Investigation into the phase separation behavior of concentrated elastin-like polypeptide solutions

WAN, JIA, HONG

24 August 2016

No description available.

Biomedical Engineering

Polymers

Elastin-like polypeptides

transition temperature

phase transition behavior

phase diagram

Structural Breakdown of Collagen Type I Elastin Blend Polymerization

Wilharm, Nils, Fischer, Tony, Hayn, Alexander, Mayr, Stefan Georg

12 July 2024

Biopolymer blends are advantageous materials with novel properties that may show performances way beyond their individual constituents. Collagen elastin hybrid gels are a new representative of such materials as they employ elastin’s thermo switching behavior in the physiological temperature regime. Although recent studies highlight the potential applications of such systems, little is known about the interaction of collagen and elastin fibers during polymerization. In fact, the final network structure is predetermined in the early and mostly arbitrary association of the fibers. We investigated type I collagen polymerized with bovine neck ligament elastin with up to 33.3 weight percent elastin and showed, by using a plate reader, zeta potential and laser scanning microscopy (LSM) experiments, that elastin fibers bind in a lateral manner to collagen fibers. Our plate reader experiments revealed an elastin concentration-dependent increase in the polymerization rate, although the rate increase was greatest at intermediate elastin concentrations. As elastin does not significantly change the structural metrics pore size, fiber thickness or 2D anisotropy of the final gel, we are confident to conclude that elastin is incorporated homogeneously into the collagen fibers.

info:eu-repo/classification/ddc/540

ddc:540

Following historical 'tracks' of hair follicle miniaturisation in patterned hair loss: Are elastin bodies the forgotten aetiology?

Rushton, D.H., Westgate, Gillian E., Van Neste, D.J.

09 June 2021

Yes / Pattern Hair Loss (PHL) is a chronic regressive condition of the scalp, where follicular miniaturisation and decreased scalp hair coverage occurs in affected areas. In all PHL cases there is a measurable progressive shortening of the terminal hair growth duration, along with reduced linear growth rates. In both genders, PHL initially shows an increase in short telogen hairs ≤30mm in length, reflecting a cycle completion of under six months in affected terminal hair follicles. To understand the miniaturisation process, we re-examine the dynamics of miniaturisation and ask the question, 'why do miniaturised hair follicles resist treatment?' In the light of recent developments in relation to hair regeneration, we looked back in the older literature for helpful clues 'lost to time' and reprise a 1978 Hermann Pinkus observation of an array of elastin deposits beneath the dermal papilla following subsequent anagen/telogen transitions in male balding, originally described by Arao and Perkins who concluded that these changes provide a "morphologic marker of the entire biologic process in the balding scalp". Thus, we have reviewed the role of the elastin-like bodies in hair pathology and we propose that alterations in elastin architecture may contribute to the failure of vellus-like hair reverting back to their terminal status and may indicate a new area for therapeutic intervention.

