Your search keyword '"Rose FR"' showing total 19 results

1. Adapting the Electrospinning Process to Provide Three Unique Environments for a Tri-layered In Vitro Model of the Airway Wall.

Author

Bridge JC, Aylott JW, Brightling CE, Ghaemmaghami AM, Knox AJ, Lewis MP, Rose FR, and Morris GE

Subjects

Adult, Cell Culture Techniques methods, Cell Differentiation physiology, Coculture Techniques methods, Extracellular Matrix physiology, Fibroblasts cytology, Humans, Myocytes, Smooth Muscle cytology, Polyethylene Terephthalates, Polymers, Porosity, Bronchioles cytology, Tissue Engineering methods, Tissue Scaffolds

Abstract

Electrospinning is a highly adaptable method producing porous 3D fibrous scaffolds that can be exploited in in vitro cell culture. Alterations to intrinsic parameters within the process allow a high degree of control over scaffold characteristics including fiber diameter, alignment and porosity. By developing scaffolds with similar dimensions and topographies to organ- or tissue-specific extracellular matrices (ECM), micro-environments representative to those that cells are exposed to in situ can be created. The airway bronchiole wall, comprised of three main micro-environments, was selected as a model tissue. Using decellularized airway ECM as a guide, we electrospun the non-degradable polymer, polyethylene terephthalate (PET), by three different protocols to produce three individual electrospun scaffolds optimized for epithelial, fibroblast or smooth muscle cell-culture. Using a commercially available bioreactor system, we stably co-cultured the three cell-types to provide an in vitro model of the airway wall over an extended time period. This model highlights the potential for such methods being employed in in vitro diagnostic studies investigating important inter-cellular cross-talk mechanisms or assessing novel pharmaceutical targets, by providing a relevant platform to allow the culture of fully differentiated adult cells within 3D, tissue-specific environments.

Published

2015

2. A novel technique for the production of electrospun scaffolds with tailored three-dimensional micro-patterns employing additive manufacturing.

Author

Rogers CM, Morris GE, Gould TW, Bail R, Toumpaniari S, Harrington H, Dixon JE, Shakesheff KM, Segal J, and Rose FR

Subjects

Animals, Cell Adhesion, Cell Proliferation, Cell Survival, Fibroblasts cytology, Lactic Acid chemistry, Mice, NIH 3T3 Cells, Polyglycolic Acid chemistry, Polylactic Acid-Polyglycolic Acid Copolymer, Electrochemical Techniques methods, Lactic Acid chemical synthesis, Polyglycolic Acid chemical synthesis, Tissue Engineering instrumentation, Tissue Scaffolds chemistry

Abstract

Electrospinning is a common technique used to fabricate fibrous scaffolds for tissue engineering applications. There is now growing interest in assessing the ability of collector plate design to influence the patterning of the fibres during the electrospinning process. In this study, we investigate a novel method to generate hybrid electrospun scaffolds consisting of both random fibres and a defined three-dimensional (3D) micro-topography at the surface, using patterned resin formers produced by rapid prototyping (RP). Poly(D,L-lactide-co-glycolide) was electrospun onto the engineered RP surfaces and the ability of these formers to influence microfibre patterning in the resulting scaffolds visualized by scanning electron microscopy. Electrospun scaffolds with patterns mirroring the microstructures of the formers were successfully fabricated. The effect of the resulting fibre patterns and 3D geometries on mammalian cell adhesion and proliferation was investigated by seeding enhanced green fluorescent protein labelled 3T3 fibroblasts onto the scaffolds. Following 24 h and four days of culture, the seeded scaffolds were visually assessed by confocal macro- and microscopy. The patterning of the fibres guided initial cell adhesion to the scaffold with subsequent proliferation over the geometry resulting in the cells being held in a 3D micro-topography. Such patterning could be designed to replicate a specific in vivo structure; we use the dermal papillae as an exemplar here. In conclusion, a novel, versatile and scalable method to produce hybrid electrospun scaffolds has been developed. The 3D directional cues of the patterned fibres have been shown to influence cell behaviour and could be used to culture cells within a similar 3D micro-topography as experienced in vivo.

