Investigating controlled release pulmonary drug delivery systems

Chia, Leonard Sze Onn

January 2018

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.

Novel Therapeutic Delivery via Cell-Nanoparticle Hybridization

Cooper, Remy C

01 January 2017

The immobilization of surface-modified polyamidoamine (PAMAM) dendrimers on the cell surface introduces a novel approach for efficient and specific cellular uptake of therapeutic-carrying nanoparticles. This cell surface-nanoparticle hybridization event takes place via bioorthogonal copper-free click chemistry between a dibenzocyclooctyne (DBCO) group on the dendrimer surface and azide-capped glycans expressed on the cell membrane through metabolic incorporation of azido sugars. This particular cell-nanoparticle hybridization method can be exploited to deliver a variety of therapeutic, genetic or fluorescent payloads directly into cells. Here, this method was employed to deliver plasmid DNA, siRNA and the hydrophobic anticancer drug Camptothecin (CPT) to enhance transfection and therapeutic efficacy. Native, acetylated, and PEGylated generation 4 (G4) PAMAM dendrimers were conjugated with DBCO. When introduced to azide expressing NIH3T3 fibroblasts and HN12 cancer cells, successful surface hybridization was achieved. The physiochemical properties of PAMAM dendrimers allowed for successful hydrophobic drug encapsulation and electrostatic nucleic acid condensation.

Dendrimer

Drug Delivery

Gene Delivery

Click Chemistry

Exploring controlled drug release from magneto liposomes

Podaru, George

January 1900

Doctor of Philosophy / Department of Chemistry / Viktor Chikan / This thesis focuses on exploring fast and controlled drug release from several liposomal drug delivery systems including its underlying mechanics. In addition, the construction of a pulsed high-voltage rotating electromagnet is demonstrated based on a nested Helmholtz coil design. Although lots of different drug delivery mechanisms can be used, fast drug delivery is very important to utilize drug molecules that are short-lived under physiological conditions. Techniques that can release model molecules under physiological conditions could play an important role to discover the pharmacokinetics of short-lived substances in the body. In this thesis, an experimental method is developed for the fast release of the liposomes’ payload without a significant increase in (local) temperatures. This goal is achieved by using short magnetic pulses to disrupt the lipid bilayer of liposomes loaded with magnetic nanoparticles. This thesis also demonstrates that pulsed magnetic fields can generate ultrasound from colloidal superparamagnetic nanoparticles. Generating ultrasound remotely by means of magnetic fields is an important technological development to circumvent some of the drawbacks of the traditional means of ultrasound generation techniques. In this thesis, it is demonstrated that ultrasound is generated from colloidal superparamagnetic nanoparticles when exposed to pulsed and alternating magnetic fields. Furthermore, a comparison between inhomogeneous and homogeneous magnetic fields indicates that both homogeneous and inhomogeneous magnetic fields could be important for efficient ultrasound generation; however, the latter is more important for dilute colloidal dispersion of magnetic nanoparticles. In strong magnetic fields, the ultrasound generated from the colloidal magnetic nanoparticles shows reasonable agreement with the magnetostriction effect commonly observed for bulk ferromagnetic materials. At low magnetic fields, the colloidal magnetic nanoparticle dispersion produces considerable amount of ultrasound when exposed to a.c. magnetic fields in the 20−5000 kHz frequency range. It is expected that the ultrasound generated from magnetic nanoparticles will have applications toward the acoustic induction of bioeffects in cells and manipulating the permeability of biological membranes

Ultrasound generation

Magneto liposomes

Drug delivery

Improvement of longevity and signal quality in implantable neural recording systems

