Dissertations / Theses on the topic 'Bioadhesive drug delivery systems'

Mucoadhesive formulations have been used to increase the residence time and improve bioavailability of nasal dosage forms. The exact nature of the interplay between formulations and the mucus layer has not been defined, although theories have been proposed suggesting that certain characteristics are required for optimum mucoadhesivity. This thesis presents an investigation into the effects of the properties of excipients in nasal formulations on their mucoadhesive performance. The main factors that were investigated included molecular weight, concentration, crosslinking density, charge, and viscosity. It was established using rotational and oscillation rheology that the polymeric formulations with the highest molecular weight expressed the highest viscosity. Thixotropy, a vital property in mucoadhesion, was also assessed. The greatest thixotropy was found with polymers of increasing molecular weight whereas low molecular weight polymers exhibited little or no thixotropy. As expected, high molecular weight polymers produced strongly gelled networks; a requirement for mucoadhesion. Mucoadhesive interactions between polymers and mucin were analysed using standard rheology and microrheology. Greater synergy was found with high molecular weight, linear, ionic polymers; factors which allow for improved chain interactions. Texture analysis of the formulations confirmed that the adhesive forces increased for higher molecular weight, ionic polymers. In conclusion, it was found that a combination of a high molecular weight, increased viscosity, charge, and a moderate level of crosslinking are all favourable properties in a polymeric nasal spray. The formulation of a mucoadhesive dosage form with these characteristics may improve the retention time of the formulation within the nose, resulting in an increased opportunity for drug absorption and thus greater bioavailability.

The objective of this research was to investigate two important aspects of buccal drug delivery, transport and mucoadhesion. Buspirone was chosen as a model drug for the in vitro buccal transport studies, polyvinyl alcohol and sodium alginate polymer blends were prepared to investigate the mucoadhesive properties through a Lewis acid-base approach and finally, the effect of formulation factors on the force of mucoadhesion, surface energy parameters, release rate and flux was studied. In vitro permeation studies were conducted to investigate the buccal transport pathway of buspirone. Mathematical models were developed to quantify the process of permeation. Permeation enhancement of buspirone across the buccal mucosa was investigated using bile salts (sodium glycocholate and taurodeoxycholate), propylene glycol, propylene. Effect of formulation factors like drug, enhancer, and plasticizer was studied through statistically designed experiments. These experiments aided in characterizing the buccal delivery system. Mathematical models were developed for surface energy parameters, force of mucoadhesion, release rate, and flux. Research conducted in this dissertation focused on two important aspects of transbuccal delivery, drug transport and mucoadhesion by studying a model drug and polymer blends. The results obtained in these investigations can be utilized in the development of other bioadhesive delivery systems with respect to drug transport and mucoadhesion. Polymer blends of polyvinyl alcohol (PVA) and sodium alginate (Alg) were prepared to evaluate their mucoadhesive properties and investigate mucoadhesive mechanism by a Lewis acid-base approach. (Abstract shortened by UMI.)

A novel mucoadhesive poly[acrylic acid-co-poly(ethylene glycol) monomethylether monomethacrylate-co-2-(N, N-Dimethylamino)ethyl methacrylate], [poly(AA-PEGMM-DMEMA)], was designed and synthesized based on a hypothesis that interactions between the negative charged surface of the buccal mucosa and the positive charged constituent in bioadhesive would increase the mucoadhesion. Introducing the cationic monomer DMEMA to poly(AA-PEGMM) increased the Lewis acid-base interaction between the polymer and the buccal mucosa, which led to a thermodynamic favorable mucoadhesion process. The polymer containing 1% DMEMA yielded the highest force of mucoadhesion among the polymers studied. The ATR-FTIR study revealed that intrapolymer interactions between the carboxyl groups in AA and the amino groups in DMEMA and interactions between polymer and buccal surface played important roles in the mucoadhesion of poly(AA-PEGMM-DMEMA). The optimal mucoadhesion can be achieved by balancing these two interactions. The thermodynamic analysis revealed the contributions of Lifshitz-van der Waals interaction and Lewis acid-base interaction, such as the interactions between the hydroxyl groups and the ester groups, to the mucoadhesion. A general trend of mucoadhesion of the polymer can be predicted from the total free energy of adhesion (Δ G TOT ) at different hydration levels. A mathematical model was established to quantitatively describe the contributions of the three stages that involved in the process of adhesion to the force of mucoadhesion by the surface free energy, the total free energy of adhesion, and the hydration of the polymer. Zalcitabine (ddC) was selected as the model drug in the drug loading, in vitro release and permeation studies. Changing the pH of the swelling medium can greatly affect the swelling of the polymer. The drug loading increased 3.6 times when the pH of the loading solution was changed from 2.2 to 8. The process of the swelling and drug release followed Fickian diffusion mechanism. Compared to the permeation of ddC through the polymer, the permeation of ddC through the buccal mucosa was the rate-limiting barrier to the transbuccal delivery of ddC. ddC permeated through buccal mucosa by passive diffusion over the range of concentrations examined. The total permeability of ddC through the buccal mucosa was contributed by the permeation of ionized and unionized species of ddC. A bilayer diffusion model was established to describe the relations among the permeability of the epithelium, the connective tissue and the full-thickness buccal mucosa. The histological study revealed that the basal lamina within the epithelium of buccal mucosa acted as the major barrier to the permeation of ddC. The permeation of ddC through the buccal mucosa can be effectively enhanced by co-administrating a penetration enhancer sodium glycodeoxycholate (GDC). GDC enhanced the buccal permeability of ddC up to 32 times. A zero-order delivery of the currently approved dosage of ddC can be achieved by a poly(AA-PEGMM-DMEMA) transbuccal drug delivery device with GDC as the penetration enhancer. The transbuccal delivery is a potential route for the administration of ddC.