Published

2014

3. A novel electrospun biphasic scaffold provides optimal three-dimensional topography for in vitro co-culture of airway epithelial and fibroblast cells.

Author

Morris GE, Bridge JC, Brace LA, Knox AJ, Aylott JW, Brightling CE, Ghaemmaghami AM, and Rose FR

Subjects

Cell Differentiation, Cell Line, Cell Proliferation, Electrochemical Techniques, Humans, Polymers chemical synthesis, Coculture Techniques instrumentation, Epithelial Cells cytology, Fibroblasts cytology, Polymers chemistry, Tissue Engineering instrumentation, Tissue Scaffolds chemistry

Abstract

Conventional airway in vitro models focus upon the function of individual structural cells cultured in a two-dimensional monolayer, with limited three-dimensional (3D) models of the bronchial mucosa. Electrospinning offers an attractive method to produce defined, porous 3D matrices for cell culture. To investigate the effects of fibre diameter on airway epithelial and fibroblast cell growth and functionality, we manipulated the concentration and deposition rate of the non-degradable polymer polyethylene terephthalate to create fibres with diameters ranging from nanometre to micrometre. The nanofibre scaffold closely resembles the basement membrane of the bronchiole mucosal layer, and epithelial cells cultured at the air-liquid interface on this scaffold showed polarized differentiation. The microfibre scaffold mimics the porous sub-mucosal layer of the airway into which lung fibroblast cells showed good penetration. Using these defined electrospinning parameters we created a biphasic scaffold with 3D topography tailored for optimal growth of both cell types. Epithelial and fibroblast cells were co-cultured onto the apical nanofibre phase and the basal microfibre phase respectively, with enhanced epithelial barrier formation observed upon co-culture. This biphasic scaffold provides a novel 3D in vitro platform optimized to mimic the different microenvironments the cells encounter in vivo on which to investigate key airway structural cell interactions in airway diseases such as asthma.

Published

2014

4. Human airway smooth muscle maintain in situ cell orientation and phenotype when cultured on aligned electrospun scaffolds.

Author

Morris GE, Bridge JC, Eltboli OM, Lewis MP, Knox AJ, Aylott JW, Brightling CE, Ghaemmaghami AM, and Rose FR

Subjects

Biocompatible Materials pharmacology, Cell Adhesion drug effects, Cell Culture Techniques, Cell Proliferation, Cells, Cultured, Cellular Microenvironment, Humans, Lung cytology, Models, Biological, Nanofibers, Cell Adhesion physiology, Muscle, Smooth cytology, Myocytes, Smooth Muscle cytology, Polyethylene Terephthalates pharmacology, Tissue Engineering methods, Tissue Scaffolds

Abstract

Human airway smooth muscle (HASM) contraction plays a central role in regulating airway resistance in both healthy and asthmatic bronchioles. In vitro studies that investigate the intricate mechanisms that regulate this contractile process are predominantly conducted on tissue culture plastic, a rigid, 2D geometry, unlike the 3D microenvironment smooth muscle cells are exposed to in situ. It is increasingly apparent that cellular characteristics and responses are altered between cells cultured on 2D substrates compared with 3D topographies. Electrospinning is an attractive method to produce 3D topographies for cell culturing as the fibers produced have dimensions within the nanometer range, similar to cells' natural environment. We have developed an electrospun scaffold using the nondegradable, nontoxic, polymer polyethylene terephthalate (PET) composed of uniaxially orientated nanofibers and have evaluated this topography's effect on HASM cell adhesion, alignment, and morphology. The fibers orientation provided contact guidance enabling the formation of fully aligned sheets of smooth muscle. Moreover, smooth muscle cells cultured on the scaffold present an elongated cell phenotype with altered contractile protein levels and distribution. HASM cells cultured on this scaffold responded to the bronchoconstrictor bradykinin. The platform presented provides a novel in vitro model that promotes airway smooth muscle cell development toward a more in vivo-like phenotype while providing topological cues to ensure full cell alignment., (Copyright © 2014 the American Physiological Society.)

