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Rapid and Uniform Cell Seeding on Fibrin Microthreads to Generate Tissue Engineered MicrovesselsParekh, Darshan P 05 May 2010 (has links)
A wide variety of techniques have been explored to synthesize small diameter tissue engineered blood vessels. Toward this end, we are exploring direct cell seeding and culture on tubular mandrels to create engineered vascular tissues. In the present study, v-shaped channels cast from polydimethyl siloxane (PDMS) were used as cell seeding wells. Fibrin microthreads placed in the chamber were used as model tubular seeding mandrels. Human mesenchymal stem cells (hMSCs) were seeded onto fibrin microthreads in v-shaped channels for 4 hours. Cell attachment to the microthreads was confirmed visually by Hoechst nuclear staining and a cell quantification assay showed that 5,114 ± 339 cells attached per 1 cm fibrin microthread sample (n = 6). Fibrin microthreads were completely degraded by hMSCs within 5 days of culture, therefore UV crosslinking was used to increase their mechanical strength and prolong the amount of time cells could be cultured on fibrin microthreads and generate tubular tissue constructs. Cell attachment was unaffected on UV-crosslinked microthreads compared to uncrosslinked microthreads, resulting in a count of 4,944 ± 210 cells per 1 cm of fibrin microthread sample (n = 3). Long term culture of the hMSCs on the UV-crosslinked fibrin microthreads showed an increase in cell number over time to 11,198 ± 582 cells per cm of microthread after 7 days with 92% cell viability (CYQUANT NF/DEAD staining) and evidence of cell proliferation. The results show that the v-well cell seeding technique was effective in promoting rapid hMSC attachment on UV-crosslinked fibrin microthreads and encouraged their growth, maintained viability and also promoted their proliferation over the culture period. In conclusion, the technique could serve as an efficient model system for rapid formation of tissue engineered vascular grafts.
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Development of an <i>in vitro</i> three-dimensional model for colon cancer study and drug efficacy analysisRobinson, Clayt Austin 24 August 2005 (has links)
No description available.
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Development of Bio-Impedance microprobes for Integration with a Smart Biopsy toolJayabalan, Vivek 14 November 2014 (has links)
Biopsy is a standard practice in the diagnosis and treatment of many cancers. Despite its integral role in cancer diagnosis, in some instances, the biopsy tool facilitates metastasis by transferring cancerous cells attached to its exterior into the healthy tissue or the blood circulation during its retraction from the tumor. These few cancer cells can then serve as seeds for the malignant tumor to grow in the healthy tissue. Cauterization using extreme heat or cold can destroy cells in the region and minimize the chance of seeding but this can be an inexact process that increases damage to otherwise healthy tissue and prolongs healing time following a biopsy procedure.
In our laboratory, we have developed the concept of a new smart biopsy tool that can reduce the chance of cancer cell dissemination during a biopsy. This tool improves on the conventional biopsy needle by introducing an impedance sensor on the biopsy tool which is housed in a sliding sheath. Due to the significant difference in the electrical conductivity of the tumor and the healthy tissue, the sensor is able to distinguish between the two and locate the exact tumor interface. The protective sheath placed around the instrumented biopsy tool and above the interface isolates the healthy tissue and prevents or at least minimizes the transfer of tumor cells. Delivering an RF dose through the sheath can kill any malignant cells that might be lurking around the interface.
This thesis, in particular, will concentrate on the development of the design, fabrication and calibration of the impedance sensor and its integration with the biopsy tool. The impedance sensor essentially consists of conductive electrodes sandwiched between insulating layers. They are built on thin-film polymer, Polyimide, using conventional microfabrication techniques. These sensors are further calibrated to estimate the cell constant. Once calibrated, these probes are used to measure the conductivity of porcine tissues, and in-house prepared agar phantoms. / Master of Science
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Improvement of the Tissue-Engineered Vascular Graft and Discovery of a Novel ImmunomodulatorBest, Cameron A. 09 October 2019 (has links)
No description available.
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ELUCIDATING BIOPHYSICAL CUES CONDUCIVE TO TARGETED MULTIPOTENT CELL DIFFERENTIATIONMcBride, Sarah January 2008 (has links)
No description available.
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New scaffolding materials for the regeneration of infarcted myocardiumArnal Pastor, María Pilar 16 January 2015 (has links)
There is growing interest in the development of biomimetic matrices that are simultaneously
cell-friendly, allow rapid vascularization, exhibit enough mechanical integrity to be comfortably
handled and resist mechanical stresses when implanted in the site of interest. Meeting all these
requirements with a single component material has proved to be very challenging.
The hypothesis underlying this work was that hybrid materials obtained by combining scaffolds
with bioactive hydrogels would result in a synergy of their best properties: a construct with
good mechanical properties, easily handled and stable thanks to the scaffold; but also, because
of the gel, cell-friendly and with enhanced oxygen and nutrients diffusion, and promoter of cell
colonization. Moreover, such a composite material would also be useful as a controlled release
system because of the gel’s incorporation.
Poly (ethyl acrylate) (PEA) scaffolds prepared with two different morphologies were envisaged
to provide the mechanical integrity to the system. Both types of scaffolds were physicochemically
characterized and the effect of the scaffolds production process on the PEA
properties was examined. The scaffolds preparation methods affected the PEA properties;
nevertheless, the modifications induced were not detrimental for the PEA biological
performance.
Two different bioactive gels were studied as fillers of the scaffolds’ pores: hyaluronan (HA),
which is a natural polysaccharide, and a synthetic self-assembling peptide, RAD16-I. HA is
ubiquitously present in the body and its degradation products have been reported to be
angiogenic. RAD16-I is a synthetic polypeptide that mimics the extracellular matrix providing a
favourable substrate for cell growth and proliferation.