O objetivo deste estudo clínico foi avaliar a eficácia clínica de um dispositivo polimérico celulósico carregado com sal anestésico, na prevenção da dor pré-procedimento operatório em odontologia, diminuindo ou eliminando o uso de agulhas gengivais em anestesias infiltrativas. Foram testados três dispositivos com propriedade bioadesiva para a liberação modificada de fármacos em contato com a mucosa oral, um contendo um núcleo central de prilocaína e lidocaína em iguais concentrações e um contendo somente lidocaína, a liberação dos princípios ativos se deu pelo processo de fast-dissolve, e o terceiro constituído somente pelo sistema bioadesivo, sem qualquer sal anestésico(controle negativo), em desenho pareado. Os dispositivos foram aplicados na região do fórnice do vestíbulo dos pré-molares superiores, após limpeza e secagem superficial da mucosa. Foram selecionados 21 voluntários de ambos os gêneros, normotipos, saudáveis, com faixa etária entre 18 e 30 anos, para um teste clínico randomizado, controlado, crossover e triplo-cego. O teste de sintomatologia pré e pós-aplicação foi realizado com o emprego da sonda computadorizada Florida Probe® System, (Florida Probe Corporation, Gainesville, FL, USA), aplicada no sentido perpendicular ao tecido mucoso, simulando o uso de agulha gengival e com pressão constante de 25 gramas, já calibrada pelo próprio sistema, foi aplicado também o teste térmico com o uso de Endo-Frost® Roeko para verificação da profundidade anestésica em nível pulpar. Para a mensuração da sintomatologia dolorosa presente/ausente foi utilizada escala visual analógica (EVA) e a versão em Língua Portuguesa do McGill Pain Questionnaire. Os indivíduos receberam instruções de como responder aos questionários para mensuração dos estímulos dolorosos, que foram computados imediatamente após a resposta. Os resultados obtidos demonstraram uma eficiência anestésica favorável para os dois dispositivos carregados com os sais onde não houve diferença estatística quanto ao efeito, porém na relação efeito versus tempo o dispositivo com os dois sais apresentou melhor resultado para o teste térmico. Conclui-se que ambos os dispositivos (B e C) apresentaram efeito anestésico tanto tópico quanto em profundidade pela diminuição da dor provocada pelos dois testes (mecânico/térmico) propostos.
The objective of this clinical study was to evaluate the efficacy of a cellulosic polymer dispositive loaded with anesthetic salt to prevent pain in dentistry pre-operative procedure, reducing or eliminating the use of gingival needles in infiltrative anesthesia. Three dispositives were tested with bioadhesive property for drugs delivery system in contact with the oral mucosa, containing prilocaine and lidocaine at same concentrations, and other containing just lidocaine with release of active elements through the process of fast-dissolve, and the other only the same bioadhesive system, without the active (negative control), paired study, which was applied in the region of the superior premolars, the mucosal surface after cleaning. Were selected 21 volunteers of both genders, normotype, healthy, aged between 18 and 30 years for a clinical trial, randomized, controlled, crossover and triple-blind. The test of symptoms before and after application was made using the electronic probe Florida Probe System® (Florida Probe Corporation, Gainesville, FL, USA), applied perpendicularly to the mucosal tissue, simulating the use of gingival needle a constant pressure of 25 grams, already calibrated by the system itself. Additional thermal testing will be proved employing Endo-Frost® tester. For the measurement of pain symptoms present / absent was used a visual analog scale (VAS) and the Portuguese language version of the McGill Pain Questionnaire adapted by Varolli and Pedrazzi (2006), using an appendix to the questionnaire (Group 9 table 1). Individuals have received instructions on how to answer the questionnaire for the measurement of painful stimuli, which would be counted immediately after the response. The results demonstrated a favorable anesthetic efficiency for both dispositive loaded with salts where there was no statistical difference in the effect, but for the relationship effect versus time the dispositive with two salts showed better results. It can be concluded that both devices (B and C) presented as both topical and depth anesthetic by decreasing the pain caused by the two mechanical/thermal proposed tests.

Implantable drug delivery is becoming an increasingly important field of research, providing great potential for a wide range of flexible and low cost solutions for localized treatment of chronically debilitating diseases. This dissertation presents work that encompasses several approaches for the remote triggering, powering, and control of micro drug delivery devices and systems, designed with remote-controllability, minimal power requirements, biocompatibility, and the potential for minimally invasive implantation in mind. The control mechanisms used rely on microtechnology, nanotechnology, and electromagnetic power transfer to magnetic nanoparticles and magnetic nanowires, for the heating and actuation of thermoresponsive Poly(N-isopropylacrylamide) hydrogels (PNIPAm) in the form of nanoparticles in membranes and stand-alone microdroplets, and actuation of flexible membranes for drug pumping. Thermoresponsive PNIPAm, in any form such as nanoparticles, microdroplets, or mezzo scale bulk material shapes, has the property of swelling with water in its hydrophilic state below a critical temperature. At higher temperatures, a sharp change occurs, the polymer network becomes hydrophilic, and the water molecules in the network is expelled, causing the overall material to shrink in size, while the released water or aqueous solution is left free to flow around or away from the material. When embedded in membrane matrices used as drug delivery gates, PNIPAm nanoparticles act as diffusion and flow blockers below the critical temperature. When PNIPAm surpasses the critical temperature, induced by heat from local magnetic iron oxide nanoparticles (exposed to a 62 mT, 450 kHz magnetic field), it shrinks in size and increases the drug flow through membrane pathways. The combination of this membrane design with osmotic pumping and methods for tailoring the drug release profile is reported. Simulation supports experimental results while describing interactions between the osmotic pump and the thermoresponsive membranes. A sensitivity analysis based on a fluidic circuit analogy gives insight into the contributions of the components of the device, in particular those of membranes affecting the displacement of fluid. PNIPAm microdroplets, spherical microparticles larger than the PNIPAm nanoparticles discussed above, are fabricated with embedded magnetic iron oxide nanoparticles or magnetic iron nanowires and pre-loaded with an aqueous drug. Upon magnetic heating, these microdroplets shrink in size and expel the drug. Magnetic nanowires have much lower power requirements when compared with widely-used iron oxide magnetic nanoparticles for triggering PNIPAm, due to their ability to generate losses via physical vibration within the microdroplets. A model is used to corroborate the experimentally observed low power (1 mT, 20 kHz magnetic field) required to induce PNIPAm microdroplet shrinkage. This model for nanowire loaded microdroplet design is compared with the well-established theory for power generation from magnetic iron oxide nanoparticles, and associated experiments (using a 72 mT, 600 kHz magnetic field) in order to confirm the validity of the calculated power generated by iron nanowires. The findings in this work offer several flexible options for the application of PNIPAm as a remotely triggerable drug delivery controller or carrier, using relatively simple fabrication methods, permitting several degrees of customization of the delivery rate or profile by adjusting the PNIPAm material, its magnetic content, and the applied magnetic field, all the while demonstrating the use of magnetic nanowires as a more efficient power transfer material when compared to traditionally used magnetic nanoparticles. The findings associated with the efficient triggering of PNIPAm microdroplets can be implemented in a more power-friendly design of magnetic, remotely triggered membranes which, although implemented in conjunction with osmotic pumps here, can be coupled with other pressure sources.
Applied Science, Faculty of
Engineering, School of (Okanagan)
Graduate