Published

2014

5. Engineering an in-vitro model of rodent cartilage.

Author

Rogers CM, Woolley TS, Cruwys SC, Buttery LD, Rose FR, and Shakesheff KM

Subjects

Animals, Cartilage metabolism, Cattle, Cells, Cultured, Chondrocytes metabolism, Cytokines pharmacology, Fetal Research, Gene Expression, Gestational Age, Hypoxia, Models, Biological, Oxygen pharmacology, Phenotype, Rats, Wistar, Reference Values, Cartilage cytology, Chondrocytes cytology, Collagen metabolism, Rats embryology, Tissue Engineering methods

Abstract

Objectives: The purpose of this study was to identify a cell source, scaffold substrate and culture environment suitable for use in engineering an in-vitro model of rodent cartilage., Methods: The chondrogenic activity and stability of cells isolated at Day 18 of gestation was assessed under normoxia and hypoxia using a cytokine stimulation assay and gene expression analysis. The ability of the selected cells seeded in fibrous electrospun scaffolds to form cartilaginous tissue during longterm static and dynamic culture was assessed using immunocytochemistry and biochemical analysis., Key Findings: Rodent fetal chondrocytes appear to have enhanced phenotypic stability compared with other cell sources. Following 16 weeks under static culture, the engineered constructs were found to have greater cellularity and collagen content that native rodent cartilage., Conclusions: A cell source, scaffold and culture environment have been identified that support the generation of in-vitro rodent cartilage. In future work, cytokine treatment of the engineered tissues will take place to generate in-vitro osteoarthritis models., (© 2012 The Authors. JPP © 2012 Royal Pharmaceutical Society.)

Published

2012

6. Tissue engineering in the development of replacement technologies.

Author

Shakesheff KM and Rose FR

Subjects

Humans, Organ Specificity, Tissue Scaffolds, Tissue Engineering methods

Abstract

The field of tissue engineering is generating new scaffolds, bioreactors and methods for stimulating cells within complex cultures, with the aim of recreating the conditions under which cells form functional tissues. Hitherto, the primary focus of this field has been on clinical applications. However, there are many methods of in vitro tissue engineering that represent new opportunities in 3D cell culture and could be the basis for new replacement methods that either replace the use of a tissue isolated from an animal or the use of a living animal. This chapter presents an overview of tissue engineering and provides tissue-specific examples of recent advances.

Published

2012

7. Analysis of sintered polymer scaffolds using concomitant synchrotron computed tomography and in situ mechanical testing.

Author

Dhillon A, Schneider P, Kuhn G, Reinwald Y, White LJ, Levchuk A, Rose FR, Müller R, Shakesheff KM, and Rahman CV

Subjects

Bone and Bones pathology, Compressive Strength, Materials Testing, Microscopy, Electron, Scanning, Polyethylene Glycols chemistry, Polyglycolic Acid chemistry, Stress, Mechanical, Synchrotrons, Temperature, Polymers chemistry, Tissue Engineering methods, Tissue Scaffolds chemistry, Tomography, X-Ray Computed methods

Abstract

The mechanical behaviour of polymer scaffolds plays a vital role in their successful use in bone tissue engineering. The present study utilised novel sintered polymer scaffolds prepared using temperature-sensitive poly(DL-lactic acid-co-glycolic acid)/poly(ethylene glycol) particles. The microstructure of these scaffolds was monitored under compressive strain by image-guided failure assessment (IGFA), which combined synchrotron radiation computed tomography (SR CT) and in situ micro-compression. Three-dimensional CT data sets of scaffolds subjected to a strain rate of 0.01%/s illustrated particle movement within the scaffolds with no deformation or cracking. When compressed using a higher strain rate of 0.02%/s particle movement was more pronounced and cracks between sintered particles were observed. The results from this study demonstrate that IGFA based on simultaneous SR CT imaging and micro-compression testing is a useful tool for assessing structural and mechanical scaffold properties, leading to further insight into structure-function relationships in scaffolds for bone tissue engineering applications.

