Thermal analyses of hydrophilic polymers used in nanocomposites and biocompatible coatings

Mohomed, Kadine

01 June 2006

ABSRACT: This research focuses on two hydrophilic polymers that form hydrogels when they sorb water: Poly(2-hydroxyethyl methacrylate) (PHEMA) and Poly(2,3-dihydroxypropyl methacrylate) (PDHPMA). Present work in the field obviated the need to properly characterize the thermal and dielectric properties of these materials.The dielectric permittivity, e', and the loss factor, e", of dry poly(2-hydroxyethyl methacrylate) and poly(2,3-dihydroxypropyl methacrylate) were measured using a dielectric analyzer in the frequency range of 0.1Hz to 100 kHz and between the temperature range of -150 °C to 275°C. The dielectric response of the sub-Tg gamma transition of PHEMA has been widely studied before but little to no DEA data above 50°C is present in the literature. This study is the first to present the full range dielectric spectrum of PHEMA, PDHPMA and their random copolymers up to and above the glass transition region. The electric modulus formalism and several mathematical proofs were used to reveal the gamma, beta, alpha and conductivity relaxations. Dielectric analysis gives insight into the network structure of the polymer; it has been shown through thermal analyses that as the DHPMA content increased in HEMA-DHPMA copolymers the polymer matrix increased in available free volume and facilitated the movement of ions in its matrix. This is of significance as we then investigated the feasibility of using PHEMA, PDHPMA and their random copolymers as materials for a biocompatible coating for an implantable glucose sensor. The biocompatibility of hydrogels can be attributed to the low interfacial tension with biological fluids, high gas permeability, high diffusion of low molecular weight compounds, and reduced mechanical and frictional irritation to surrounding tissue. Once the biocompatibility of the hydrogels was established, the task to coat the polyurethane (PU)/epoxy coated metal glucose sensor was addressed. Plasma polymerization was found to be the most feasible technique for the application of the biocompatible hydrogel as a coating on the implantable glucose sensor. It has also been shown that thermal analysis techniques provide a mode of investigation that can be used to investigate the interfacial interactions of a novel hydroxylated, self-assembled nanoparticle with two functionally different polymers, poly(2-dihydroxyethyl methacrylate) and poly(methyl methacrylate).

Poly(2-hydroxyethyl methacrylate)

Poly(2,3-dihydroxypropyl methacrylate)

Dielectric analysis

Hydrogel

American Studies

Arts and Humanities

Smart Packaging: A Novel Technique For Localized Drug Delivery For Ovarian Cancer

Williams, Eva Christabel

01 January 2012

Localized drug delivery is emerging as an effective technique due to its ability to administer therapeutic concentrations and controlled release of drugs to cancer sites in the body. It also prevents the contact of harsh chemotherapy drugs to healthy regions in the body that otherwise would become exposed to current treatments. This study reports on a model chemotherapy drug delivery system comprising non-ionic surfactant vesicles (niosomes) packaged within a temperature-sensitive chitosan network. This smart packaging, or package-within-a package system, provides two distinct advantages. First, the gel prevents circulation of the niosomes and maintains delivery in the vicinity of a tumor. Secondly, the chitosan network protects the niosomes against fluctuations in tonicity, which affects delivery rates. Tonicity is the sum of the concentrations of the solutes which have the capacity to exert an osmotic force across the membrane. Release rates were monitored from both bare niosomes alone and niosome-embedded, chitosan networks. It was observed that chitosan networks prolonged delivery from 100 hours to 55 days in low ionic strength environment and pH conditions similar to a tumor site. The primary effect of chitosan is to add control on release time and dosage, and stabilize the niosomes through a high ionic strength surrounding that prevents uncontrolled bursting of the niosomes. Secondary factors include cross-link density of the chitosan network, molecular weight of the individual chitosan polymers, dye concentration within the niosomes, and the number density of niosomes packaged within the chitosan network. Each of these factors can be altered to fine-tune release rates. Release rate experiments were conducted with 5,6-carboxyfluorescein, a fluorescent dye and chemotherapeutics paclitaxel and carboplatin. In vitro studies showed a preferential affinity of the smart packaged system to ovarian carcinoma cell line OV2008 as compared to normal epithelial cell lines of Ilow and MCC3. Further, feasibility of the drug delivery system was evaluated in vivo. Toxicity studies revealed that the system was non-toxic and feasible in vivo. The final outcome of this study includes tuning of the variables mentioned above that will contribute to the development of low cost and improved methods for drug delivery with application to intracavitary ovarian cancer treatment and other types of cancer

