Nanoparticles for multifunctional drug delivery systems

Qin, Jian

January 2007

<p>Multifunctional drug delivery systems incorporated with stimuli-sensitive drug release, magnetic nanoparticles and magnetic resonance (MR) <em>T</em>₂ contrast agents is attracting increasing attention recently. In this thesis, works on polymer nanospheres response to temperature change, superparamagnetic iron oxide nanoparticles (SPION)/polymeric composite materials for MR imaging contrast agents are summarized.</p><p>A “shell-in-shell” polymeric structure has been constructed through a “modified double-emulsion method”. Thermosensitive inner shell is comprised of poly(<em>N</em>-isopropylacrylamide) which undergoes phase transition at body temperature. Such a feature could facilitate drug release at an elevated temperature upon administration. Furthermore, the dual-shell structure is covered by a layer of gold nanoparticles. According to the cytotoxicity tests, the biocompatibility is shown to be enhanced due to the layer of gold.</p><p>SPION have been prepared using a high temperature decomposition method. Particle growth of SPION is monitored by transmission electron microscope and synchrotron X-ray diffraction. Poly(L,L-lactide)@SPION (PLLA@SPION) composite particles have been prepared through surface-initiated ring-opening polymerization which has been developed in our lab. For biomedical applications, it is essential to transfer the particles to physiological solutions from organic solutions. Phase transfer of SPION has been carried out by utilizing small molecules. Stability at the neutral pH is of large concern for such transfer systems. A novel phase transfer agent, Pluronic F127 (PF127), a triblock copolymer has been applied and the stability of the aqueous PF127@oleic acid (OA)@SPION solution has been greatly enhanced over a broad pH range. Most interestingly, PF127@OA@SPION show remarkable efficacy as T2 contrast agents as indicated by relaxometric measurements compared with commercially available products.</p>

drug delivery

stimuli-sensitive

SPION

PLLA

PNIPAAm

gold

MRI

cytotoxicity

Pluronic

phase transfer

Materials chemistry

Materialkemi

Poly-N-isopropylacrylamide-based Thermoresponsive Hydrogels for Retinal Pigment Epithelial Cell Delivery

Amaral, Nicole

January 2021

Despite being the most prevalent presentation of Age-Related Macular Degeneration (AMD), dry AMD (dAMD) lacks a therapeutic treatment. Retinal pigment epithelium (RPE) dysfunction preceding the onset of dAMD has inspired interest in regenerative medicine approaches seeking to replenish the RPE and preserve visual acuity. Cell delivery to the subretinal space however has been met with challenges surrounding ease of access and invasive surgical implantation. Two-dimensional scaffolds have made use of natural and polymeric materials to act as carriers for RPE cells and various progenitor lines. These substrates mitigate issues surrounding the handling of delicate cell sheets harvested for transplant. As well, they are often successful in preserving RPE phenotype, supporting growth, and can be fine tuned to possess morphologies comparable to native extracellular matrix (ECM). Despite aiming to act as replacement Bruch’s membrane on which RPE resides, two-dimensional substrates are often notably bulky and require traumatic surgery for implantation. As a result, the use of injectable methods of cell delivery has gained appeal. Bolus injections, despite improved methods of administration, are correlated with issues of inadequate cell localization. In response, three-dimensional hydrogel carriers for retinal applications aim to encapsulate cells, allowing for better cell distribution as these materials spread throughout the subretinal space. Increased viscosity of hydrogels as compared to saline injections, is hypothesized to improve cell loss and reduce aggregation. Of particular interest are in situ gelling systems, which undergo physical changes upon injection. Gelation upon delivery works to further assist in maintaining the cells within their target site. Purity and reproducibility concerns associated with the use of natural materials in the development of hydrogel cell carriers, have inspired the use of synthetic thermoresponsive poly-N-isopropylacrylamide (pNIPAAm). pNIPAAm undergoes a liquid to gel transition at a lower critical solution temperature (LCST) of 32°C. Copolymerization with various hydrophobic and hydrophilic groups can be used to adjust gel properties such as increasing or decreasing LCST, allowing for degradation, and improving water retention. In the work described herein, two NIPAAm-based thermoresponsive hydrogels intended for use as subretinal cell carriers are proposed. / Thesis / Master of Applied Science (MASc)