Published

2011

8. Preparation of Caco-2 cell sheets using plasma polymerised acrylic acid as a weak boundary layer.

Author

Majani R, Zelzer M, Gadegaard N, Rose FR, and Alexander MR

Subjects

Animals, Caco-2 Cells, Cell Survival drug effects, Elements, Glycolates pharmacology, Humans, Lactic Acid, Mice, Microscopy, Electron, Scanning, Polyglycolic Acid, Polylactic Acid-Polyglycolic Acid Copolymer, Surface Properties drug effects, Tissue Scaffolds chemistry, Acrylates pharmacology, Polymers chemistry, Tissue Engineering methods

Abstract

The use of cell sheets for tissue engineering applications has considerable advantages over single cell seeding techniques. So far, only thermoresponsive surfaces have been used to manufacture cell sheets without chemically disrupting the cell-surface interactions. Here, we present a new and facile technique to prepare sheets of epithelial cells using plasma polymerised acrylic acid films. The cell sheets are harvested by gentle agitation of the media without the need of any additional external stimulus. We demonstrate that the plasma polymer deposition conditions affect the viability and metabolic activity of the cells in the sheet and relate these effects to the different surface properties of the plasma polymerised acrylic acid films. Based on surface analysis data, a first attempt is made to explain the mechanism behind the cell sheet formation. The advantage of the epithelial cell sheets generated here over single cell suspensions to seed a PLGA scaffold is presented. The scaffold itself, prepared using a mould fabricated via photolithography, exhibits a unique architecture that mimics closely the dimensions of the native tissue (mouse intestine)., (Copyright 2010 Elsevier Ltd. All rights reserved.)

Published

2010

9. Tracking large solid constructs suspended in a rotating bioreactor: A combined experimental and theoretical study.

Author

Cummings LJ, Sawyer NB, Morgan SP, Rose FR, and Waters SL

Subjects

Models, Statistical, Bioreactors, Culture Media, Movement, Rotation, Suspensions, Tissue Engineering methods

Abstract

We present a combined experimental and theoretical study of the trajectory of a large solid cylindrical disc suspended within a fluid-filled rotating cylindrical vessel. The experimental set-up is relevant to tissue-engineering applications where a disc-shaped porous scaffold is seeded with cells to be cultured, placed within a bioreactor filled with nutrient-rich culture medium, which is then rotated in a vertical plane to keep the growing tissue construct suspended in a state of "free fall." The experimental results are compared with theoretical predictions based on the model of Cummings and Waters (2007), who showed that the suspended disc executes a periodic motion. For anticlockwise vessel rotation three regimes were identified: (i) disc remains suspended at a fixed position on the right-hand side of the bioreactor; (ii) disc executes a periodic oscillatory motion on the right-hand side of the bioreactor; and (iii) disc orbits the bioreactor. All three regimes are captured experimentally, and good agreement between theory and experiment is obtained. For the tissue engineering application, computation of the fluid dynamics allows the nutrient concentration field surrounding a tissue construct (a property that cannot be measured experimentally) to be determined (Cummings and Waters, 2007). The implications for experimental cell-culture protocols are discussed., (2009 Wiley Periodicals, Inc.)

Published

2009

10. Mathematical modelling of tissue-engineered angiogenesis.

Author

Lemon G, Howard D, Tomlinson MJ, Buttery LD, Rose FR, Waters SL, and King JR

Subjects

Algorithms, Animals, Cell Death physiology, Cell Hypoxia physiology, Chick Embryo, Chorioallantoic Membrane blood supply, Chorioallantoic Membrane cytology, Chorioallantoic Membrane growth & development, Chorioallantoic Membrane metabolism, Computer Simulation, Endothelial Cells cytology, Endothelial Cells metabolism, Extracellular Matrix metabolism, Fibroblasts cytology, Fibroblasts metabolism, Macrophages cytology, Macrophages metabolism, Microvessels anatomy & histology, Microvessels growth & development, Oxygen metabolism, Pericytes cytology, Pericytes metabolism, Time Factors, Transplants, Vascular Endothelial Growth Factor A metabolism, Models, Biological, Neovascularization, Physiologic physiology, Tissue Engineering methods, Tissue Scaffolds