The targeted delivery of drugs is one of the most actively pursued goals in anti-HIV and anti-cancer chemotherapy. This project takes a proof-of-concept approach to the development of protein-based drug delivery systems - delivery systems that would package, target, and deliver cytotoxins to diseased cells. Primarily, this project explores the use of the potent anti-HN protein, cyanovirin-N (CV-N), to actively target and deliver cytotoxic natural products to HN-infected cells. This project also investigates the use of human serum albumin (HSA), a 66 kDa protein, as a macromolecular carrier to passively target and deliver cytotoxic natural products to cancerous cells. To facilitate release of the toxin within infected cells, an enzymatically-cleavable tetra peptide was incorporated in the conjugates. Maleimido-activated tetra peptide toxin constructs were prepared in readiness for selective reaction with proteins carrying thiol functionalities. Release of the toxin, norhomohalichondrin B, was demonstrated in vitro. Native CV -N conjugates were prepared by thiolation of the lysine ε-amino groups, and the subsequent reaction with maleimido-activated compounds. Reaction across all lysine residues was demonstrated. A singly-substituted tyrosinamide conjugate of CV-N was prepared. Two recombinantly produced mutant CV-N proteins allowed for the production of selectively modified, double- and single-norhomohalichondrin B conjugates of CV-N. The conjugates retained the anti-HN activity of the parent protein. Homohalichondrin B, doxorubicin, and tyrosinamide conjugates of HSA were prepared. The syntheses exploited the availability of a free thiolmoiety at cysteine-34 of HSA, and the specific and selective reaction of this thiol with the maleimido-activated tetra peptide derivatives. All toxin conjugates demonstrate excellent cell toxicity. Further research to investigate whether this is targeted toxicity is currently underway.

Drug delivery systems (DDS) with multiple functionalities such as environment-sensitive drug release mechanisms and visualization agents have motivated the biomedical community as well as materials chemists for more than a decade. This dissertation is concerned with the development of nanoparticles for multifunctional DDS  to tackle several crucial challenges in these complex systems, including polymeric nanospheres which respond to temperature change, superparamagnetic iron oxide nanoparticles/polymeric composite for magnetic resonance imaging contrast agents and drug carriers, immunoresponse of nanomaterials and injectable magnetic field sensitive ferrogels. The biocompatible and biodegradable polylactide (PLA) was employed as matrix materials for polymeric nanosphere-based DDS. The thermosensitive polymeric nanospheres have been constructed through a “modified double-emulsion method”. The inner shell containing the thermosensitive poly(N-isopropylacrylamide) (PNIPAAm) undergoes a “hydrophilic-to-hydrophobic” phase transition around the human body temperature. The sensitivity of the polymer to the temperature can facilitate drug release at an elevated temperature upon administration. In addition, gold nanoparticles were assembled on the dual-shell structure to form a layer of gold shell. The cell viability was found to be enhanced due to the gold layer. The immunoresponse of the gold nanoparticles has been considered even if no acute cytotoxicity was observed. Imaging is another functionality of multifunctional DDS. This work focuses on magnetic resonance imaging (MRI) and involves synthesis and surface modification of superparamagnetic iron oxide nanoparticles (SPIONs) for contrast agents. The SPIONs have been prepared through a high temperature decomposition method. Surface modification was carried out in different ways. Poly(L,L-lactide) (PLLA) was grafted on SPIONs through surface-initiated ring-opening polymerization. The hydrophobic model drug indomethacin was loaded in the PLLA layer of the composite particles. For biomedical applications, it is essential to modify the hydrophobic particles so that they can be dispersed in physiological solutions. A series of protocols including using small charged molecules and amphiphilic polymers has been established. Pluronic F127 (PF127), a triblock copolymer was applied as a phase transfer reagent. Most interestingly, PF127@SPIONs show remarkable efficacy as T2 contrast agents. The PF127@SPIONs have been successfully applied to image the cochlea in a rat model. As another phase transfer reagent, poly(maleic anhydride-alt-octadecene)-graft-PNIPAAm (PMAO-graft-PNIPAAm) was created for surface modification of SPIONs. This new copolymer provides the modified SPIONs with thermosensitivity together with water-dispersibility. As another form of DDS, ferrogel made of PF127 copolymer and SPIONs was developed. Gelation process depends on the temperature of the SPIONs/PF127 mixture. This property makes it possible to use the ferrogel as an injectable drug carrier. Unlike other ferrogels based on crosslinked polymeric network, the PF127 ferrogel can entrap and release hydrophobic drugs. Application of an external magnetic field is found to enhance the drug release rate. This property can find application in externally stimulated local drug release applications.
QC20100722

Nanoparticulate delivery systems have been widely used in recent decades, available in a wide variety of structures, for targeted drug delivery. They provide controlled and prolonged release for drugs, peptides and biopharmaceuticals. Ceramic nanoparticles are one of the various nanocarriers, which have been employed in local targeted delivery, most commonly in the area of orthopaedic drug delivery to enhance treatment therapies. This thesis therefore focused on the development of aquasomes, a ceramic nanoparticulate carrier system, for the delivery of proteins, growth factors and antibiotics for its potential application in bone regeneration in fracture healing. The suitability of non-aqueous silicone elastomer gels (NASEGs) as a topical/transdermal delivery system for proteins as well as protein-loaded aquasomes was also investigated. Through process optimisation, a suitable lyophilisation method was developed and used for the preparation of bioactive aquasome formulations of growth factors, bone morphogenetic protein (BMP-2), vascular endothelial growth factor (VEGF-121), and antibiotic, gentamicin. Physical characterisation of aquasomes using zeta potential and optimisation of preliminary aquasome formulations were optimised by utilising smaller nanocore sizes. In addition, scanning electron microscopy (SEM), confocal microscopy analysis and entrapment efficiency studies were performed to ascertain the drug loading efficiency of the different aquasome formulations. BMP-2 loading aquasomes exhibited an entrapment efficiency of 98.9% Protein loading on aquasomes yielded a higher negative zeta potential in comparison to blank nanocores. Confocal microscopy images elucidated the behaviour of nanocore particles showing agglomeration of nanocores and the presence of fluorescent drug adsorbed onto nanocores. The bioactivity of the aquasome formulations were analysed via in vitro cell culture model assays and microbiological assays. BMP-2-loaded aquasomes were investigated for enhanced osteogenic proliferation and differentiation effects on osteoblast-like cells, MG63 cells. The enhanced osteogenic effect of HUVECs in co-culture with these cells was also examined. In addition, the committed differentiation of ATMSCs into osteoblasts induced by their exposure to BMP-2 -loaded aquasomes was also investigated. Results exhibited the enhanced osteogenic differentiation effect, analysed by alkaline phosphatase (ALP) secretion (a major biochemical marker of osteoblastic differentiation) from MG63 cells was dependent on the protein loading onto the aquasome formulation. However, differentiation of ATMSCs cultured in osteogenic medium was significantly higher than ATMSCs exposed to BMP-2 or VEGF-121 treatments. Gentamicin-loaded aquasomes were investigated for their antimicrobial activity against Staphylococcus aureus, a major pathogen popularly implicated in cases of osteomyelitis. Results showed that gentamicin released from aquasomes exhibited excellent bactericidal activity against bacterial cultures without any reproduction of bacteria in 24 hours. In conclusion, the aquasome formulations were able to offer controlled release of bioactive antimicrobials and growth factors over a prolonged duration. The amount of bio-actives released was dependent on the loading of the bio-actives in the fabrication process of aquasome formulations. However, minute (ng/μg) amounts of adsorbed growth factor/drug were observed in comparison to the loading (high ng/mg) within the duration of study. It can be inferred these aquasomes can be employed in the sustained local and targeted delivery of antimicrobials and growth factors in orthopaedic treatments for enhanced fracture healing. However, the loading of bio-actives onto aquasome formulations may need to be optimised to increase the amount of bio-actives released to elicit more pronounced pharmacological effects.