cell culture

chitosan

confocal microscopy

niosome

thermo-responsive hydrogel

xenogen

American Studies

Arts and Humanities

Chemical Engineering

Digital Microfluidics for Multidimensional Biology

Eydelnant, Irwin Adam

09 January 2014

Digital microfluidics (DMF) has emerged in the past decade as a novel microfluidic paradigm. As a liquid handling technology, DMF facilitates the electrostatic manipulation of discrete nano- and micro- litre droplets across open electrode arrays providing the advantages of single sample addressability, automation, and parallelization. This thesis presents DMF advances toward improved functionality and compatibility for automated miniaturized cell culture in two and three dimensions. Through the development and integration of surface patterning techniques we demonstrate a virtual microwell method for high precision on-device reagent dispensing in one and two plate DMF geometries. These methods are shown to be compatible with two-dimensional culture of immortalized cell lines on ITO, primary cells on coated surfaces, and for co-culture assays. We further extrapolate this method for the formation of microgels on-demand where form micro scale hydrogel structures through passive dispensing in a wide array of geometries. With this system we interrogate three-dimensional cell culture models, specifically for the recapitulation of kidney epthelialization and the analysis of functional cardiac microgels.

Digital microfluidics

Microfluidics

Biology

Cell culture

3D cell culture

hydrogel

0541

Digital Microfluidics for Multidimensional Biology

Eydelnant, Irwin Adam

09 January 2014

Digital microfluidics (DMF) has emerged in the past decade as a novel microfluidic paradigm. As a liquid handling technology, DMF facilitates the electrostatic manipulation of discrete nano- and micro- litre droplets across open electrode arrays providing the advantages of single sample addressability, automation, and parallelization. This thesis presents DMF advances toward improved functionality and compatibility for automated miniaturized cell culture in two and three dimensions. Through the development and integration of surface patterning techniques we demonstrate a virtual microwell method for high precision on-device reagent dispensing in one and two plate DMF geometries. These methods are shown to be compatible with two-dimensional culture of immortalized cell lines on ITO, primary cells on coated surfaces, and for co-culture assays. We further extrapolate this method for the formation of microgels on-demand where form micro scale hydrogel structures through passive dispensing in a wide array of geometries. With this system we interrogate three-dimensional cell culture models, specifically for the recapitulation of kidney epthelialization and the analysis of functional cardiac microgels.

Digital microfluidics

Microfluidics

Biology

Cell culture

3D cell culture

hydrogel

0541

The controlled release of rat adipose-derived stem cells from alginate microbeads for bone regeneration

Leslie, Shirae

16 September 2013

Cell-based therapies have potential for tissue regeneration but poor delivery methods lead to low viability or dispersal of cells from target sites, limiting clinical utility. Here, we developed a degradable and injectable hydrogel to deliver stem cells for bone regeneration. Alginate microbeads <200µm are injectable, persist at implantation sites and contain viable cells, but do not readily degrade in-vivo. We hypothesized that controlled release of rat adipose-derived stem cells (ASCs) from alginate microbeads can be achieved by incorporating alginate-lyase in the hydrogel. Microbeads were formed using high electrostatic potential. Controlled degradation was achieved through direct combination of alginate-lyase and alginate at 4°C. Results showed that microbead degradation and cell release depended on the alginate-lyase to alginate ratio. Viability of released cells ranged from 87% on day 2 to 71% on day 12. Monolayer cultures of released ASCs grown in osteogenic medium produced higher levels of osteocalcin and similar levels of other soluble factors as ASCs that were neither previously encapsulated nor exposed to alginate-lyase. Bmp2, Fgf2, and Vegfa mRNA in released cells were also increased. Thus, this delivery system allows for controlled release of viable cells and can modulate their downstream osteogenic factor production.