Androgenetic alopecia

Dermis

Elastin body

Hair follicle

Hair follicle miniaturisation

Vellus hair

Biaxial Mechanical Evaluation of Uterosacral and Cardinal Ligaments

Baah-Dwomoh, Adwoa Sarpong

06 March 2018

The uterosacral ligament (USL) and the cardinal ligament (CL) are two major suspensory tissues that provide structural support to the vagina/cervix/uterus complex. These ligaments have been studied mainly due for their role in the surgical repair for pelvic organ prolapse (POP). POP, which is the descent of a pelvic organ from its normal place towards the vaginal walls and into the vaginal cavity, affects an estimated 3.3 million women in the United States annually. Despite their important mechanical function, little is known about the elastic and viscoelastic properties of the USL and CL due to ethical concerns with in vivo testing of human tissues and the lack of accepted animal models. The goal of this first study is to help establish an appropriate animal model for studying the mechanics of these pelvic supportive ligaments. To achieve this, the first rigorous comparison of histological and planar equi-biaxial mechanical properties of the swine and human USLs was completed. Relative collagen, smooth muscle, and elastin contents were quantified from histological sections and the USL was found to have similar components in both species, with a comparable relative collagen content. Using the digital image correlation (DIC) method to calculate the in-plane Lagrangian strain, no differences in the peak strain during precon- ditioning/cyclic loading tests, secant modulus of the pre-creep/elastic response, and strain at the end of creep tests were detected in the USLs from the two species along both axial loading directions (the main in vivo loading direction and the direction that is perpendicular to it). Because these ligaments are subjected to repeated constant loads in vivo, the effect of re- peated biaxial loads at three different load levels (1 N, 2 N, or 3 N) on elastic and creep properties of the swine CL was investigated. The results showed that CL was elastically anisotropic, as statistical differences were found between the mean strains along the two axial loading directions for specimens at all three different load levels. The increase in strain over time by the end of the 3rd creep test was comparable along the axial loading direc- tions. The greatest mean normalized strain (or, equivalently, the largest increase in strain over time) was measured at the end of the 1st creep test, regardless of the equi-biaxial load magnitude or loading direction. Overall, these experimental findings validate the use of swine as an appropriate animal model and offer new knowledge of the mechanical properties of the USL and CL that can guide the development of better treatment methods such as surgical reconstruction for POP. / Ph. D. / The uterosacral ligament (USL) and the cardinal ligament (CL) are two major suspensory tissues that provide structural support to the vagina/cervix/uterus complex. These ligaments have been studied mainly due for their role in the surgical repair for pelvic organ prolapse (POP). POP, which is the descent of a pelvic organ from its normal place towards the vaginal walls and into the vaginal cavity, affects an estimated 3.3 million women in the United States annually. Despite their important mechanical function, little is known about the elastic and viscoelastic properties of the USL and CL due to ethical concerns with in vivo testing of human tissues and the lack of accepted animal models. The goal of this first study is to help establish an appropriate animal model for studying the mechanics of these pelvic supportive ligaments. To achieve this, the first rigorous comparison of histological and planar equi-biaxial mechanical properties of the swine and human USLs was completed. Relative collagen, smooth muscle, and elastin contents were quantified from histological sections and the USL was found to have similar components in both species, with a comparable relative collagen content. Using the digital image correlation (DIC) method to calculate the in-plane Lagrangian strain, no differences in the peak strain during preconditioning/cyclic loading tests, secant modulus of the pre-creep/elastic response, and strain at the end of creep tests were detected in the USLs from the two species along both axial loading directions (the main in vivo loading direction and the direction that is perpendicular to it). Because these ligaments are subjected to repeated constant loads in vivo, the effect of repeated biaxial loads at three different load levels (1 N, 2 N, or 3 N) on elastic and creep properties of the swine CL was investigated. The results showed that CL was elastically anisotropic, as statistical differences were found between the mean strains along the two axial loading directions for specimens at all three different load levels. The increase in strain over time by the end of the 3rd creep test was comparable along the axial loading directions. The greatest mean normalized strain (or, equivalently, the largest increase in strain over time) was measured at the end of the 1st creep test, regardless of the equi-biaxial load magnitude or loading direction. Overall, these experimental findings validate the use of swine as an appropriate animal model and offer new knowledge of the mechanical properties of the USL and CL that can guide the development of better treatment methods such as surgical reconstruction for POP.

Uterosacral Ligament

Cardinal Ligament

Viscoelasticity

Creep

Histology

Collagen

Smooth Muscle

Elastin

Characterization and Biomedical Applications of Recombinant Silk-Elastinlike Protein Polymers

