selective cationic channels by 5 microM GsMtx-4 toxin, decreased the proportion of sustained [Ca(2+)](i) responses but increased transient responses. In this condition, a third of the cells responded to stretch by a bursts of [Ca(2+)](i) spikes. The decrease of calcium influx triggered the generation of burst of calcium spikes after the application of stretch steps to the vascular wall. We conclude that progressive recruitment of smooth muscle cells is the mechanism underlying the force-generating part of the myogenic response. Two types of stretch-elicited calcium responses were observed during the recruitment of the smooth muscle cells. One was a phasic calcium discharge generated by the sarcoplasmic reticulum. The second was a tonic response produced by the activation of the stretch-sensitive cationic channels allowing extracellular Ca(2+) entry.     

Elements of calcified sites in human thoracic aorta

To elucidate the manner of element accumulation in the arteries with aging, the authors investigated the element contents in the calcified and surrounding sites of the thoracic aortas by inductively coupled plasma-atomic emission spectrometry. The subjects consisted of three men and five women, ranging in age from 45 to 99 yr. The calcified, calcification-surrounding, and control (which appeared normal) sites were removed from the thoracic aortas and the element contents were determined. It was found that the contents of calcium, phosphorus, magnesium, zinc, and aluminum were higher in the calcified site than in the control site, whereas the contents of sulfur, iron, and lead were lower in the calcified site than in the control site. The contents of the elements in the surrounding site were intermediate between those of the calcified and control sites, except for the magnesium and lead contents, which were the lowest. The mass ratios of magnesium to calcium and phosphorus were lower in the calcified site compared with the surrounding and control sites, and as calcium and phosphorus increased in the aorta, the mass ratios lowered gradually in the aorta.     

Thermomechanical analysis of soft-tissue thermotherapy

Soft-tissue thermotherapy based on sub-ablative heating of collagenous tissues finds wide-spread application in medicine such as tissue welding, thermokeratoplasty, skin resurfacing, elimination of discogenic pain in the spine and treatment of joint instability. In this paper, heat-induced thermomechanical response characteristics of collagenous tissues are quantified by means of in vitro experimentation with a representative model tissue (New Zealand white rabbit patellar tendon). Three distinct heat-induced thermomechanical response regimes (defined by the rate of deformation and the variation of material properties) are identified. Arrhenius damage integral representation of collagenous tissue thermal history is shown to be adequate in establishing the master response curves for quantification of thermomechanical response for modeling purposes. The trade-off between the improved kinematical stability and compromised mechanical stability of the heated collagenous tissue is shown to be the major challenge hindering the success of subablative thermotherapies.     

Mechanical properties of elastin along the thoracic aorta in the pig

Understanding the mechanical environment of each component within the arterial wall is fundamental for understanding vascular growth and remodelling and for engineering artificial vascular conduits. We have investigated the mechanical status of arterial elastin by measuring the circumferential mechanical properties of purified elastin as function of position along the descending thoracic aorta of the pig. The tensile circumferential secant modulus, E(sec), measured in uniaxial mechanical tests, increased 30% (P<0.001), from a value of 0.88 MPa in the proximal tissue near the aortic arch to 1.14 MPa in the distal tissue near the diaphragm, indicating the stiffness of the elastin sample increased with position. Breaking stress was 54% higher in the distal tissue compared to the proximal (P<0.001), but the breaking stretch ratio did not change. E(sec) correlated with the ratio of radius to wall thickness measured in the no load state, r(nl)/h(nl), suggesting that the rise in stiffness was linked to ring morphology. The higher stiffness and strength of the distal tissue might be explained by a higher proportion of circumferentially oriented fibres in the distal tissue, which would indicate that the elastin meshwork in the thoracic aorta may become progressively anisotropic with distance from the heart. The ratio r(nl)/(h(nl)E (sec))rose only 7%, which suggests that the in vivo circumferential strain on the elastin may be constant along the pig thoracic aorta. The positional variation in elastin's properties should be taken into account in mechanical studies on purified elastin and in mathematical models of aorta mechanics.