Cell encapsulation

Alginate degradation

Hydrogel

Stem cells

Bone regeneration

Fractures Treatment

Cellular therapy

Modular Approach to Adipose Tissue Engineering

Butler, Mark James

29 August 2011

Despite the increasing clinical demand in reconstructive, cosmetic and correctional surgery there remains no optimal strategy for the regeneration or replacement of adipose tissue. Previous approaches to adipose tissue engineering have failed to create an adipose tissue depot that maintains implant volume in vivo long-term (>3 months). This is due to inadequate mechanical properties of the biomaterial and insufficient vascularization upon implantation. Modular tissue engineering is a means to produce large volume functional tissues from small sub-mm sized tissues with an intrinsic vascularization. We first explored the potential of a semi-synthetic collagen/poloxamine hydrogel with improved mechanical properties to be used as the module biomaterial. We found this biomaterial to not be suitable for adipose tissue engineering because it did not support embedded adipose-derived stem cell (ASC) viability, differentiation and human microvascular endothelial cell (HMEC) attachment. ASC-embedded collagen gel modules coated with HMEC were then implanted subcutaneously in SCID mice to study its revascularization potential. ASC cotransplantation was shown to drive HMEC vascularization in vivo: HMEC were seen to detach from the surface of the modules to form vessels containing erythrocytes as early as day 3; vessels decreased in number but increased in size over 14 days; and persisted for up to 3 months. Early vascularization promoted fat development. Only in the case of ASC-HMEC cotransplantation was progressive fat accumulation observed in the module implants. Although implant volume was not maintained, likely due rapid collagen degradation, the key result here is that ASC-HMEC cotransplantation in the modular approach was successful in creating vascularized adipose tissue in vivo that persisted for 3 months. The modular system was then studied in vitro to further understand ASC-EC interaction. Coculture with ASC was shown to promote an angiogenic phenotype (e.g. sprouting, migration) from HUVEC on modules. RT-PCR analysis revealed that VEGF, PAI-1 and TNFα was involved in ASC-EC paracrine signalling. In summary, ASC-HMEC cotransplantation in modules was effective in rapidly forming a vascular network that supported fat development. Future work should focus on further elucidating ASC-EC interactions and developing a suitable biomaterial to improve adipose tissue development and volume maintenance of engineered constructs.

Adipose Tissue Engineering

Adipose-derived Stem Cells

Regenerative Medicine

Biomaterials

Cotransplantation

In Vivo

Revascularization

Hydrogel

0542

0541

Development of a Biomimetic Scaffold for Ligament Tissue Engineering

Hayami, James W.S.

22 June 2011

The focus of this thesis was to design a scaffold for in vitro culture that would mimic the structure of the native ligament in order to influence primary ligament cells towards the production of ligament-specific tissue. A major part of this project was material selection and subsequent testing to determine if the chosen materials were suitable for the scaffold design. A 20:80 (CL:DLLA) poly(ε-caprolactone-co-D,L-lactide) copolymer (PCLDLLA) was synthesized and electrospun with sub-cellular fibre diameters. The fibres were manufactured into aligned arrays to mimic the collagen fibrils of the ligament. To enhance cell and protein adhesion properties, the PCLDLLA polymer surface was modified using a base catalyzed etching technique. A photocrosslinked methacrylated glycol chitosan (M-GC) hydrogel was used to deliver encapsulated ligament cells to the biomimetic scaffold and mimic the hydrated proteoglycan matrix portion of the ligament. The scaffolds were cultured in vitro for a 4 week period and characterized using immunohistochemistry to identify and localize ligament specific proteins produced within the scaffolds. Cell culture results indicated that the M-GC hydrogel was an effective method of delivering viable cells evenly throughout the biomimetic scaffold. Compared to the unmodified PCLDLLA surfaces, the base-etched electrospun PCLDLLA fibre surfaces increased cell adhesion and acted as new tissue growth guides in the biomimetic scaffold. The biomimetic scaffolds produced and accumulated ligament specific proteins: collagens type I and III. The biomimetic scaffold design was determined to be a viable alternative to the current designs of ligament tissue engineering scaffolds. / Thesis (Master, Chemical Engineering) -- Queen's University, 2011-06-22 10:46:12.291