Age-Related Macular Degeneration

cell delivery

thermoresponsive hydrogel

pNIPAAm

biomaterials

tissue regeneration

Nanoparticles for multifunctional drug delivery systems

Qin, Jian

January 2007

Multifunctional drug delivery systems incorporated with stimuli-sensitive drug release, magnetic nanoparticles and magnetic resonance (MR) T2 contrast agents is attracting increasing attention recently. In this thesis, works on polymer nanospheres response to temperature change, superparamagnetic iron oxide nanoparticles (SPION)/polymeric composite materials for MR imaging contrast agents are summarized. A “shell-in-shell” polymeric structure has been constructed through a “modified double-emulsion method”. Thermosensitive inner shell is comprised of poly(N-isopropylacrylamide) which undergoes phase transition at body temperature. Such a feature could facilitate drug release at an elevated temperature upon administration. Furthermore, the dual-shell structure is covered by a layer of gold nanoparticles. According to the cytotoxicity tests, the biocompatibility is shown to be enhanced due to the layer of gold. SPION have been prepared using a high temperature decomposition method. Particle growth of SPION is monitored by transmission electron microscope and synchrotron X-ray diffraction. Poly(L,L-lactide)@SPION (PLLA@SPION) composite particles have been prepared through surface-initiated ring-opening polymerization which has been developed in our lab. For biomedical applications, it is essential to transfer the particles to physiological solutions from organic solutions. Phase transfer of SPION has been carried out by utilizing small molecules. Stability at the neutral pH is of large concern for such transfer systems. A novel phase transfer agent, Pluronic F127 (PF127), a triblock copolymer has been applied and the stability of the aqueous PF127@oleic acid (OA)@SPION solution has been greatly enhanced over a broad pH range. Most interestingly, PF127@OA@SPION show remarkable efficacy as T2 contrast agents as indicated by relaxometric measurements compared with commercially available products. / QC 20101115

drug delivery

stimuli-sensitive

SPION

PLLA

PNIPAAm

gold

MRI

cytotoxicity

Pluronic

phase transfer

Materials Chemistry

Materialkemi

Smart-Release Cell Sheet Delivery System for Diabetic Wound Healing

Chikelu, Chukwuemeka W.

11 October 2016

No description available.

Biomedical Research

Cell sheet engineering

PNIPAAm

Keratinocytes

Chronic diabetic ulcers

Thermoresponsive

Cell culture surfaces

MINIMALLY INVASIVE COPOLYMERS FOR POSTERIOR SEGMENT OCULAR THERAPEUTICS

Fitzpatrick, Scott D.

10 1900

<p>Efficient delivery of therapeutic cell and pharmaceutical suspensions to the posterior segment of the eye remains an elusive goal. Delivery is made difficult by blood ocular barriers that separate the eye from systemic circulation, the compartmentalized structure of the eye that limits diffusion across the globe, and effective clearance mechanisms that result in short drug residence times. The work presented in this thesis focuses on the design, synthesis, evolution and refinement of novel biomaterial scaffolds ultimately intended to facilitate the minimally invasive delivery of therapeutic payloads into the posterior segment of the eye. The first generation materials presented in this work (Chapter 2) consist of linear chains of temperature-sensitive amine-terminated poly(N-isopropylacrylamide) (PNIPAAm) grafted onto the backbone of type I collagen. Second generation materials (Chapter 3) saw the inclusion of the lubricious polysaccharide, hyaluronic acid (HA), and replacement of the bulky collagen backbone, which was observed to impede scaffold gelation, with small cell adhesive RGD peptide sequences. The introduction of degradability was the emphasis of third generation copolymers (Chapter 4) and was achieved through copolymerization with dimethyl-γ-butyrolactone acrylate (DBA). The DBA lactone side group was found to undergo a hydrolysis dependent ring opening, which raises copolymer LCST above physiologic temperature, triggering the gelled scaffold to solubilize and be excreted from the body via renal filtration without the liberation of any degradation by-products. Degradation was found to occur slowly, which is favourable for long-term release scaffolds intended to decrease the frequency of injections required to maintain therapeutically relevant concentrations within the vitreous. Finally, the design of a fourth generation material is discussed (Chapter 5), in which optical transparency is achieved through copolymerization of third generation materials with polyethylene glycol (PEG) monomers of varying molecular weight. Synthesis, design and characterization of the various copolymers is described herein.</p> / Doctor of Philosophy (PhD)