Teng, Weibing

January 2012

Biomaterials requirements nowadays are becoming more and more specialized to meet increasingly demanding needs for biomedical applications such as matrices for tissue scaffolds. Among various useful classes of biomaterials, protein-based materials have been extensively pursued as they can offer a wide range of material properties to accommodate a broader spectrum of functional and performance requirements. The advent of genetic engineering and recombinant DNA technology has enabled the production of new protein-based biopolymers with precisely controlled amino acid sequence. As an example, silk-elastinlike protein (SELP) polymers consisting of polypeptide sequences from native silk of remarkable mechanical strength and polypeptide sequences from native elastin that is extremely durable and resilient have been produced. In this dissertation, a particular silk-elastinlike protein copolymer, SELP-47K, was cast into film form, and fully characterized for its material properties, including the mechanical property, secondary structure transition, optical transparency, surface, and other physical, chemical properties. The relationship between mechanical property and protein secondary structure was investigated as well. In addition, the material property tunability which can be induced by physical, mechanical, and chemical treatments has been explored. It is worth noting that the physically crosslinked SELP-47K films displayed mechanical properties comparable to those of native elastin obtained from bovine ligament. Secondary structure study through Raman and FTIR spectra showed that methanol treatment is capable of inducing theβ-sheet crystallization of silklike blocks, which act as physical crosslinks in the protein polymer chain network, thus stabilizing the protein structure and conferring the improved material integrity. The SELP-47K protein polymer thin films displayed excellent optical transparency. In particular, its excellent optical transmittance (over 90%) in visible light range may indicate SELPs can be a family of promising biomaterial candidate for ocular applications. Besides material property characterization, SELP-47K protein polymer has been fabricated into a variety of drug delivery devices to sustainably release a common ocular antibiotic, ciprofloxacin over a period of up to 220 h, with near-first order kinetics.

Protein-Based Materials

Protein Secondary Structure

Self-Assembly

Silk-Elastin-Like Protein Polymers

Mechanical Engineering

Drug Delivery

Mechanical Characterization

Multi-photon microscopy of cartilage

Mansfield, Jessica

January 2008

Articular cartilage has been imaged using the following multi-photon modalities: Second Harmonic Generation (SHG), Two-photon Fluorescence (TPF) and Coherent Anti-Stokes Raman Scattering (CARS). A simple epi detection microscope was constructed for SHG and TPF imaging in the early stages of this research. Later the imaging was transferred to a new microscope system which allowed simultaneous forwards and epi detection and combined CARS imaging with TPF and SHG. Multiphoton spectroscopic studies were conducted on both intact tissue samples and the major components of the extracellular matrix, in order to identify sources of TPF. Fluorescence was detected from type II collagen, elastin and samples of purified collagen and elastin crosslinks. Age related glycation crosslinks of collagen may be a significant source of TPF. No fluorescence was detected from proteoglycans. In intact, unfixed healthy articular cartilage the cells were observed via CARS, surrounded in their pericellular matrix which is characterised by an increase in TPF. The collagen of the extra cellular matrix showed up clearly in the SHG images. Diseased cartilage was also imaged revealing microscopic lesion at the articular surface in early osteoarthritis and highly fibrous collagen structures and cell clusters in more advanced degeneration. In young healthy cartilage a network of elastin fibres were found lying parallel to the articular surface in the most superficial 50μm of the tissue. Regional variations in these fibres were also investigated. The fibres appeared mainly long and straight suggesting that they may be under tension, further work is needed to identify whether they have a mechanical function. The polarization sensitivity of the SHG from collagen has been investigated for both cartilage and tendon. In the most superficial tissue these measurements can be used directly to determine the collagen fibre orientation. However at increasing depths the effects of biattenuation and birefringence must be considered. Healthy cartilage has a characteristic pattern of polarization sensitivity with depth and this changes at lesions indicating a disruption of the normal collagen architecture. The methods developed in this thesis demonstrate the use of non-linear microscopy to visualise the structure of the extracellular matrix and cells in intact unstained tissue. They should also be appropriate in many areas of cell and matrix biology.