Abstract

We present a mathematical model for the vascularisation of a porous scaffold following implantation in vivo. The model is given as a set of coupled non-linear ordinary differential equations (ODEs) which describe the evolution in time of the amounts of the different tissue constituents inside the scaffold. Bifurcation analyses reveal how the extent of scaffold vascularisation changes as a function of the parameter values. For example, it is shown how the loss of seeded cells arising from slow infiltration of vascular tissue can be overcome using a prevascularisation strategy consisting of seeding the scaffold with vascular cells. Using certain assumptions it is shown how the system can be simplified to one which is partially tractable and for which some analysis is given. Limited comparison is also given of the model solutions with experimental data from the chick chorioallantoic membrane (CAM) assay.

Published

2009

11. Investigation of cell-surface interactions using chemical gradients formed from plasma polymers.

Author

Zelzer M, Majani R, Bradley JW, Rose FR, Davies MC, and Alexander MR

Subjects

Allylamine chemistry, Animals, Cell Proliferation, Hexanes chemistry, Mice, Microscopy, Atomic Force, NIH 3T3 Cells, Spectrum Analysis, Surface Properties, Polymers chemistry, Tissue Engineering instrumentation

Abstract

This paper reports on the application of surface chemical gradients to study mammalian cell interactions with synthetic surfaces and investigates if the cell response on certain parts of the gradient is the same as that on uniform surfaces of equivalent chemistry. The gradients, formed using a diffusion-controlled plasma polymerisation technique, were fabricated such that cell response to a large range of different chemistries on a single sample could be investigated. Surface chemical gradients from hydrophobic plasma polymerised hexane (ppHex) to a more hydrophilic plasma polymerised allylamine (ppAAm), previously used to control cell density within 3D tissue-engineering scaffolds, were formed on glass coverslips. Surface characterisation was carried out to determine water contact angles (WCA), elemental composition, coating thickness and topography of the chemical gradients. Cell response was assessed following culture of 3T3 fibroblasts on both steep and shallow gradients. Fibroblasts adhered and proliferated preferentially on ppAAm (WCA approximately 60 degrees ) showing a gradual decreasing cell density towards the hydrophobic ppHex (WCA approximately 93 degrees ). Experiments on a uniform ppAAm surface revealed that there was a significant difference in cell density when compared to the gradient samples. The initial number of cells that adhered to the surface was confirmed as the difference between the uniform and graduated ppAAm samples, and it is assumed that this difference relates to different cell-cell signalling processes and/or greater protein production from surrounding cells on these two samples formats.

Published

2008

12. Mathematical modelling of human mesenchymal stem cell proliferation and differentiation inside artificial porous scaffolds.

Author

Lemon G, Waters SL, Rose FR, and King JR

Subjects

Biocompatible Materials, Cell Differentiation drug effects, Cell Differentiation physiology, Cell Hypoxia physiology, Cell Proliferation drug effects, Extracellular Matrix drug effects, Extracellular Matrix metabolism, Humans, Mesenchymal Stem Cells drug effects, Oxygen pharmacology, Mesenchymal Stem Cells cytology, Models, Biological, Tissue Engineering methods

Abstract

We present a mathematical model for the proliferation and differentiation of human mesenchymal stem cells grown inside artificial porous scaffolds under different oxygen concentrations. The values of parameters in the model are determined by comparison of the model solutions to published experimental data, complemented with a sensitivity analysis of the fitted parameters. It is shown that a simple hypothesis whereby the secretion of extra-cellular matrix (ECM) is oxygen dependent and that ECM itself stimulates cell proliferation is sufficient to explain the experimental data, which under conditions of low oxygen reveals increased total cell proliferation, upregulation of the numbers of undifferentiated cells, and extended lag phase. These results may help further to understand how cells proliferate inside artificial materials and are of importance to the field of tissue engineering.