This thesis describes the novel synthesis of eight polyamine-nitrogen mustard conjugates and two polyamine-nitroxide conjugates. The structure-activity relationship of these compounds with DNA has been investigated. The approach started with the regioselective BOC protection of commercially available norspermidine, spermidine and spermine plus the total synthesis of protected polyamines e.g. homospermidine and spermine. The nitrogen mustards chlorambucil and melphalan were conjugated to the polyamines at primary and secondary nitrogens via a variable length amide linkage to give a structural range of differentially charged polyamine-drug conjugates. The spin label 3-carboxy-proxyl was conjugated to a primary and secondary nitrogen of spermine via an amide linkage to give two novel spermine-spin labelled adducts. Electron paramagnetic resonance spin exchange experiments in the presence of DNA gave an indication of translational motion of spermine on the DNA. The DNA cross-linking of the polyamine-nitrogen mustards identified that: (i) spacing between positive charges does not significantly affect the cross-linking efficiency, (ii) increasing the positive charge of the polyamine increases the cross-linking ability of the conjugates (reflecting the trend in binding ability of charged polyamines) and (iii) primary amino polyamine-drug conjugates are more efficient cross-linkers than the corresponding secondary amino conjugates. The polyamine-nitrogen mustard conjugates also showed the same sequence selectivity as the parent drugs i.e. chlorambucil and melphalan. The N7 position in the major groove of DNA is alkylated. Runs of contiguous guanines provide sites of highest alkylation for chlorambucil and the polyamine-drug conjugates. The results imply that the initial site of alkylation is not dictated by the poly amine moiety binding to specific sites on DNA.

Polyanhydrides are useful biodegradable vehicles for controlled drug delivery. In aqueous media the breaking of the anhydride bonds resulting in gradually polymer fragments collapse and release drugs in a controlled manner. In this study, two new biodegradable polyanhydrides copolymers were synthesised using a melt-polycondensation method. The first is poly (bis (p-carboxyphenoxy)-2-butene-co-sebacic acid) (CP2B: SA), which has double bonds along the polymer backbone. The second is crosslinked poly (glutamic acid-sebacic acid-co-sebacic acid) (GluSA: SA), where the conjugated unit of glutamic acid with sebacic acid (glutamic acid-SA) acted as a crosslinking fragment in producing the crosslinking polymer. The two polymers were applied to preparation of microspheres with bovine serum albumin (BSA) as a model protein, using both double emulsion solvent evaporation and spray drying methods. The characterisation of the microspheres, morphology, particle size, and drug loading, was studied. The in vitro hydrolytic degradation of polymers and blank microspheres was monitored using IR, GPC, and DSC. In vitro drug release behaviour was also studied. Though the studies showed cleavages of anhydride bonds occurred rapidly (<5 days), bulks of the polymer microspheres could be observed after a few weeks to a month; and only around 10-35% of the protein was detectable in a four-week period in vitro. We found the pH of the medium exerts a large impact on the release of the protein from the microspheres. The higher the pH, the faster the release. Therefore the release of the protein from the polyanhydride microspheres was pH-sensitive due mainly to the dissolution of monomers from the microspheres.

Homing is the process that stem cells move to their own stem cell niches under the influence of chemokines like stromal-derived factor-1&alpha
(SDF-1&alpha
) upon bone marrow transplantation (BMT). There is a need for increasing homing efficiency after BMT since only 10-15% of the transplanted cells can home to their own niches and a limited amount of donor marrow can be transplanted. In this study, we aimed to develop and characterize bone marrow targeted liposomal SDF-1&alpha
delivery system prepared by extrusion method. Alendronate conjugation was chosen to target the liposomes to bone marrow microenvironment, particularly the endosteal niche. Optimization studies were conducted with the model protein (

Delivery across skin offers many advantages compared to oral or parenteral routes e.g. non-invasive, avoiding first-past metabolism, improved bioavailability and reduction of systemic side effects. Microneedle (MN) are minimally-invasive devices that painlessly by-pass the skin's stratum corneum, which is the principal barrier to topically-applied drugs. Polymeric MN delivery systems were designed and evaluated to transdermally deliver two model drugs, the small water soluble drug ibuprofen sodium and the large protein ovalbumin (OVA). A range of hydrogel forming materials for MN production was evaluated to identify the most suitable super swelling hydrogel MN array that are hard in the dry state but, upon insertion into skin, rapidly take up interstitial fluid. The MN themselves contain no drug, but instead drug are loaded into lyophilized patches. Novel super swelling hydrogel forming MN arrays were fabricated from aqueous blends containing 20% w/w poly(methyl vinyl ether co maleic acid) (Gantrez® S97), 7.5% w/w poly(ethylene glycol) (PEG) and 3% sodium carbonate (Na2C03). In addition, dissolving MN arrays loaded with a high dose of non-potent therapeutic drug were fabricated from aqueous blends of 70% w/w Gantrez® AN139 (PH 7) and 30% ibuprofen sodium. Successful drug delivery was achieved in this research work using novel polymeric MN, super swelling hydrogel MN and dissolving MN. The in vitro studies has been shown first ever example of polymeric MN being loaded with a NSAIDs. The novel concept of super swelling hydrogel MN integrated with lyophilized patches loaded with ovalbumin was evaluated. They enabled the sustained delivery of the ibuprofen sodium and ovalbumin both in vitro and in vivo. Gamma sterilization can be done without compromising polymeric MN properties. Finally, hydrogel forming MN arrays can be successfully and reproducibly applied by human volunteers given appropriate instruction so the use of MN applicator devices may not be necessary, thus possibly enhancing patient compliance.