Given the hydrophobic nature of poly(ethyl acrylate), the combination of PEA scaffolds with
aqueous gels raised a number of problems regarding the methods to combine such different
elements, the ways to gel them inside the pores, and the procedures to seed cells in the new
composite materials. Different alternatives to solve these questions were thoroughly studied and
yielded protocols to reliably obtain these complex structures and their biohybrids.
An extensive physico-chemical characterization of the components’ interaction and the
combined systems was undertaken. As these materials were intended for cardiac tissue
engineering applications, the mechanical properties and the effect of the fatigue on them were studied. The different composite systems here developed were homogeneously filled or coated
with the hydrogels, were easy to manipulate, and displayed appropriate mechanical properties.
Interestingly, these materials exhibited a very good performance under fatigue.
The use of the composite systems as a controlled release device was based on the possibility of
incorporating active soluble molecules in the hydrogel within the pores. A release study of
bovine serum albumin (BSA), intended as a model protein, was performed, which served as a
proof of concept.
The biological performance of the hybrid scaffolds was first evaluated with fibroblasts to discard
the materials cytotoxicity and to optimize the cell seeding procedure. Subsequently, human
umbilical vein endothelial cells (HUVECs) cultures were performed for their interest in
angiogenic and vascularization processes. Finally, co-cultures of HUVECs with adipose-tissue
derived mesenchymal cells (MSCs) were carried out. These last cells are believed to play an
important role for clinical regenerative medicine, and their cross-talk with the endothelial cells
enhances the viability and phenotypic development of HUVECs. Through the different
experiments undertaken, hybrid scaffolds exceeded the outcome achieved by bare PEA scaffolds. / Arnal Pastor, MP. (2014). New scaffolding materials for the regeneration of infarcted myocardium [Tesis doctoral]. Editorial Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/46129 / Premios Extraordinarios de tesis doctorales
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Tailoring of Biomaterials using Ionic Interactions : Synthesis, Characterization and ApplicationAtthoff, Björn January 2006 (has links)
<p>The interactions between polymers and components of biological systems are an important area of interest within the fields of tissue engineering, polymer chemistry, medicine and biomaterials. In order to create such a biomimetic material, it must show the inherent ability to reproduce or elicit a biological function. How do we design synthetic materials in order to direct their interactions with biological systems?</p><p>This thesis contributes to this research with aspects of how polymers interact with biological materials with the help of ionic interactions. Polyesters, biodegradable or not, may after a hydrolytic cleavage interact ionically with protonated amines by the liberated carboxylate functions. Amines are found in proteins and this fact will help us to anchor proteins to polyester surfaces. Another type of interaction is to culture cells in polymeric materials, i.e. scaffolds. We have been working on compliant substrates, knitted structures, to allow cell culture in three dimensions. A problem that arises here is how to get a high cell seeding efficiency? By working on the interactions between polymers, proteins and finally cells, it is possible to create a polarized protein membrane that allows for very efficient cell seeding, and subsequent three dimensional cell cultures. Finally a synthetic route to taylor interaction was developed. Here a group of polymers known as ionomers were synthesized. In our case ionic end groups have been placed onto biodegradable polycarbonates, we have created amphiphilic telechelic ionomers. Functionalization, anionic or cationic, changes the properties of the material in many ways due to aggregation and surface enrichment of ionic groups. It is possible to add functional groups for a variety of different interactions, for example introducing ionic groups that interact and bind to the complementary charge of proteins or on the other hand one can chose groups to prevent protein interactions, like the phosphorylcholine zwitterionomers. Such interactions can be utilized to modulate the release of proteins from these materials when used in protein delivery applications. The swelling properties, Tg, degradation rate and mechanical properties are among other things that will easily be altered with the choice of functional groups or backbone polymer.</p>
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Tailoring of Biomaterials using Ionic Interactions : Synthesis, Characterization and ApplicationAtthoff, Björn January 2006 (has links)
The interactions between polymers and components of biological systems are an important area of interest within the fields of tissue engineering, polymer chemistry, medicine and biomaterials. In order to create such a biomimetic material, it must show the inherent ability to reproduce or elicit a biological function. How do we design synthetic materials in order to direct their interactions with biological systems? This thesis contributes to this research with aspects of how polymers interact with biological materials with the help of ionic interactions. Polyesters, biodegradable or not, may after a hydrolytic cleavage interact ionically with protonated amines by the liberated carboxylate functions. Amines are found in proteins and this fact will help us to anchor proteins to polyester surfaces. Another type of interaction is to culture cells in polymeric materials, i.e. scaffolds. We have been working on compliant substrates, knitted structures, to allow cell culture in three dimensions. A problem that arises here is how to get a high cell seeding efficiency? By working on the interactions between polymers, proteins and finally cells, it is possible to create a polarized protein membrane that allows for very efficient cell seeding, and subsequent three dimensional cell cultures. Finally a synthetic route to taylor interaction was developed. Here a group of polymers known as ionomers were synthesized. In our case ionic end groups have been placed onto biodegradable polycarbonates, we have created amphiphilic telechelic ionomers. Functionalization, anionic or cationic, changes the properties of the material in many ways due to aggregation and surface enrichment of ionic groups. It is possible to add functional groups for a variety of different interactions, for example introducing ionic groups that interact and bind to the complementary charge of proteins or on the other hand one can chose groups to prevent protein interactions, like the phosphorylcholine zwitterionomers. Such interactions can be utilized to modulate the release of proteins from these materials when used in protein delivery applications. The swelling properties, Tg, degradation rate and mechanical properties are among other things that will easily be altered with the choice of functional groups or backbone polymer.
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