Stimuli-Responsive Hydrogel Microlenses

Kim, Jongseong

08 January 2007

This dissertation is aimed towards using stimuli-responsive pNIPAm-co-AAc microgels synthesized via free-radical precipitation polymerization to prepare stimuli-responsive hydrogel microlenses. Chapter 1 gives a detailed background of hydrogels, and their applications using responsive hydrogels. Chapter 2 describes the use of colloidal hydrogel microparticles as microlens elements and the fabrication method to form the hydrogel microlens arrays via Coulombic interactions. Chapter 3 shows the demonstration of tunable microlenses prepared by the method used in Chapter 2. In this chapter the microlenses are subjected to various pH and temperature in aqueous solutions. Chapter 4 describes that the microlens arrays constructed on Au nanoparticle-functionalized glass substrates by self-assembly display dramatic changes in lensing power in response to an impingent frequency-doubled Nd:YAG laser. The microlens photoswitching is highly reversible, with sub-millisecond lens switching times. Chapter 5 describes the development of bioresponsive hydrogel microlenses as a new protein detection technology. The microlens method is shown to be very specific for the target protein, with no detectable interference from nonspecific protein binding. Chapter 6 describes the use of bioresponsive hydrogel microlenses as a label-free biosensing scaffolding. These microstructures simultaneously act as the biosensors scaffolding/immobilization architecture, transducer, amplifier, and also allow for broad tunability of the analyte concentration to which the microlens is sensitive.

Biosensing

Bioresponsive Hydrogel

Responsive Hydrogel

Microlens

Hydrogel

Thermo-responsive Copolymers with Enzyme-dependent Lower Critical Solution Temperatures for Endovascular Embolization

January 2019

abstract: Minimally invasive endovascular embolization procedures decrease surgery time, speed up recovery, and provide the possibility for more comprehensive treatment of aneurysms, arteriovenous malformations (AVMs), and hypervascular tumors. Liquid embolic agents (LEAs) are preferred over mechanical embolic agents, such as coils, because they achieve homogeneous filling of aneurysms and more complex angioarchitectures. The gold standard of commercially available LEAs is dissolved in dimethyl sulfoxide (DMSO), which has been associated with vasospasm and angiotoxicity. The aim of this study was to investigate amino acid substitution in an enzyme-degradable side group of an N-isopropylacrylamide (NIPAAm) copolymer for the development of a LEA that would be delivered in water and degrade at the rate that tissue is regenerated. NIPAAm copolymers have a lower critical solution temperature (LCST) due to their amphiphilic nature. This property enables them to be delivered as liquids through a microcatheter below their LCST and to solidify in situ above the LCST, which would result in the successful selective occlusion of blood vessels. Therefore, in this work, a series of poly(NIPAAm-co-peptide) copolymers with hydrophobic side groups containing the Ala-Pro-Gly-Leu collagenase substrate peptide sequence were synthesized as in situ forming, injectable copolymers.. The Gly-Leu peptide bond in these polypeptides is cleaved by collagenase, converting the side group into the more hydrophilic Gly-Ala-Pro-Gly-COOH (GAPG-COOH), thus increasing the LCST of the hydrogel after enzyme degradation. Enzyme degradation property and moderate mechanical stability convinces the use of these copolymers as liquid embolic agents. / Dissertation/Thesis / Masters Thesis Biomedical Engineering 2019

Biomedical engineering

Chemistry

Organic chemistry

bioresponsive

Embolic agent

Enzyme-degradable

NIPAAm

Polymer

stimuli-responsive

Tampon-like Foam Structures for Bioresponsive Vaginal Drug Delivery Applications.

Mehta, Ankit N.

17 October 2014

No description available.

Pharmaceuticals

Carbopol 974P

Bioadhesion

Dual purpose contraceptive

Lyophilized Foam

Bioresponsive

Vaginal Delivery

Elastase responsive hydrogel dressing for chronic wounds

Bibi, Nurguse

January 2011

Chronic wounds are a major financial and clinical burden causing the deaths of millions per year. Over expression of elastase is well documented as the main culprit that delays the normal wound repair process within chronic wounds. The aim of this thesis is to design a responsive chronic wound dressing based on the hydrogel polymer, PEGA (polyethylene glycol acrylamide) in the form of particles to mop-up excess elastase by exploiting polymer collapse in response to elastase hydrolytic activity within sample fluids mimicking the environment of chronic wounds. PEGA particles were functionalised with enzyme cleavable peptides (ECPs) containing charged residues. Upon cleavage the charge balance changes, causing polymer swelling and consequent elastase entrapment. The pH range of chronic wounds is reported in the range of 5.45 - 8.65. Due to its pI which is around 8.3, within this range elastase exist both in its cationic and anionic forms. To accommodate a hydrogel dressing that could selectively entrap excess elastase both in its cationic and anionic, oppositely charged ECPs were designed. In its cationic form, elastase was found to have a high preference of cleaving ECPs and penetrating into PEGA particles bearing negative charges. In contrast, in its anionic form the opposite effect was observed, wherein elastase preferred to cleave ECPs and penetrate PEGA particles bearing positive charges. The diffusion, accessibility and entrapment of elastase into functionalised PEGA particles was explored using various fluorescence microscopy techniques. Removal of the charged residue by elastase showed a reduction in particle swelling causing the pores of PEGA particles to become restricted. In this manner, cleaved PEGA particles prevented the accessibility of molecules with a molecular weight as low as 20 kDa into the cleaved PEGA particles. Since elastase has a molecular weight of 25.9 kDa the collapsing of the pores within PEGA particles entrapped elastase inside the interior of cleaved PEGA particles. In its cationic form (at pH 7.4) elastase was found to penetrate and become trapped more into both negative and positive PEGA particles compared to neutral particles. The negative particles were shown to trapped cationic elastase within 2 minutes compared to the positive particles. In contrast, the neutral particles failed to retain and encapsulate elastase as the fluorescence inside the neutral particles was found to decrease. Coinciding with these observations, after sample fluids containing elastase were treated with functionalised PEGA particles, the residual elastase activity in sample fluids was reduced more by the charged PEGA particles compared to neutral particles. The cell culture studies demonstrated that the elastase activity observed in human dermal fibroblasts (HDF) was also reduced more by the charged particles compared to the neutral particles. However, the positive particles were found to significantly reduced HDF-elastase activity compared to both the negative and neutral PEGA particles. Overall, this thesis exemplifies that on the basis of charge selective cleaving of ECPs coupled to PEGA particles can be exploited to selectively remove excess proteases such as elastase from sample fluids mimicking the environment of chronic wounds.

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