Zargaran Yazd, Arash

05 1900

Application of neural prostheses in today's medicine successfully helps patients to increase their activities of daily life and participate in social activities again. These implantable microsystems provide an interface to the nervous system, giving cellular resolution to physiological processes unattainable today with non-invasive methods. The latest developments in genetic engineering, nanotechnologies and materials science have paved the way for these complex systems to interface the human nervous system. The ideal system for neural signal recording would be a fully implantable device which is capable of amplifying the neural signals and transmitting them to the outside world while sustaining a long-term and accurate performance, therefore different sciences from neurosciences, biology, electrical engineering and computer science have to interact and discuss the synergies to develop a practical system which can be used in daily medicine practice. This work investigates the main building blocks necessary to improve the quality of acquired signal from the micro-electronics and MEMS perspectives. While all of these components will be ultimately embedded in a fully implantable recording probe, each of them addresses and deals with a specific obstacle in the neural signal recording path. Specifically we present a low-voltage low-noise low-power CMOS amplifier particularly designed for neural recording applications. This is done by surveying a number of designs and evaluating each design against the requirements for a neural recording system such as power dissipation and noise, and then choosing the most suitable topology for design and implementation of a fully implantable system. In addition a surface modification method is investigated to improve the sacrificial properties and biocompatibility of probe in order to extend the implant life and enhance the signal quality. / Applied Science, Faculty of / Electrical and Computer Engineering, Department of / Graduate

Neural amplifier

Drug delivery

MEMS

VLSI

Evaluation of the pinocytic uptake and cellular processing of antibody-HPMA copolymer conjugates and estimation of their potential use in targeted drug delivery

Flanagan, P. A.

January 1987

No description available.

615.1

Drug delivery to cancer cells

Stimuli-Responsive Liposomes for Controlled Drug Delivery

Li, Wengang

09 1900

Liposomes are promising drug delivery vesicles due to their biodegradibility, large volume and biocompatibility towards both hydrophilic and hydrophobic drugs. They suffer, however, from poor stability which limits their use in controlled delivery applications. Herein, a novel method was devised for modification of liposomes with small molecules, polymers or nanoparticles to afford stimuli responsive systems that release on demand and stay relatively stable in the absence of the trigger.. This dissertation discusses thermosensitive, pH sensitive, light sensitive and magnetically triggered liposomes that have been prepared for controlled drug delivery application. RAFT polymerization was utilized for the preparation of thermosensitive liposomes (Cholesterol-PNIPAm) and acid-labile liposomes (DOPE-PAA). With low Mw Cholesterol-PNIPAm, the thermosensitive liposomes proved to be effective for controlled release and decreased the cytotoxicity of PNIPAm by eliciting the polymer doses. By crosslinking the DOPE-PAA on liposome surface with acid-labile diamine linkers, DOPE-PAA liposomes were verified to be sensitive at low pH. The effects of polymer structures (linear or hyperbranched) have also been studied for the stability and release properties of liposomes. Finally, a dual-responsive Au@SPIO embedded liposome hybrid (ALHs) was prepared with light-induced “on-and-off” function by photo-thermal process (visible light) and instant release properties triggered by alternating magnetic field, respectively. The ALH system would be further applied into the cellular imaging field as MRI contrast agent.

Liposomes

drug delivery

stimuli responsive

lipid polymer

An Examination of Transdermal Drug Delivery Using a Model Polyisobutylene Pressure Sensitive Adhesive

Trenor, Scott Russell

27 September 2001

This work was performed as a preliminary transdermal drug delivery (TDD) study to investigate the diffusion characteristics and effects of skin surfactants in vitro of four active ingredients on a poly(dimethyl siloxane) polycarbonate copolymer membrane. A Franz-type diffusion cell and various receptor solutions were used. The adhesive used was comprised of a polyisobutylene-based pressure sensitive adhesive manufactured by Adhesives Research Inc. High performance liquid chromatography was used to analyze the diffusion characteristics of these systems. In addition, the effects of two skin surfactants (sodium lauryl sulfate and dimethyl sulfoxide) on the adhesive were also investigated. Results from peel testing and thermal analysis showed that the peel strength, glass transition, and softening temperature of the adhesive was greatly reduced with the addition of the surfactants. / Master of Engineering

peel testing

surfactant plasticization

Transdermal drug delivery

The formulation and characterisation of corticosteroid loaded Ethosomes for topical delivery