Development of liposome formulation of an amphiphilic anticancer peptide using the ANTS/DPX leakage assay. The effects of lipid composition on the liposomes' resistance to an amphiphilic cyclic peptide c[KS.S.S.KWL W] were studied by the ANTS/DPX leakage assay. One or more unsaturated acyl chains in the phospholipids, small phospholipid headgroup size, the presence of cholesterol, and the presence of PEG-lipid were demonstrated as critical parameters to stabilize the liposome membrane. A liposome formulation of the peptide comprising POPE/POPC/cholesterol/C16 mPEG 2000 ceramide (20.8:31.2:40:8, mol%) was thereby developed with a peptide-encapsulation efficiency of 47.8%. The liposomal cyclic peptide exhibited dose-dependent toxicity to MCF7 human breast cancer cells and stability under incubation. Design, construction and in vitro characterization of a hydrazone-based convertible liposomal system for anticancer drug delivery. A novel PEG-lipid, PEG2ooo-Hz-DHG, with an acid-labile hydrazone linker between the PEG2ooo head group and the lipidic DHG moiety was synthesized. PEG2000-Hz-DHG was relatively stable at normal physiological pH 7.4, but hydrolyzed more quickly at tumor interstitium pH 6.5-7.0 and endosomal/lysosomal pH 5.0. A novel pH-sensitive "Convertible Liposome System" (CLS) was constructed comprising PEG2ooo-Hz-DHG, positively charged lipid DOTAP, and the zwitterionic phospholipid POPC (8:15:77, mol%). CLS converted from neutrally charged "stealth" liposome to positively charged liposome at tumor interstitual pH owing to the hydrolysis ofPEG2ooo-Hz-DHG. The doxorubicin-encapsulated CLS that had been pre-incubated at pH 6.5 for 30 h exhibited more intensive binding and higher toxicity to Bl6-Fl0 murine melanoma and MDA-MB-435S human breast cancer cells than doxorubicin encapsulated in pH-insensitive stealth liposome.

Delivery of drugs to the posterior segment of the eye is notoriously difficult and unfortunately many chronic conditions of the posterior segment often lead to sight-loss if not treated effectively. Current methods of delivery such as topical drops result in poor bioavailability at the back of the eye, while the blood brain retina imposes restrictions on the entry on drugs into the eye delivered by the systemic system. The gold-standard method for delivery of therapeutic concentrations of drugs is intravitreal delivery, which involves an injection into the vitreous cavity. Although this provides therapeutic levels of drugs, numerous injections are required to maintain these concentrations, and the frequency of injection can cause various adverse effects such as retinal detachment, vitreous haemorrhage and endophthalmitis. The present study investigates the potential use of solvent-induced in situ forming implants (ISFI) as a method of delivering drugs in a prolonged manner to the posterior segment of the eye. These systems are composed of a water-insoluble polymer dissolved in an organic solvent. Their low viscosity allows for easy administration through small-bore needles (e.g. 27 gauge) and on contact with an aqueous environment, such as the vitreous humour, phase inversion through solvent exchange takes place resulting in a biodegradable polymeric implant that can release drugs for an extended period. . As another method to improve posterior drug delivery in a minimally-invasive manner, microneedles (MN) were used to inject small amounts of ISFI formulation into sclera. Drug release and permeation stUdies across sclera indicated that the use of MN did indeed improve scleral permeation, with potential to allow posterior drug delivery from an intrascleral depot. From investigations carried out in the present study, ISFI show promise in transforming drug delivery to the eye and therefore possibly preventing the loss of sight in numerous individuals.

The therapeutic effect of pulmonary drug delivery systems is limited by its rapid clearance from the lungs by robust clearance mechanisms. By controlling the release of drugs, the therapeutic effect of pulmonary drug delivery systems, as well as patient convenience and compliance could be improved by reducing the number of times drugs need to be administered. In this study, two controlled pulmonary drug delivery systems for drugs of different solubilities were investigated and they were characterised for their viability as effective controlled release pulmonary drug delivery systems, particularly in areas of aerosol performance and dissolution profile. A hybrid protein-polymer controlled release pulmonary drug delivery system was developed to sustain the release of a water-soluble anti-asthma drug, cromolyn sodium (CS). Two excipients with complementary characteristics – a protein, bovine serum albumin, and a polymer, polyvinyl alcohol – were formulated together with CS via co-spray drying, with varying protein-polymer ratios and drug loadings. The hybrid particles showed promise in combining the positive attributes of each excipient, with respirable particles shown to sustain the release of CS with a fine particle fraction of 30%. Combining the two excipients was complex, with further optimisation of the hybrid formulations possible. A commercially available polymer, Soluplus® was spray-dried with a poorly-water soluble corticosteroid, beclomethasone dipropionate (BDP). The resultant respirable powders were shown to have potential for use as a controlled release pulmonary drug delivery system with up to 7-fold improvement in the amount of BDP released compared to spray-dried BDP. The spray-dried BDP-Soluplus® powders were found to be amorphous, and physically stable against re-crystallisation for up to 9 months at accelerated stress test conditions with drug loadings of up to 15 % (w/w). Although it provided a platform to compare between formulations, the USP 4 flow-through cell dissolution apparatus was found to be inadequate to accurately study the dissolution profiles of the pulmonary drug delivery systems due to the formation of a gel in the apparatus. Preliminary work on the use of a novel technique to predict the crystallisation of amorphous formulations with terahertz time-domain spectroscopy was also conducted. The system confirmed the re-crystallisation tendencies of several hybrid CS/BSA/PVA formulations. Modification to the experimental setup to probe the formulations at different relative humidities instead of temperatures could yield improved results.

The blood brain barrier (BBB) poses a significant hurdle to brain drug delivery. However, the location of the olfactory mucosa, within the nasal cavity, is a viable target site for direct nose-to-brain (N2B) delivery, thereby bypassing the BBB. To exploit this target site innovative nasal formulations are required for targeting and increasing residency within the olfactory mucosa. We developed and characterised three formulation systems for N2B delivery, (i) thermoresponsive mucoadhesion nasal gels sprays; (ii) mesoporous silica nanoparticles and (iii) nasal pMDI devices. We developed an optimal mucoadhesive formulation system incorporating amantadine as a model, water-soluble anti-Parkinson’s drug using carboxymethy cellulose and chitosan as mucoadhesives. Formulations demonstrated droplet sizes of < 130mm and stability over 8-weeks when stored at refrigeration conditions with no significant cellular toxicity against olfactory bulb (OBGF400) and nasal epithelial (RPMI 2650) cells. Mesoporous silica nanoparticles (MSNP) were prepared (~220nm) and demonstrated cellular uptake into OBGF400 within 2-hours of incubation with minimal toxicity. MSNP were loaded with two novel phytochemicals known to possess CNS activity, curcumin and chrysin, with loading efficiencies of ~12% confirmed through TGA, DSC and HPLC-UV analysis. Furthermore, a pH dependant release profile was identified with curcumin with greater release at nasal cavity pH 5.5 compared to pH 7.4. Furthermore, successful incorporation of MSNP into nasal gels was demonstrated through rheological studies with a decrease in Tsol-gel. A pilot study was conducted to assess the feasibility of modified existing pulmonary pMDI to deliver diazepam intranasally, targeting the olfactory mucosa. Diazepam was formulated with HFA134a and using ethanol as a co-solvent, and demonstrated stability in formulation over 3 months. Deposition studies within a nasal cast model demonstrated 5-6% deposition onto the olfactory mucosa under optimal administration conditions in the absence of any nozzle attachments. Our studies have provided a basis for the development to innovative intranasal formulation systems potentially capable of targeting the olfactory mucosa for both water soluble and poorly soluble drugs.