Ligament Tissue Engineering

Electrospun Self-Crimping Fibres

Hydrogel Cell Encapsulation

Composite Scaffold

Modular Approach to Adipose Tissue Engineering

Butler, Mark James

29 August 2011

Despite the increasing clinical demand in reconstructive, cosmetic and correctional surgery there remains no optimal strategy for the regeneration or replacement of adipose tissue. Previous approaches to adipose tissue engineering have failed to create an adipose tissue depot that maintains implant volume in vivo long-term (>3 months). This is due to inadequate mechanical properties of the biomaterial and insufficient vascularization upon implantation. Modular tissue engineering is a means to produce large volume functional tissues from small sub-mm sized tissues with an intrinsic vascularization. We first explored the potential of a semi-synthetic collagen/poloxamine hydrogel with improved mechanical properties to be used as the module biomaterial. We found this biomaterial to not be suitable for adipose tissue engineering because it did not support embedded adipose-derived stem cell (ASC) viability, differentiation and human microvascular endothelial cell (HMEC) attachment. ASC-embedded collagen gel modules coated with HMEC were then implanted subcutaneously in SCID mice to study its revascularization potential. ASC cotransplantation was shown to drive HMEC vascularization in vivo: HMEC were seen to detach from the surface of the modules to form vessels containing erythrocytes as early as day 3; vessels decreased in number but increased in size over 14 days; and persisted for up to 3 months. Early vascularization promoted fat development. Only in the case of ASC-HMEC cotransplantation was progressive fat accumulation observed in the module implants. Although implant volume was not maintained, likely due rapid collagen degradation, the key result here is that ASC-HMEC cotransplantation in the modular approach was successful in creating vascularized adipose tissue in vivo that persisted for 3 months. The modular system was then studied in vitro to further understand ASC-EC interaction. Coculture with ASC was shown to promote an angiogenic phenotype (e.g. sprouting, migration) from HUVEC on modules. RT-PCR analysis revealed that VEGF, PAI-1 and TNFα was involved in ASC-EC paracrine signalling. In summary, ASC-HMEC cotransplantation in modules was effective in rapidly forming a vascular network that supported fat development. Future work should focus on further elucidating ASC-EC interactions and developing a suitable biomaterial to improve adipose tissue development and volume maintenance of engineered constructs.

Adipose Tissue Engineering

Adipose-derived Stem Cells

Regenerative Medicine

Biomaterials

Cotransplantation

In Vivo

Revascularization

Hydrogel

0542

0541

Die Rekonstruktion des Unterkiefers bei Knochendefekten mit einer Kombination aus rhBMP-2, einer synthetischen Polyethylenglycol-Matrix und Calciumphosphat -Eine Pilotstudie am Göttinger Minipig / The reconstruction of mandibular bone defects using a combination of rhBMP -2, a synthetic polyethylene glycol hydrogel and calcium phosphate -A pilot study in Göttingen minipigs

Krohn, Sebastian

28 April 2015

No description available.

610

bone morphogenetic protein 2

jawbone defects

maxillomandibular reconstruction

polyethylene glycol hydrogel

Medizin (PPN619874732)

NANOSCALE FUNCTIONALIZATION AND CHARACTERIZATION OF SURFACES WITH HYDROGEL PATTERNS AND BIOMOLECULES

Chirra Dinakar, Hariharasudhan

01 January 2010

The advent of numerous tools, ease of techniques, and concepts related to nanotechnology, in combination with functionalization via simple chemistry has made gold important for various biomedical applications. In this dissertation, the development and characterization of planar gold surfaces with responsive hydrogel patterns for rapid point of care sensing and the functionalization of gold nanoparticles for drug delivery are highlighted. Biomedical micro- and nanoscale devices that are spatially functionalized with intelligent hydrogels are typically fabricated using conventional UV-lithography. Herein, precise 3-D hydrogel patterns made up of temperature responsive crosslinked poly(N-isopropylacrylamide) over gold were synthesized. The XY control of the hydrogel was achieved using microcontact printing, while thickness control was achieved using atom transfer radical polymerization (ATRP). Atomic force microscopy analysis showed that to the ATRP reaction time governed the pattern growth. The temperature dependent swelling ratio was tailored by tuning the mesh size of the hydrogel. While nanopatterns exhibited a broad lower critical solution temperature (LCST) transition, surface roughness showed a sharp LCST transition. Quartz crystal microbalance with dissipation showed rapid response behavior of the thin films, which makes them applicable as functional components in biomedical devices. The easy synthesis, relative biocompatibility, inertness, and easy functionalization of gold nanoparticles (GNPs) have made them useful for various biomedical applications. Although ATRP can be successfully carried out over GNPs, the yield of stable solution based GNPs for biomedical applications prove to be low. As an alternative approach, a novel method of ISOlating, FUnctionalizing, and REleasing nanoparticles (ISOFURE) was proposed. Biodegradable poly(β-amino ester) hydrogels were used to synthesize ISOFURE-GNP composites. ATRP was performed inside the composite, and the final hydrogel coated GNPs were released via matrix degradation. Response analysis confirmed that the ISOFURE method led to the increased stability and yield of the hydrogel coated ISOFURE-GNPs. The ISOFURE protocol was also utilized in functionalizing GNPs with enzyme catalase in the absence of a stabilizing reagent. Biotin-streptavidin affinity was used as the bioconjugation method. Activity analysis of the conjugated enzyme showed that the ISOFURE-GNPs showed enhanced biomolecular loading relative to solution based stabilizing reagent passivated GNPs.

Hydrogel

Gold nanoparticle

ISOFURE

Atom transfer radical polymerization

Microcontact printing

Chemical Engineering

Nanoscience and Nanotechnology