Published

2007

13. Cell adhesion and mechanical properties of a flexible scaffold for cardiac tissue engineering.

Author

Hidalgo-Bastida LA, Barry JJ, Everitt NM, Rose FR, Buttery LD, Hall IP, Claycomb WC, and Shakesheff KM

Subjects

Animals, Cell Adhesion, Cell Culture Techniques, Cell Line, Citrates chemistry, Coated Materials, Biocompatible chemistry, Collagen chemistry, Collagen metabolism, Collagen ultrastructure, Elastomers chemistry, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Extracellular Matrix ultrastructure, Fibronectins chemistry, Fibronectins metabolism, Laminin chemistry, Laminin metabolism, Laminin ultrastructure, Materials Testing, Mice, Microscopy, Electron, Scanning, Myocytes, Cardiac cytology, Myocytes, Cardiac ultrastructure, Polymers chemistry, Porosity, Tomography, X-Ray Computed, Citrates metabolism, Coated Materials, Biocompatible metabolism, Elastomers metabolism, Myocytes, Cardiac physiology, Polymers metabolism, Tissue Engineering methods

Abstract

Cardiac tissue engineering is focused on obtaining functional cardiomyocyte constructs to provide an alternative to cellular cardiomyoplasty. Mechanical stimuli have been shown to stimulate protein expression and the differentiation of mammalian cells from contractile tissues. Our aim was to obtain a flexible scaffold which could be used to apply mechanical forces during tissue regeneration. Poly(1,8-octanediol-co-citric acid) (POC) is an elastomer that can be processed into scaffolds for tissue engineering. We investigated the effect of modifying the porosity on the mechanical properties of the POC scaffolds. In addition, the effects of the storage method and strain rate on material integrity were assessed. The maximum elongation of POC porous films varied from 60% to 160% of their original length. A decrease in the porosity caused a rise in this elastic modulus. The attachment of HL-1 cardiomyocytes to POC was assessed on films coated with fibronectin, collagen and laminin. These extracellular matrix proteins promoted cell adhesion in a protein-type- and concentration-dependent manner. Therefore, POC scaffolds can be optimised to meet the mechanical and biological parameters needed for cardiac culture. This porous material has the potential to be used for cardiac tissue engineering as well as for other soft tissue applications.

Published

2007

14. The effect of anisotropic architecture on cell and tissue infiltration into tissue engineering scaffolds.

Author

Silva MM, Cyster LA, Barry JJ, Yang XB, Oreffo RO, Grant DM, Scotchford CA, Howdle SM, Shakesheff KM, and Rose FR

Subjects

Animals, Chondrocytes ultrastructure, Humans, Microscopy, Electron, Scanning, Sheep, Tumor Cells, Cultured, Chondrocytes cytology, Tissue Engineering

Abstract

A common phenomenon in tissue engineering is rapid tissue formation on the outer edge of the scaffold which restricts cell penetration and nutrient exchange to the scaffold centre, resulting in a necrotic core. To address this problem, we generated scaffolds with both random and anisotropic open porous architectures to enhance cell and subsequent tissue infiltration throughout the scaffold for applications in bone and cartilage engineering. Hydroxyapatite (HA) and poly(D,L-lactic acid) (P(DL)LA) scaffolds with random open porosity were manufactured, using modified slip-casting and by supercritical fluid processing respectively, and subsequently characterised. An array of porous aligned channels (400 microm) was incorporated into both scaffold types and cell (human osteoblast sarcoma, for HA scaffolds; ovine meniscal fibrochondrocytes, for P(DL)LA scaffolds) and tissue infiltration into these modified scaffolds was assessed in vitro (cell penetration) and in vivo (tissue infiltration; HA scaffolds only). Scaffolds were shown to have an extensive random, open porous structure with an average porosity of 85%. Enhanced cell and tissue penetration was observed both in vitro and in vivo demonstrating that scaffold design alone can influence cell and tissue infiltration into the centre of tissue engineering scaffolds.