611.0183

Intracranial aneurysm disease : novel modelling of inception and the microstructural adaption of collagen fabric

Chen, Haoyu

January 2014

An intracranial aneurysm (IA) is a balloon-like focal lesion on the cerebral arterial wall. IAs are poorly understood, but are commonly considered to be a disease caused by multiple factors. Current interventional treatments are accompanied with risks. Given the low incidence of rupture, it would be ideal to only treat aneurysms identified with rupture risk. Numerical models of aneurysm development may provide insight into the disease mechanisms, and contribute to the prediction of disease progression. Better understanding of the disease aetiology will also guide clinical decision making. Different hypotheses have been proposed on the influence of haemodynamic stimuli on IA inception. We investigate this influence by examining the haemodynamic stimuli of the 'pre-aneurysmal' vasculature in the locations of IA formation in 22 clinical cases. The 'pre aneurysmal' geometries are obtained by applying a novel numerical vessel reconstruction method on the aneurysmal geometries. This automated reconstruction method propagates a closed curve along the vessel skeleton using the local Frenet frames to smoothly morph the upstream boundary into the downstream boundary. We observe that locally elevated wall shear stress (WSS) and gradient oscillatory number (GON) are highly correlated with regions susceptible to sidewall IA formation, whilst haemodynamic indices associated with the oscillation of the WSS vectors have much lower correlations. A common assumption made in the literature on arterial growth and remodelling (G&R) is that the 'state of stretch' (denoted as the attachment stretch) at which collagen fibres are configured in the extracellular matrix (ECM) is assumed to be constant. This will lead to an unrealistically thickened arterial wall in modelling aneurysm evolution. We propose a novel 1D mathematical model of collagen microstructural adaption during IA evolution. We assume new collagen fibres are configured into the ECM in a state of attachment stretch distribution which can be temporally adaptive. We explicitly define the functional form of this distribution and model its temporal adaption during IA evolution. This model is then implemented into two 3D models of IA evolution: a solid structural model and Fluid-Solid-Growth (FSG) model. In the solid structural model, the artery is modelled as a two-layer, nonlinear elastic cylindrical membrane using a physiologically realistic constitutive model. The development of the aneurysm is considered as a consequence of the growth and remodelling of its material constituents: elastinous constituents are prescribed to degrade in a localised circular patch; collagen concentration and recruitment variables enable the growth and remodelling of collagen fabric to be simulated; adaption of the attachment stretch distribution is confined locally within the region of aneurysm evolution. The sophisticated solid model predicts stabilised saccular IAs with realistic sizes and wall thicknesses. The FSG model simulates the IA development on patient-specific vasculature: the updated 3D solid structural model is integrated into a patient-specific geometry of the vasculature and the growth and remodelling of the constituents is now linked to the local haemodynamic stimuli obtained from a rigid-wall computational fluid dynamics analysis. Adaption of the attachment stretch distribution is also confined locally in the region where the constituents degrade. An illustrative case of IA development on patient specific geometry is provided. Based on our study, we conclude that incorporating the adaption of attachment stretch distribution is necessary to simulate IA evolution with physiological evolving wall thicknesses. However, how vascular cells confine this adaption heterogeneously needs further investigation. Improved understanding and modelling of the biology of the arterial wall is needed for more sophisticated models of aneurysm evolution. It will in turn assist in understanding the aetiology of IA formation. Ultimately we hope to have a patient-specific growth model that could have the potential be used to assist diagnostic decisions.

610.28

Rôle des peptides de l’élastine dans la progression des carcinomes broncho-pulmonaires / Role of elastin-derived peptides in tumor progression of lung carcinomas