Ophthalmic materials

biomaterials

N-isopropylacrylamide

PNIPAAm

drug delivery

cell delivery

Biomaterials

Biomaterials

Lipid Bilayers Supported by Multi-Stimuli Responsive Polymers

Kaufmann, Martin

25 March 2013

Artificial lipid bilayers formed on solid surface supports are widespread model systems to study physical, chemical, as well as biological aspects of cell membranes and fundamental interfacial interactions. The approach to use a thin polymer film representing a cushion for lipid bilayers prevents incorporated membrane proteins from pinning to the support and mimics the native environment of a lipid bilayer in certain aspects of the extracellular matrix and intracellular structures. A key component for cell anchorage to extracellular fibronectin is the transmembrane adhesion receptor alpha(5)beta(1) integrin. Its transport dynamics and clustering behavior plays a major role in the assembly of focal adhesions, which mediate mechanical forces and biochemical signals of cells with their surrounding. The system investigated herein is envisioned to use extrinsically controlled stimuli-responsive polymer cushions to tune the frictional drag between polymer cushion and mobile membranes with incorporated integrins to actively regulate lipid membrane characteristics. To attain this goal, a temperature- and pH-responsive polymer based on poly(N-isopropylacrylamide) copolymers containing varying amounts of carboxyl-group-terminated comonomers at different aliphatic spacer lengths (PNIPAAm-co-carboxyAAM) was surface-grafted to a poly(glycidyl methacrylate) anchorage layer. The swelling transitions were characterized using atomic force microscopy, ellipsometry and quartz crystal microbalance with dissipation monitoring (QCM-D) and found to be tunable over a wide range of temperature and pH. In agreement with the behavior of the polymers in solution, longer alkyl spacers decreased the phase transition temperature T(P) and higher contents of carboxylic acid terminated comonomers increased T(P) at alkaline conditions and decreased T(P) at acidic conditions. Remarkably, the point where the degree of carboxyl group deprotonation balances the T(P)-lowering effect of the alkyl spacer was distinctive for each alkyl spacer length. These findings illustrate how the local and global balance of hydrophilic and hydrophobic interactions along the copolymer chain allows to adjust the swelling transition to temperatures below, comparable, or above those observed for PNIPAAm homopolymers. Additionally, it could be shown that surface-grafting leads to a decrease in T(P) for PNIPAAm homopolymers (7°C) and copolymers (5°C - 10°C). The main reason is the increase in local polymer concentration of the swollen film constrained by dense surface anchorage in comparison to the behavior of dilute free chains in solution. In accordance with the Flory-Huggins theory, T(P) decreases with increasing concentration up to the critical concentration. Biological functionalization of the PNIPAAm-co-carboxyAAm thin films was demonstrated for the cell adhesion ligand peptide cRGD via carbodiimide chemistry to mimic extracellular binding sites for the cell adhesion receptors integrin. The outcome of QCM-D measurements of cRGD-functionalized surfaces showed a maintained stimuli-responsiveness with slight reduction in T(P). A drying/rehydration procedure of a 9:1 lipid mixture of the cationic lipid dioleoyl-trimethylammoniumpropane (DOTAP) and the zwitterionic dioleoyl-phosphatidylcholine (DOPC) was utilized to form lipid bilayer membranes on PNIPAAm-co-carboxyAAM cushions. Fluorescence recovery after photobleaching (FRAP) revealed that lipid mobility was distinctively higher (6.3 - 9.6) µm2 s-1 in comparison to solid glass support ((3.0 - 5.9) µm2 s-1). In contradiction to the initial expectations, modulation of temperature and pH led to poor variations in lipid mobility that did not correlate with the PNIPAAm cushion swelling state. The results suggested a weak coupling of the lipid bilayer with PNIPAAm polymer cushions that can be slightly tuned by electrostatic interactions. The transmembrane adhesion receptor alpha(5)beta(1) integrin was reconstituted into liposomes consisting of DOPC/sphingomyelin/cholesterol 2:2:1 for the formation of polymer cushioned bilayers. PNIPAAm- co-carboxyAAM and maleic acid (MA) copolymers were used as cushions, both with the option for cRGD functionalization. On the MA copolymer cushions, fusion of proteoliposomes resulted in supported bilayers with mobile lipids as confirmed by FRAP. However, incorporated integrins were immobile. In an attempt to explain this observation, the medium-sized cytoplasmic integrin domain was accounted to hamper the movement by steric interactions with the underlying polymer chains in conjunction with electrostatic interactions of the cationic cytoplasmic domain with the oppositely charged MA copolymer. On the PNIPAAm-co-carboxyAAM cushion only a drying/rehydration procedure lead to bilayer formation. However, again the integrins were immobile, presumably due to the harsh treatment during preparation. Nevertheless, the results of the investigated set of PNIPAAm copolymer films suggest their application as temperature- and pH-responsive switchable layers to control interfacial phenomena in bio-systems at different physiological conditions. The PNIPAAm-co-carboxyAAm cushioned bilayer system represents a promising step towards extrinsically controlled membrane – substrate interactions.