Polymers are becoming preferred materials in biomedical applications because of their vast diversity of properties, functionalities and applications. Properties as mechanical strength, stability against degradation, biocompatibility and biodegradability, among others, have been attractive for different medical applications. One of the most interesting applications of these materials is drug delivery systems. Biodegradable polymers and copolymers are the preferred materials for the manufacture of a variety of devices for temporal applications in medicine and pharmacology; these biodegradable polymers can be chemically synthesized or biologically produced. Biotechnological polymers have attracted much attention because two main advantages; first, they are produced from renewable resources; and second, as they are biologically produced they are biocompatible, biodegradable and bioresorbable materials. Thus, modification of biotechnological polymers to obtain specific properties or functionalities is a good strategy for the development of promising biomedical materials. In this Thesis the water soluble biotechnological polymer poly(ß,L-malic acid) (PMLA) was modified to change its hydrophilic character to produce non water-soluble polymers capable of forming particulate systems for drug encapsulation and controlled release. PMLA is a polyester-3 with a pendant carboxylic group; it is biocompatible, biodegradable and bioresorbable. The carboxylic side group can be substituted in order to modify the properties of the polymer. The polymer as polyelectrolyte, is also water-soluble. Different strategies were used for polymer derivatization: direct esterification and amidation through the activation of the carboxylic side groups with carbodiimides; ionic complex formation with a cationic drug (Doxorubicin); and esterification with aliphatic long chains by a two step method employing thiol-ene click reactions. Obtained PMLA derivatives resulted in hydrophobic or amphiphilic polymers, which were appropriated for nanoparticle formation, either by emulsion solvent evaporation or by precipitation dialysis techniques. Derivatives physicochemical characterization was made by 1H and 13C nuclear magnetic resonance (NMR) spectroscopy, gel permeation chromatography (GPC) and differential scanning calorimetry. Hydrolytic degradation was followed by GPC and 1H NMR, while particles were observed by scanning electron microscopy and their size and surface charge characterized by dynamic light scattering and ζ-potential measurement. Assays of drug encapsulation and release were also performed and cytotoxicity tests were done on cancer cell lines. Nanoparticles (100-300 nm aprox.) were obtained from all PMLA derivatives, except for the ionic complex which formed microparticles. Nanoparticles showed potential as drug delivery systems since they were able to encapsulate the anticancer drugs Temozolomide and Doxorubicin, as well as the model drugs Theophylline and Carbamazepine. Drug release was assessed under physiological conditions; the release rate was found to depend on encapsulation method, drug and polymer derivative. Hydrolytic degradation assays showed that free malic acid and the organic compound derived from the reagent used for modification were the last products of aqueous degradation of PMLA derivatives. Cytotoxicity tests demonstrated the low toxicity of the synthesized derivatives. Results generated in this Thesis suggest that the biotechnological polymer PMLA is a material of interest as a platform for the design and development of biodegradable drug delivery systems with potential in the therapy of diseases considered today challenging for pharmacologic treatment.