Published

2006

15. Tissue growth in a rotating bioreactor. Part I: mechanical stability.

Author

Waters SL, Cummings LJ, Shakesheff KM, and Rose FR

Subjects

Algorithms, Animals, Cell Culture Techniques instrumentation, Cell Culture Techniques methods, Gravitation, Humans, Mechanics, Rheology, Rotation, Tissue Engineering methods, Bioreactors, Models, Biological, Tissue Engineering instrumentation

Abstract

We develop mathematical models to provide insights into the morphology of a tissue construct formed from a single-cell suspension in culture media, within a rotating bioreactor. The bioreactor consists of a cylindrical vessel of circular cross-section rotating about its longitudinal axis with constant angular speed. Experimental studies show that at rotation rates below a critical value, the cells 'self-assemble' to form smooth 'nodules' that are approximately cylindrical with elliptical cross-section; however, at rotation rates above a critical value, an amorphous construct forms with a highly irregular boundary. The construct is denser than the surrounding culture media and histological studies indicate that the interior of the construct, which is a mix of apoptotic cells and culture media, is surrounded by an outer rim of proliferating cells and collagen. The construct is modelled as a viscous fluid drop surrounded by an extensible membrane in a (less dense) immiscible viscous fluid within a rotating bioreactor. We consider both thin-disk and slender-pipe bioreactors for which the aspect ratio, L(*)/a(*) (where L(*) and a(*) are the bioreactor length and radius, respectively), is small and large, respectively, and obtain a series of spatially 2D problems (independent of the axial coordinate). We then examine the hypothesis that the construct morphology is a result of the mechanical forces that it experiences by considering the interfacial stability of an initially circular fluid-fluid interface to small-amplitude, oscillatory perturbations. The instability is driven by the density difference between the two fluids, and we investigate the effect of the rotation rate, the (time-dependent) gravitational field, and the material and geometrical properties of the system on the stability properties.

Published

2006

16. Zonal release of proteins within tissue engineering scaffolds.

Author

Suciati T, Howard D, Barry J, Everitt NM, Shakesheff KM, and Rose FR

Subjects

Animals, Bone Morphogenetic Protein 2, Bone Morphogenetic Proteins pharmacokinetics, Cell Line, Horseradish Peroxidase pharmacokinetics, Humans, Mice, Microspheres, Transforming Growth Factor beta pharmacokinetics, Biocompatible Materials, Growth Substances pharmacokinetics, Proteins pharmacokinetics, Tissue Engineering

Abstract

The manufacture of a scaffold for tissue engineering applications that can control the location and timing of growth factor release is described. The scaffold is formed by the sintering of poly(DL-lactic acid) (P(DL)LA) microparticles, plasticized with poly(ethylene glycol) (PEG), although the method can be used for many other polymer types. The microparticles were loaded with model proteins, trypsin and horseradish peroxidase (HRP), or recombinant human bone morphogenetic protein-2 (rhBMP-2). Entrapment efficiencies above 75% were achieved using a solid-in-oil-in-water system. Controlled release of active protein was achieved for at least 30 days. Microparticles were built into protein-loaded or protein-free layers and release of the protein was restricted to zones within the scaffold. Cell response to rhBMP-2 was tuneable by changing the dose of the rhBMP-2 released by varying the ratio of protein-loaded and protein-free microparticles within scaffolds. Zonal activity of rhBMP-2 on C2C12 cells was demonstrated. The scaffolds may find utility in applications where gradients of growth factors within 3D templates are required or where zonation of tissue growth is required.

Published

2006

17. The influence of dispersant concentration on the pore morphology of hydroxyapatite ceramics for bone tissue engineering.