Toupance, Simon

29 September 2011

Au cours de l'invasion tumorale, la matrice extracellulaire du tissu broncho-pulmonaire, riche en élastine, subit de nombreux remaniements. La dégradation de cette élastine conduit à la production de peptides bioactifs. Ces peptides d'élastine (PE) possèdent un récepteur spécifique, le complexe récepteur de l'élastine (CRE), et peuvent également interagir avec l'intégrine alphavbeta3 et la galectine-3. Dans cette étude, nous avons étudié le rôle des PE et de leurs récepteurs dans la progression tumorale des carcinomes broncho-pulmonaires.Des cellules épithéliales bronchiques tumorales sont incubées in vitro avec un mélange de PE, la kappa-élastine (kE), ou avec des peptides synthétiques. Le traitement par les peptides entraine une augmentation de la capacité infiltrante des cellules invasives associée à un relargage précoce de MMP 2, MMP 9 et uPA mais n'a pas d'effet sur la prolifération et le phénotype cellulaire. Les niveaux d'ARNm des 3 protéases stimulées ne sont pas modifiés et ni l'actinomycine D, ni le cycloheximide ou la bréfeldine A ne sont capables d'inhiber les effets liés à la kE. Ces effets ne sont pas non plus inhibés par le lactose et les autres antagonistes des trois récepteurs. Enfin, les peptides VGVAPG et GRKRK, présentant les séquences spécifiques reconnues par les récepteurs, ne réussissent pas à reproduire les effets observés avec la kE, alors que des nonapeptides les reproduisent de façon quasi-identique.Ces résultats montrent que les PE régulent la capacité invasive des carcinomes broncho-pulmonaires, via le relargage d'enzymes protéolytiques. Cette modulation mettrait en jeu des mécanismes post-traductionnels et un récepteur lactose-insensible, différent du CRE, de l'intégrine alphavbeta3 et de la galectine-3, et reconnaissant des nonapeptides d'élastine. / Elastin-rich lung extra-cellular matrix is largely remodeled during tumor invasion. Elastin degradation produces peptides displaying a wide range of biological activities. These elastin derived peptides (EP) interact with the Elastin Receptor Complex (ERC) but also bind to alphaVbeta3 integrin and galectin-3. In this study, we explored the role of EP and their receptors in tumor progression of lung carcinomas.In vitro, lung tumor cells were incubated in presence of kappa-elastin (kE), a mix of EP or with synthetic elastin peptides. EP treatment induced an increase of invasive capacity of invasive cells with quickly increased levels of MMP-2, MMP 9 and uPA but had no effect on cell proliferation and phenotype. Interestingly, protease regulation was not observed at the mRNA level and actinomycin D, cycloheximide and brefeldin A were unable to inhibit kE effects. These effects could not be inhibited either by classical receptor antagonists including lactose or blocking antibodies. Finally, synthetic peptides VGVAPG and GRKRK, displaying receptor-specific sequences, failed to reproduce kE effects whereas nonapeptides partially mimicked them.These results demonstrate that treatment with EP up-regulates invasiveness of lung tumor cells via the release of proteolytic enzymes. This modulation involves post-translational mechanisms and a lactose-insensitive receptor, different from the ERC, alphaVbeta3 integrin and galectin-3 and recognizing nonapeptidic sequences.

Peptides d’élastine

Cancers broncho-pulmonaires

Invasion tumorale

MMPs

Urokinase

Elastin-derived peptides

Lung cancers

Tumor invasion

MMPs

Urokinase

610

Reparo de defeito femoral em ratos através do uso de polí­meros de colágeno e elastina associados a hidroxiapatita e proteína morfogenética óssea / Repair of femoral defect in rats through the use of collagen and elastin polymers associated with hydroxyapatite and bone morphogenetic protein