This study evolved to its last form primarily around the development of a hybrid material is the core of the work. This hybrid material is then further explored for two different applications which are catalysis and drug delivery. A nanoassembly was established around a mesoporous silica support. SBA-15 was picked as this support among the other mesoporous silica dueto its well-defined pore structure and accessible pore volume. The silica framework was doped with Zr-atoms and the pores partly infiltrated with Cu nanoparticles resulting in a hybrid material with tunable properties. SBA-15 was synthesized by a sol-gel method where a micellar solution was employed as a template for the silica framework. To achieve the doped version, a Zr precursor was added to the synthesis solution. The effects of different synthesis conditions on the final material were investigated. lt was observed that changes in these synthesis conditions yielded different particle morphology, pore size, and specific surface area. The infiltration method is based on functionalizing the (Zr-) SBA-15 support surfaces before the Cu ion attachment whereas EIWI is based on slow evaporation of the liquid from the (Zr-)SBA-15 - Cu aqueous suspension. Both methods are designed to yield preferential growth of Cu NPs in the pores with a diameter smaller than 1O nm and in oxidized form. However, depending on the infiltration method used different chemical states of the final material is achieved, i.e. Zr content and porous network properties are different. Cu-Zr-SBA-15 nanoassembl ies were used for the catalytic conversion of C02 into valuable fuels such as methanol and dimethyl ether (DME). The effect of different chemical states of the catalyst was investigated. lt was found that the Si precursor had a considerable impact on the overall performance of the catalyst whereas the Cu loading method (lnf or EIWI) changed the catalytic selectivity between DME and methanol. The activity of the catalyst was further investigated in a time-evolution study where the accumulation of each product in the gas phase and the molecular groups attached to the catalyst surface were recorded over time. Accordingly, thermodynamic equilibrium was achieved on the 14th day of the reaction under 250ºC and 33 bar. The resulting total C02 conversion was 24%, which is the thermodynamically highest possible conversion, according to theoretical calculations. lt was also concluded from the experimental results that, DME is formed by a combination of two methoxy surface groups . Additionally, the formation of DME also boosts the total C02 conversion to fuels, which otherwise is limited to 9.5%. The design of Cu-Zr-SBA-15 was also investigated for drug delivery applications, dueto its potential as a biomaterial, e.g. , a filler in dental composites, and the antibacterial properties of Cu. Also, the bioactivity of Si02 and Zr02 was considered to be an advantage . With this aim, Cu infiltrated Zr doped SBA-15 material was prepared by using TEOSas the silica precursor and the lnf-method to grow Cu NPs. The performance of the final material as a drug delivery vehicle was tested by an in-vitro delivery study with chlorhexidine digluconate. The nanoassemblies show a drug loading capacity of 25-40% [mg drug 1 mg (drug+carrier)] . The drug release was determined to be composed of two steps. The presence of Zr and Cu limits the burst release and beneficially slows down the drug release process. The effect of pore properties of SBA-15 was explored in a study where the antibiotic doxycycline hyclate was loaded in SBA-15 materials with different pore sizes. lt was observed that the pore size is directly proportional to the drug loading capacity [mg drug 1 mg (drug+carrier)] and the released drug % (the released drug amounUtotal amount of loaded drug). The release profile was fast, dueto its weak interactions with the SBA-15 and smaller size molecule compared to chlorhexidine digluconate.
Los sistemas de materiales híbridos poseen propiedades multifuncionales. En este trabajo se desarrolló un nanoensamblaje alrededor de un soporte de sílice mesoporoso. Como soporte se seleccionó SBA-15 debido a su estructura de poro bien definida y volumen de poro accesible. La matriz de sílice fue dopada con átomos de Zr y los poros se infiltraron parcialmente con nanopartículas de Cu dando como resultado un material híbrido con propiedades ajustables . La síntesis de SBA-15 se realizó mediante un método de sol-gel en el que se empleó una solución micelar como plantilla para el sílice. Para lograr la versión dopada, se añadió un precursor de Zr a la solución de síntesis. Se investigaron los efectos de diferentes condiciones de síntesis, como el catalizador así como la fuente de Si en las características del material final. Los cambios en estas condiciones de. síntesis dieron lugar a partículas con distinta morfología, tamaño de poro (11-15 nm) y área superficial específica (400-700 m2/g). Las nanopartículas de Cu (NP) se hicieron crecer en el sustrato (Zr-) SBA-15 usando los métodos de infiltración (lnf) o de impregnación húmeda inducida por evaporación (EIWI).Dependiendo del método de infiltración utilizado, se logran diferentes propieddes químicas del material final, es decir, el contenido de Zr y las propiedades de red porosa son diferentes. Los nanoensamblajes de Cu-Zr-SBA-15 producidos bajo diversas condiciones de síntesis se usaron para la conversión catalítica de C02 en combustibles valiosos tales como metanol y dimetil éter (DME). El precursor de Si (TEOS o SMS) tuvo un impacto considerable en el rendimiento global del catalizador mientras que el método de carga de Cu (lnf o EIWI) cambió la selectividad catalítica entre DME y metanol. Por otra parte, la actividad del catalizador se investigó evaluando la acumulación de cada producto en la fase gaseosa y los grupos moleculares unidos a la superficie del catalizador a lo largo del tiempo. Se llegó al equilibrio termodinámico en el día 14 de la reacción a 250 ºC y 33 bar. La conversión total resultante de C02 fue del 24%, que es la conversión termodinámicamente más alta posible, según los cálculos teóricos . El material híbrido sintetizado Cu-Zr-SBA-15 también se investigó para aplicaciones de administración de fármacos, debido a su potencial como material de relleno en compuestos dentales y las propiedades antibacterianas del Cu. Por otra parte, la bioactividad de SiO2 y ZrO2 podría ser ventajosa para esta aplicación. El rendimiento del material final como vehículo de administración de fármacos se probó mediante un estudio de liberación in vitro con digluconato de clorhexidina . Los materiales desarrollados muestran una elevada capacidad de carga de fármaco (25-40%). Los perfiles de liberación del fármaco muestran dos etapas: una primera etapa de liberación rápida de las moléculas del fármaco unidas con interacciones más débiles al sustrato mesoporoso, seguida por la difusión de las moléculas del fármaco que están unidas a la superficie del portador. La presencia de Zr y Cu limita la liberación inicial y reduce la velocidad de liberación del fármaco . En otro estudio se evaluó el efecto del tamaño de poro de SBA-15 en la liberación del antibiótico hiclato de doxiciclina. Se observó que el tamaño de poro es directamente proporcional a la capacidad de carga de fármaco, el porcentaje y la cantidad de fármaco liberado . En resumen, este trabajo demuestra el carácter multifuncional de una nanomatriz diseñada a medida que proporciona información valiosa para dos aplicaciones en catálisis y liberación de fármaco.
Hybridmaterial består av minst två komponenter, vilket ger dem mångfacetterade egenskaper. Detta har gjort att denna typ av material attraktiva sedan länge. Det är dock inte enkelt att tillverka dessa materialsystem. Ett enkelt och effektivt tillvägagångssätt behövs för att tillvara ta de önskade egenskaperna hos varje komponent och få dem att samverka. Denna avhandling bygger huvudsakligen på utvecklingen av ett hybridmaterial.Ett hybridmaterial med en sammansättning bestämd på nanonivå, tillverkades med mesoporös kiseldioxid, SBA-15, som stomme. SBA-15 valdes framför andra typer av mesoporös kiseldioxid på grund av dess väldefinierade porstruktur och stora, tillgängliga porvolym. Kiseldioxiden dopades med zirkoniumatomer och porerna fylldes delvis med kopparnanopartiklar, vilket resulterade i ett hybridmaterial med egenskaper som kunde varieras. SBA-15 tillverkades via en våtkemisk metod där en micellösning används som mall för kiseldioxidens struktur. Vid dopningen tillsätts en zirkoniumkälla till synteslösningen. Effekterna av olika tillverkningsparametrar, till exempel salter med katalytiska egenskaper (salter med F- eller Cl-), olika kiselkällor (tetraetyl ortosilikat eller natriummetasilikat), på materialens egenskaper studerades. Variationer av dessa parametrar ger material med olika form, porstorlekar (11 – 15 nm) och specifik yta (400 – 700 m2/g). Kopparnanopartiklar växtes i (Zr-)SBA-15-stommarna med två metoder: infiltration (Inf) eller indunstningsinducerad våtimpregnering (EIWI). Inf baseras på funktionalisering av (Zr-)SBA-15-stommen innan kopparjoner fick reagera med ytan. EIWI bygger på en blandning av (Zr-)SBA-15 och kopparsalt i en lösning där vätskan långsamt får avdunsta. Båda metoderna är designade för framställning av oxiderade kopparnanopartiklar, mindre än 10 nm i diameter, som ska växa i stommens porer. Dock påverkar infiltrationsmetoden den kemiska sammansättningen hos det slutliga materialet då Zr-koncentrationen och porositeten i stommen ändras. Cu-Zr-SBA-15-sammansättningar, tillverkade med varierande syntesparametrar, användes som katalysatorer för omvandling av CO2 till bränslen såsom metanol och dimetyleter (DME). Resultaten visar att valet av kiselkälla har en stor inverkan på katalysatorns prestanda, samt att metoden för att introducera koppar ändrar den katalytiska selektiviteten mellan DME och metanol. Katalysatorns aktivitet undersöktes även över tid. Ackumuleringen av varje produkt, både i gasfas och på katalysatorns yta, registrerades över tid. Termodynamisk jämvikt nåddes efter att reaktionen fortgått i fjorton dagar vid 250 °C och 33 bar. Den totala CO2-omvandlingen var 24 %, vilket, enligt teoretiska beräkningar, är den termodynamiskt högsta möjliga omvandlingen. Det observerades att DME bildas genom en kombination av två metoxygrupper på katalysatorns yta, samt att bildandet av DME ökar den totala omvandlingen av CO2 till bränsle, vilken annars är begränsad till 9.5 %. Cu-Zr-SBA-15-sammansättningen användes även i läkemedelstillämpningar. De kan användas som biomaterial, e.g., fyllnadsmaterial i tandkompositer, och koppar har antibakteriella egenskaper. Dessutom kan kiseldioxid och zirkoniumdioxid vara bioaktiva vilket ses som en fördel. För denna tillämpning tillverkades Cu-Zr-SBA-15 med TEOS som kiselkälla och Inf-metoden för att växa kopparnanopartiklar. Cu-Zr-SBA-15 lämplighet som bärare av läkemedelet klorhexidindiglukonat testades in vitro. I detta fall uppvisar bäraren en laddningskapacitet [massa laddat läkemedel/(massa laddat läkemedel +massa bärare)] på 25 – 40 %. Frisättningen av läkemedel skedde i två steg. Först frisattes en stor mängd läkemedelsmolekyler. Dessa var löst placerade i håligheter i de mesoporösa stommarna. Därefter frisattes läkemedel via diffusion av molekyler som bundit till stommens yta. De två stegen representerar växelverkan mellan läkemedel – läkemedel- och läkemedel – bärare. Närvaron av zirkonium och koppar begränsar den första frisättningen och förlänger den aktiva tiden, vilket är fördelaktigt ur tillämpningsperspektiv. Effekten av porstorlek hos SBA-15 vid läkemedelsfrisättning undersöktes också i en studie där SBA-15 fylldes med doxycyklinhyklat. Laddningskapaciteten och mängden frisatt läkemedel och andelen av laddat läkemedel som frisätts var båda direkt proportionella mot porstorleken där frisättningen av doxycyklinhyklat dominerades av läkemedel – läkemedelsväxelverkan. Doxycyklinhyklat är en mindre molekyl jämfört med klorhexidindiglukonat och växelverkar svagare med SBA-15 på grund av sin mer anjoniska natur. Sammanfattningsvis visar arbetet den multifunktionella karaktären hos en skräddarsydd nanosammansättning, vilket ger värdefulla insikter i två användningsområden: katalys och läkemedelstransport Materialet testas sedan i två olika tillämpningar: katalys och läkemedelstransport.