Polymerkissen

Stimuliresponsive Polymerfilme

PNIPAAm

QCM-D

Lipiddoppelschichten

alpha(5)beta(1) Integrin

FRAP

polymer cushion

stimuli responsive polymer films

PNIPAAm

QCM-D

lipid bilayer

alpha(5)beta(1) integrin

FRAP

ddc:540

rvk:VK 8007

Lipid Bilayers Supported by Multi-Stimuli Responsive Polymers

Kaufmann, Martin

08 February 2013

Artificial lipid bilayers formed on solid surface supports are widespread model systems to study physical, chemical, as well as biological aspects of cell membranes and fundamental interfacial interactions. The approach to use a thin polymer film representing a cushion for lipid bilayers prevents incorporated membrane proteins from pinning to the support and mimics the native environment of a lipid bilayer in certain aspects of the extracellular matrix and intracellular structures. A key component for cell anchorage to extracellular fibronectin is the transmembrane adhesion receptor alpha(5)beta(1) integrin. Its transport dynamics and clustering behavior plays a major role in the assembly of focal adhesions, which mediate mechanical forces and biochemical signals of cells with their surrounding. The system investigated herein is envisioned to use extrinsically controlled stimuli-responsive polymer cushions to tune the frictional drag between polymer cushion and mobile membranes with incorporated integrins to actively regulate lipid membrane characteristics. To attain this goal, a temperature- and pH-responsive polymer based on poly(N-isopropylacrylamide) copolymers containing varying amounts of carboxyl-group-terminated comonomers at different aliphatic spacer lengths (PNIPAAm-co-carboxyAAM) was surface-grafted to a poly(glycidyl methacrylate) anchorage layer. The swelling transitions were characterized using atomic force microscopy, ellipsometry and quartz crystal microbalance with dissipation monitoring (QCM-D) and found to be tunable over a wide range of temperature and pH. In agreement with the behavior of the polymers in solution, longer alkyl spacers decreased the phase transition temperature T(P) and higher contents of carboxylic acid terminated comonomers increased T(P) at alkaline conditions and decreased T(P) at acidic conditions. Remarkably, the point where the degree of carboxyl group deprotonation balances the T(P)-lowering effect of the alkyl spacer was distinctive for each alkyl spacer length. These findings illustrate how the local and global balance of hydrophilic and hydrophobic interactions along the copolymer chain allows to adjust the swelling transition to temperatures below, comparable, or above those observed for PNIPAAm homopolymers. Additionally, it could be shown that surface-grafting leads to a decrease in T(P) for PNIPAAm homopolymers (7°C) and copolymers (5°C - 10°C). The main reason is the increase in local polymer concentration of the swollen film constrained by dense surface anchorage in comparison to the behavior of dilute free chains in solution. In accordance with the Flory-Huggins theory, T(P) decreases with increasing concentration up to the critical concentration. Biological functionalization of the PNIPAAm-co-carboxyAAm thin films was demonstrated for the cell adhesion ligand peptide cRGD via carbodiimide chemistry to mimic extracellular binding sites for the cell adhesion receptors integrin. The outcome of QCM-D measurements of cRGD-functionalized surfaces showed a maintained stimuli-responsiveness with slight reduction in T(P). A drying/rehydration procedure of a 9:1 lipid mixture of the cationic lipid dioleoyl-trimethylammoniumpropane (DOTAP) and the zwitterionic dioleoyl-phosphatidylcholine (DOPC) was utilized to form lipid bilayer membranes on PNIPAAm-co-carboxyAAM cushions. Fluorescence recovery after photobleaching (FRAP) revealed that lipid mobility was distinctively higher (6.3 - 9.6) µm2 s-1 in comparison to solid glass support ((3.0 - 5.9) µm2 s-1). In contradiction to the initial expectations, modulation of temperature and pH led to poor variations in lipid mobility that did not correlate with the PNIPAAm cushion swelling state. The results suggested a weak coupling of the lipid bilayer with PNIPAAm polymer cushions that can be slightly tuned by electrostatic interactions. The transmembrane adhesion receptor alpha(5)beta(1) integrin was reconstituted into liposomes consisting of DOPC/sphingomyelin/cholesterol 2:2:1 for the formation of polymer cushioned bilayers. PNIPAAm- co-carboxyAAM and maleic acid (MA) copolymers were used as cushions, both with the option for cRGD functionalization. On the MA copolymer cushions, fusion of proteoliposomes resulted in supported bilayers with mobile lipids as confirmed by FRAP. However, incorporated integrins were immobile. In an attempt to explain this observation, the medium-sized cytoplasmic integrin domain was accounted to hamper the movement by steric interactions with the underlying polymer chains in conjunction with electrostatic interactions of the cationic cytoplasmic domain with the oppositely charged MA copolymer. On the PNIPAAm-co-carboxyAAM cushion only a drying/rehydration procedure lead to bilayer formation. However, again the integrins were immobile, presumably due to the harsh treatment during preparation. Nevertheless, the results of the investigated set of PNIPAAm copolymer films suggest their application as temperature- and pH-responsive switchable layers to control interfacial phenomena in bio-systems at different physiological conditions. The PNIPAAm-co-carboxyAAm cushioned bilayer system represents a promising step towards extrinsically controlled membrane – substrate interactions.

info:eu-repo/classification/ddc/540

ddc:540

Simulación de Propiedades en Disolución de Polímeros

Rodríguez Schmidt, Ricardo

07 November 2012

En la Tesis se desarrollan diferentes aspectos de la simulación computacional de polímeros en disolución. Uno de los capítulos de la tesis trata sobre las diferencias existentes entre los valores del coeficiente de difusión traslacional calculados mediante diferentes algoritmos. Otro capítulo establece una comparación entre cuatro algoritmos diferentes para el cálculo de trayectorias mediante dinámica browniana. Finalmente, en los dos últimos capítulos de la Tesis se detalla la aplicación de un procedimiento de simulación multiescala desarrollado por nuestro grupo de investigación al caso de polímeros hiperramificados y al de copolímeros anfifílicos termosensibles, y la comparación de los resultados obtenidos en cada caso a resultados obtenidos en laboratorio por otros investigadores / In this Thesis, different aspects of the computational simulation of polymers in solution are developed. One of the chapters is about the differences observed among the values of the translational diffusion coefficient calculated by means of different algorithms. Another chapter establishes a comparison between four different browniand dynamics algorithms for the calculation of trajectories. Finally, in the two last chapters of the Thesis verse about the application of a multiscale simulation procedure developed by our group to the cases of hyperbranched polymers and thermoresponsive amphiphilic copolymers, and comparing the results to the experimental data obtained by other researchers.