Author

Cyster LA, Grant DM, Howdle SM, Rose FR, Irvine DJ, Freeman D, Scotchford CA, and Shakesheff KM

Subjects

Compressive Strength, Materials Testing, Molecular Conformation, Particle Size, Porosity, Powders, Bone Substitutes chemistry, Ceramics chemistry, Durapatite chemistry, Surface-Active Agents chemistry, Tissue Engineering methods

Abstract

There is a clinical need for synthetic scaffolds that will promote bone regeneration. Important factors include obtaining an optimal porosity and size of interconnecting windows whilst maintaining scaffold mechanical strength, enabling complete penetration of cells and nutrients throughout the scaffold, preventing the formation of necrotic tissue in the centre of the scaffold. To address this we investigated varying slip deflocculation in order to control the resulting porosity, pore size and interconnecting window size whilst maintaining mechanical strength. Hydroxyapatite (HA) porous ceramics were prepared using a modified slip casting process. Rheological measurements of the HA slips were used to identify deflocculation conditions which resulted in changes in the cell and window sizes of the resulting ceramics. Sintered ceramics were characterised by X-ray diffraction (XRD) and scanning electron microscopy (SEM). Pore and window size distribution was determined by SEM. XRD analysis confirmed that the crystal structure remained HA after the sintering process. SEM showed that HA porous ceramics presented a highly interconnected porous network with average pore sizes ranging from 391+/-39 to 495+/-25 microm. The average window size varied from 73+/-5 to 135+/-7 microm. Pore diameters obtained were controllable in the range 200-500 microm. Window sizes were in the range 30-250 microm. The use of dispersant concentration allows pore and window size to be modified whilst maintaining control over porosity demonstrated by a porosity of 85% for seven different dispersant concentrations. The advantage of this approach allows the correlation between the rheological conditions of the slip and the resultant sintered ceramic properties. In particular, optimising the ceramic strength by controlling the agglomeration during the casting process.

Published

2005

18. Seeding cells into needled felt scaffolds for tissue engineering applications.

Author

Unsworth JM, Rose FR, Wright E, Scotchford CA, and Shakesheff KM

Subjects

Animals, Cattle, Biocompatible Materials, Chondrocytes, Tissue Engineering

Abstract

Tissue engineering methods are under development that will enable the repair or replacement of a variety of tissues, including articular cartilage and bone. To engineer functional tissue it is necessary that scaffolds initially be seeded with a large number of cells distributed evenly throughout the scaffold structure. It previously has been shown that, compared to static seeding conditions, seeding scaffolds under dynamic conditions facilitates high seeding densities and even distributions of cells (Li et al., Biotechnology Progress 2001;17:935-944). The efficiency of seeding HOSTE85 cells and bovine chondrocytes into needled felt scaffolds following agitation at different speeds was determined. Seeding efficiency was determined using the Hoechst 33258 assay, and cell viability was assessed using the Alamar Blue trade mark assay. The distribution of cells within the scaffolds was imaged using scanning electron microscopy. It was found that the optimum seeding conditions varied for HOSTE85 cells and bovine chondrocytes, with different agitation speeds leading to different seeding efficiencies, cell viabilities, and distributions of cells within scaffolds. The optimum agitation speeds for seeding a high number of viable cells into scaffolds so that they were arranged evenly were 300 rpm for HOSTE85 cells and 200 rpm for bovine chondrocytes., (Copyright 2003 Wiley Periodicals, Inc.)

Published

2003

19. Bone tissue engineering: hope vs hype.

Author

Rose FR and Oreffo RO

Subjects

Bone Substitutes, Fractures, Bone therapy, Genetic Therapy, Growth Substances therapeutic use, Hematopoietic Stem Cells physiology, Humans, Models, Biological, Bone Regeneration, Tissue Engineering methods

Abstract

The requirement for new bone to replace or restore the function of traumatised, damaged, or lost bone is a major clinical and socioeconomic need. Bone formation strategies, although attractive, have yet to yield functional and mechanically competent bone. Bone tissue engineering has been heralded as the alternative strategy to regenerate bone. In essence, the discipline aims to combine progenitor or mature cells with biocompatible materials or scaffolds, with or without appropriate growth factors, to initiate repair and regeneration. This brief review outlines the concepts, challenges, and limitations in bone tissue engineering and the potential that could improve the quality of life for many as a result of interdisciplinary collaboration., ((C)2002 Elsevier Science (USA).)

Published

2002