Cancer is undoubtedly one of the main threats to global human health and as a result, despite significant advances in the field, new and improved cancer treatments are still in great need. Although chemotherapy (in combination with other therapies) is widely used to suppress the growth of tumours, many of the current anti-cancer drugs suffer from poor selectivity and consequently severe toxicity. In order to conquer these limitations, targeted drug delivery systems have been designed and studied with the primary aim of improving the accuracy of transporting anti-cancer drugs into cancer cells and tissue areas. The overall aim of the work presented in this thesis is to design new anti-cancer drug delivery systems using three different strategies. In Chapter 2, intelligent stimulus-responsive short elastin-like peptides (ELPs) and elastin-based side chain polymers (ESPs) were synthesised. The conformation and aggregation properties of these ELPs and ESPs were studied in different aqueous buffers (varying pH also) using ultraviolet-visible (UV-Vis) spectroscopy and circular dichroism (CD). Of the ELPs investigated, peptide 10 (N-acetylated VPGVG) was found to have the lowest transition temperature at pH 7 (i.e. 45oC). Amongst all the ESPs, PF100-GABA(VPGVG) (29) was proven to have the lowest transition temperature (47oC) which was most likely due to the fact that it had the highest molecular weight. In Chapter 3, gold nanoparticles (GNPs) were synthesised and functionalised with biomolecules including elastin-like peptides (ELPs), elastin-based side chain polymers (ESPs) and the pro-apoptotic peptide D-(KLAKLAK)2 (KLA). The hybrids materials, ELP-GNPs and ESP-GNPs were characterized by UV-Vis, CD and transmission electron microscopy (TEM). The hybrids showed the same temperature sensitive properties as the free ELPs and ESPs previously studied, confirming the successful functionalization of GNPs. The KLA-GNPs were found to have increased anti-cancer activity against HeLa cells compared to the free KLA. In Chapter 4, the pro-apoptotic KLA peptide was conjugated to a series of cell penetrating peptoids (CPPos) to prepare peptoid-peptide hybrids (CPPos-KLA). The anti-cancer, antimicrobial and cell penetrating properties of these peptoid-peptide hybrids were investigated. The results demonstrated an increasing trend in anti-cancer ability of CPPos-KLA hybrids (compared to free KLA) and KLA-CPPo6 (57) gave the lowest IC50 value (ca.8 μM) against HeLa cells.

In this study microgels have been used as novel drug carriers (i.e. a novel controlled drug delivery system) for either dermal or transdermal delivery. The experiments conducted in this project were, firstly, to investigate the uptake and release of model compounds with different physico-chemical properties (i.e. solubility and logKoct/w) to and from two colloidal gel systems. Secondly, the permeation of model compounds across a model skin membrane (silicone membrane), and human epidermis was investigated. The first part of the project was to co-synthesise temperature-sensitive colloidal microgels particles based on a co-polymer of poly(N-isopropylacrylamide) (90%)-co-butyl acrylate (10%) (NIPAM/BA) (90/10)(w/w)%, in the presence of and in the absence of ibuprofen (IBU), methyl paraben (MP), and propyl paraben (PP), by a surfactant-free emulsion polymerisation (SFEP) in water. Physico-chemical properties of the microgels were determined using different techniques including photon correlation spectroscopy (PCS), transmission electron microscopy (TEM), nuclear magnetic resonance (NMR spectroscopy), and turbidimetric analysis (UV-vis). The uptake and release of the model compounds to and from colloidal microgel particles was controlled by the solubility and logKoct/w of the drugs. Their subsequent permeation across a model silicone membrane and human skin, were investigated over a range of temperatures (292 K – 313 K). The transport rate of IBU and, PP from poly(NIPAM) microgel is significantly reduced by two and one order of magnitude, respectively, compared with the transport rate of saturated solutions. A huge reduction in the flux indicates that the microgel retards permeation of the drug across both membranes, and hence the microgel can be considered as a permeation retarder. However, fluxes of MP from poly(NIPAM) microgel are equivalents to fluxes of saturated solutions of MP. There is a clear correlation between the solubility and logKoct/w value of the drugs and the flux value for the microgels, incorporating the drugs, across both types of membranes. In the second part of the work, a co-polymer of poly(NIPAM) (85%) co-butyl acrylate (10%) co-methacrylic acid (5%) (NIPAM/BA/MAA) (85/10/5) microgel was synthesised and investigated as a potential pH and temperature sensitive transdermal delivery device. Three compounds having different logKoct/w and solubilities were incorporated into the microgel, namely: salicylamide (SA), methyl paraben and propyl paraben.