Simulación

Propiedades en Disolución

Polímeros

Dinámica Browniana

Montecarlo

Coeficiente de Difusión traslacional

Interacción Hidrodinámica

Polímeros hiperramificados

PNIPAAM

Química Física

544

Synthesis of nanostructured and hierarchical materials for bio-applications

Ye, Fei

January 2011

In recent years, nanostructured materials incorporated with inorganic particles and polymers have attracted attention for simultaneous multifunctional biomedical applications. This thesis summarized three works, which are preparation of mesoporous silica coated superparamagnetic iron oxide (Fe3O4@mSiO2) nanoparticles (NPs) as magnetic resonance imaging T2 contrast agents, polymer grafted Fe3O4@mSiO2 NPs response to temperature change, synthesis and biocompatibility evaluation of high aspect ratio (AR) gold nanorods. Monodisperse Fe3O4@mSiO2 NPs have been prepared through a sol-gel process. The coating thickness and particle sizes can be precisely controlled by varying the synthesis parameters. Impact of surface coatings on magnetometric and relaxometric properties of Fe3O4 NPs is studied. The efficiency of these contrast agents, evaluated by MR relaxivities ratio (r2/r1), is much higher than that of the commercial ones. This coating-thickness dependent relaxation behavior is explained due to the effects of mSiO2 coatings on water exclusion. Multifunctional core-shell composite NPs have been developed by growing thermo-sensitive poly(N-isopropylacrylamide-co-acrylamide) (P(NIPAAm-co-AAm)) on Fe3O4@mSiO2 NPs through free radical polymerization. Their phase transition behavior is studied, and their lower critical solution temperature (LCST) can be subtly tuned from ca. 34 to ca. 42 °C, suitable for further in vivo applications. A seedless surfactant-mediated protocol has been applied for synthesis of high AR gold nanorods with the additive of HNO3. A growth mechanism based on the effect of nitrate ions on surfactant micelle elongation and Ostwald ripening process is proposed. The biocompatibility of high AR nanorods was evaluated on primary human monocyte derived dendritic cells (MDDCs). Their minor effects on viability and immune regulatory markers support further development for medical applications. / QC 20110701

Fe3O4

mSiO2

core-shell

MRI

multifunctional

PNIPAAm

LCST

gold

nanorod

nitric acid

AR

MDDC

biocompatibility

immunomodulation

Materials Chemistry

Materialkemi

Integration Of A Nanostructure Embedded Thermoresponsive Polymer For Microfluidic Applications

Londe, Ghanashyam

01 January 2008

This work describes the modeling, synthesis, integration and characterization of a novel nanostructure embedded thermoresponsive material for microfluidic applications. The innumerable applications of thermoresponsive surfaces in the recent years have necessitated the development of a rigorous mathematical treatment for these surfaces to understand and improve their behavior. An analytical model is proposed to describe the transfer characteristic (variation of contact angle versus temperature) of a unique switchable, nanostructured, thermoresponsive surface consisting of silica nanoparticles and the thermoresponsive polymer, Poly(N-isopropylacrylamide ) (PNIPAAm) which changes its wetting angle upon heating. Important metrics such as the absolute lower critical solution temperature, threshold & saturation temperatures and gain are modeled and quantified by mathematical expressions. Based on the modeling, a heat source for the thermoresponsive surface was integrated on the glass substrate itself to create a fully functional smart surface. The design and fabrication of a smart platform consisting of the switchable, nanostructured, thermoresponsive surface with an integrated gold microheater for wettability control and its time response analysis was conducted. The insight gained into the behavior of the thermoresponsive surface by using the analytical model, aided the effort in the effective integration of the surface into a microfluidic channel for flow regulation applications. The implementations of novel microfluidic flow regulator concepts were tested. The aim is to integrate a regulator function to a channel surface utilizing the layer-by-layer (LBL) deposition technique. The characterization and pressure differential study of the microfluidic regulators was carried out on simple straight microchannels which were selectively coated with the thermoresponsive surface. Theoretical and experimental studies were performed to determine the important characteristic parameters including capillary, Weber and Reynolds numbers. The pressure differential data was used to develop critical operating specifications. This work lays out a new microfluidic device concept consisting of a channel with a built-in regulatory function.

Thermoresponsive

PNIPAAm

Nanostructure

Layer-by-Layer

Logistic function

Microfluidic flow regulation

Pressure differential

Electrical and Computer Engineering

Electrical and Electronics

Engineering