Machado, Eduardo Gomes

23 March 2018

Na presença de fraturas, infecções ou tumores ósseos que ocasionem perda extensa de tecido ósseo, existe a necessidade da utilização de enxerto ósseo autólogo. Apesar deste método ser considerado o padrão-ouro, apresenta algumas desvantagens, como a morbidade da área doadora e limitação do volume a ser obtido. Alternativamente, são considerados como uma importante opção de tratamento, os implantes com biomateriais. Dentre eles, destacam-se as esponjas de colágeno, hidroxiapatita e proteína morfogenética óssea (BMP). A elastina atualmente esta sendo investigada como nova opção para substrato na regeneração tecidual. Assim, o objetivo deste projeto foi avaliar o processo de reparo de defeitos ósseos enxertados com estes biomateriais. Foram estudados 77 animais da seguinte forma: Grupo 1 (G1-C): ratos com defeito crítico induzido no osso femoral direito, sem preenchimento com implante (grupo controle). Grupo 2 (G2-E24/37): animais com defeito produzido no fêmur distal direito, preenchido com membrana de elastina 24h a 37ºC. Grupo 3 (G3-E24/37+HA): animais com defeito produzido no fêmur distal direito, preenchido com membrana de elastina 24h a 37ºC + hidroxiapatita. Grupo 4 (G4-E24/37+BMP): animais com defeito produzido no fêmur distal direito, preenchido com membrana de elastina 24h a 37ºC + BMP. Grupo 5 (G5-C24/25): animais com defeito produzido no fêmur distal direito, preenchido com membrana de colágeno da serosa de intestino porcino 24h a 25ºC. Grupo 6 (G6-C24/25+HA): animais com defeito produzido no fêmur distal direito, preenchido com membrana de colágeno da serosa de intestino porcino 24h a 25ºC + hidroxiapatita. Grupo 7 (G7-C24/25+BMP): animais com defeito produzido no fêmur distal direito, preenchido com membrana de colágeno da serosa de intestino porcino 24h a 25ºC + BMP. As análises demonstraram a biocompatibilidade das membranas devido a ausência de elementos celulares característicos de processo inflamatório. A membrana de elastina isolada ou associada a hidroxiapatita não apresentou resultados superiores ao grupo controle, apenas quando associada à BMP, o resultado foi superior ao controle. A membrana de colágeno isolada ou associada à BMP ou hidroxiapatita apresentaram resultados superiores ao controle. Os biomateriais estudados apresentaram capacidade osteogênica e houve osteointegração na falha óssea induzida experimentalmente. / Bone lesions as fractures, infections or bone tumors can cause extensive bone loss. In this scenario, the use of any type of bone augments is advocated. Although autollogus bone graft is considered the gold standard, some disadvantages are related with this method such as donor area morbidity and limited availability of graft material. Alternatively, implants with biomaterials are considered an important option. Among them, the sponges of collagen, hydroxyapatite and BMP show outstanding results. Elastin is currently being investigated as a new substrate option in tissue regeneration. Thus, the objective of this project was to evaluate the repair process of bone defects grafted with these biomaterials. A total of 77 animals were studied as follows: Group 1 (G1-C): rats with critical defect induced in the right femoral bone, without implant filling (control group). Group 2 (G2-E24/37): animals with defect produced in the right distal femur, filled with elastin membrane. Group 3 (G3-E24/37 + HA): animals with defect produced in the right distal femur, filled with elastin membrane plus hydroxyapatite. Group 4 (G4-E24/37 + BMP): animals with defect produced in the right distal femur, filled with elastin membrane plus BMP. Group 5 (G5-C24/25): animals with defect produced in the right distal femur, filled with porcine intestinal serosa collagen membrane. Group 6 (G6-C24/25 + HA): animals with defect produced in the right distal femur, filled with porcine intestine serous collagen membrane plus hydroxyapatite. Group 7 G7-C24/25 + BMP: animals with defect produced in the right distal femur, filled with porcine intestinal serosa collagen membrane plus BMP. The analyzes demonstrated the biocompatibility of the membranes due to the absence of cellular elements characteristic of inflammatory process. The elastin membrane isolated or associated with hydroxyapatite did not present superior results to the control group. The result was superior to the control only when elastin was associated with BMP. The collagen membrane isolated or associated with BMP or hydroxyapatite presented superior results to control. The studied biomaterials presented osteogenic capacity and osseointegration in experimentally induced bone failure.

Biocompatible materials

Bone morphogenetic receptors

Colágeno

Collagen

Elastin

Elastina

Hidroxiapatita

Materiais biocompatíveis

Osseointegração

Osseointegration

Elastin synthesis in the fetal sheep lung in vivo : effects of physical, metabolic and endocrine factors

Joyce, Belinda Jane

January 2004

Abstract not available

Elastin -- Synthesis

Lungs -- Growth

Sheep -- Fetuses -- Physiology

Fetus -- Growth

Fetal growth retardation