Martin, Björn Franklin

January 2020

Magister Pharmaceuticae - MPharm / Background/Introduction: Atopic dermatitis (AD) is one of the most prevalent diseases worldwide. It is a rapidly growing field of study with several research avenues to explore its pathophysiology and to find innovative treatment and management regimens. Clinically, it is classified as a non-contagious, intensely pruritic, inflammatory, chronic skin disorder mediated by abnormalities associated with atopy. Symptoms include inflammation, redness, pain and a negative impact on the patient‘s overall quality of life. Chronic itching often leads to the formation of lichenified skin, which may increase the thickness of the epidermis and exacerbate the barrier function of the skin. AD is treated with topical corticosteroids which help to decrease inflammation. However, lichification of the skin may decrease the efficacy of topical dosage forms. Nanomedicine is a rapidly developing field where advances have been made using ethosomes for topical delivery. As such, corticosteroid loaded ethosomal formulations containing hydrocortiosone acetate (HCA) and betamethasone valerate (BMV) were developed and characterised to develop novel tools for topical drug delivery. Aim: This study aimed at developing corticosteroid loaded ethosomes as a pre-formulation component for inclusion in a topical dosage form. To date, no ethosmal formulation with HCA and BMV has been investigated for topical drug delivery. Method: Ethosomes were synthesised using the hot method and the cold method, a modified version of a double emulsion (o/w/o), solvent evaporation technique, as developed by Touitou et al, 2007.1 Ethosomes were prepared using fixed concentrations of either BMV or HCA (10 mg/ml), ethanol (30% v/v) and purified water (70% v/v) and were comminuted using bath sonication or mini-extrusion. Centrifugation and centrifugal drying were used to purify and isolate the ethosomes for solid state characterisation. The morphology was determined using Scanning electron microscopy (SEM). Ethosomes were characterised using: dynamic light scattering (DLS), Fourier-transform infrared spectroscopy (FTIR), hot stage microscopy (HSM), differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA). The encapsulation efficiency (EE) and drug loading (DL) were determined using validated HPLC methods. Finally, the drug release was determined using Franz diffusion cells and mathematical models were fitted to the % cumulative release data to determine the release kinetics. Results: Ethosomes were assessed according to the following criteria for topical drug delivery which were determined using dynamic light scattering (DLS): Hydrodynamic diameter (HdD), ~ 200 nm, polydispersity index (PdI) < 0.5 and zeta potential (ζp) ± 30 mV. The optimum formulations contained phosphatidylcholine (PC) 50 mg/ml. Extrusion was found to be the best method for particle reduction based on the reproducibility of the results. The HdD was 163.8±31.99 and 147.7±19.91 for BMV loaded ethosomes and HCA loaded ethosomes respectively and both formulations had an acceptable PdI of 0.049 and 0.111, respectively. SEM analyses indicated that the ethosomes had a spherical shape. Encapsulation of the APIs was verified by the thermoanalyses and possible intermolecular interactions were identified using FTIR. BMV loaded and HCA loaded ethosomes had a respective EE of 74.57 % and 37.30 %, and a DL of 14.91 % and 7.46 %, respectively. The release kinetics best fit the Peppas-Sahlin model indicative of an anomalous non-Fickian diffusion coupled with polymer relaxation and zero order release. Conclusions: BMV and HCA loaded ethosomes for topical drug delivery were successfully synthesised and characterised. These novel nanoparticles have provided an array of avenues for further investigation and application in the topical delivery of corticosteroids

Hydrocortisone

Betamethasone

Nanoparticles

Topical drug delivery

Highly Tunable and Degradable Hydrophobized Nanogels for the Intranasal Delivery of Poorly-Water Soluble Antipsychotic Drugs to the Brain

Simpson, Madeline J.

January 2020

Nanogels are soft, deformable networks of cross-linked polymer swollen in water. Nanogels have the unique ability to swell in response to external physiological conditions. Their stimuli-responsive nature affects degradability, drug uptake and release, which can be exploited to create tunable drug delivery systems. The ability to alter the composition and structure of nanogels imparts advantageous characteristics for targeted drug delivery applications. Antipsychotic drugs (APDs) used to treat schizophrenia, a chronic neuropsychiatric disorder, are typically hydrophobic. Prolonged dosing causes neurological and metabolic side effects due to the systemic administration of drug. Patient adherence to APD administration is low, causing complications that contribute to the substantial burden of disease. APDs would benefit from nanogel encapsulation through improved solubility and controlled release kinetics to reduce the adverse side effects associated with typical administration protocols. This thesis presents the development of hydrophobized, biodegradable poly(oligoethylene glycol methacrylate) (POEGMA)-based nanogels to deliver APDs to the brain. Both an adaptation of conventional precipitation polymerization as well as a spontaneous self-assembly technique are utilized to synthesize nanogels containing different hydrophobic domains. Incorporation of cross-linkers with different modalities of biodegradability enable stimuli-responsive degradation and drug release. The effects on nanogel swelling, biodegradability, and APD uptake and release kinetics are explored in vitro. The preclinical application of these APD-loaded nanogels is evaluated using the minimally invasive intranasal (IN) route for delivery. We show that these nanogel delivery systems have therapeutic effects in terms of significantly altering a range of rodent behaviours, including locomotion inhibition, the onset of catalepsy, and improvement in pre-pulse inhibition, over extended periods of time in relation to current administration strategies. These drug-loaded nanogel delivery systems show potential to minimize the effective therapeutic dose by enhancing APD bioavailability via IN administration, thus reducing adverse outcomes and improving potential patient adherence to APD-based therapies in clinical use. / Thesis / Doctor of Philosophy (PhD) / Nanogels are soft, deformable polymer networks swollen in water with potential for drug delivery given their easy-to-tune physicochemical properties. However, the poor water solubility of many therapeutics, including antipsychotic drugs (APDs) used to treat schizophrenia, limits drug encapsulation within nanogels. In addition, conventional synthetic techniques produce materials that degrade into poorly-defined byproducts, causing toxicity concerns. This thesis presents novel strategies to incorporate hydrophobic domains and biodegradable bonds within poly(oligo ethylene glycol methacrylate) (POEGMA) nanogels. We demonstrate how these moieties affect nanogel swelling, degradability, cytocompatability as well as the uptake and release of clinically prescribed APDs. Intranasal (IN) administration of drug-loaded nanogels is studied as a non-invasive delivery alternative to improve drug bioavailability. The proposed nanogel-based drug delivery systems can decrease drug dose, minimize adverse side effects, and improve patient adherence to therapeutic regimens relying on APDs, demonstrating their potential for clinical application.

Nanogel

Drug Delivery

Intranasal

Antipsychotic Drugs

Enhanced Killing of Mycobacterium abscessus by Nanosponge Delivery of Antimycobacterials

Albano, Casey

09 August 2023

The increasing prevalence of bacterial infections has made it necessary to find novel methods of combatting the resistance of bacteria to conventional antibiotics. Mycobacterium abscessus is an increasingly prevalent pathogen that is intrinsically drug resistant, therefore difficult to treat. The use of phytochemicals as a source of alternate antibiotics has been explored, however, the poor solubility of phytochemicals in water makes it difficult to effectively deliver them to bacterial biofilms. In this study, I investigated the efficacy of nanosponge-emulsified phytochemicals in killing M. abscessus biofilms. The nanosponge technology was used to improve the solubility and stability of the phytochemicals, allowing for improved bioavailability. Results showed that the nanosponge-emulsified phytochemicals effectively reduced the viability of M. abscessus biofilms, compared to non-emulsified phytochemicals. The findings of this study contribute to a development of new strategies for the treatment of bacterial infections and demonstrate the potential of nanosponge-emulsified phytochemicals as a promising alternative to conventional antibiotics.

Nanosponge

Mycobacteria

Drug Delivery

Biofilm

Microbiology