The in vitro and in vivo pharmacokinetic parameters of polylactic-co-glycolic acid nanoparticles encapsulating anti-tuberculosis drugs / L.L.I.J. Booysen

Booysen, Laetitia Lucretia Ismarelda Josephine

January 2012

Tuberculosis (TB) is an infectious, deadly disease, caused by Mycobacterium tuberculosis (M.tb). In 2010, there were 8,8 million incident cases of TB globally. South Africa currently has the third highest TB incident cases worldwide. In an attempt to address the challenges facing TB chemotherapy, among which frequent dosing and long duration of therapy resulting in poor patient compliance, a novel poly(DL-lactic-co-glycolic) acid (PLGA) nanoparticulate drug delivery system (DDS) encapsulating anti-TB drugs was developed. It is hypothesised that this nanoparticulate DDS will address the challenges mentioned by enabling decreased dosing frequency, shortening duration of therapy and minimising adverse side effects. Therefore, favourable modification of pharmacodynamic (PD) and pharmacokinetic (PK) properties of the conventional anti-TB drugs was demonstrated. Furthermore, the nanoparticles will provide a platform for drug delivery to macrophages that serve as hosts for M.tb. The study design was based on determining specific physicochemical properties of the nanoparticulate DDS to elucidate the hypothesis. Spray-dried PLGA nanoparticles were prepared using the double emulsion solvent evaporation technique. In vivo analysis of macrophage uptake and possible immunological response in mice were evaluated. In vitro protein-binding assays of PLGA nanoparticles encapsulating anti-TB drugs isoniazid (INH) and rifampicin (RIF) were performed with subsequent in vivo tissue distribution assays to support protein-binding data generated. Finally, PK/PD analyses were conducted to evaluate the effect of nanoencapsulation on the anti-TB drugs. These involved in vitro assays to determine if sufficient drug was released from the nanoparticles to exhibit minimum inhibitory concentration (MIC) and minimum bactericidal concentrations (MBC). Furthermore, in vivo drug distribution and drug release kinetics assays of encapsulated RIF, INH, pyrazinamide (PZA) and ethambutol (ETB) in a mouse model were performed. The results confirmed that the PLGA nanoparticles (<250 nm, low positive zeta potential) were taken up by macrophages in vivo with no significant immunological effect. Furthermore the nanoparticles were present in the brain, heart, kidneys, lungs, liver and spleen for up to 7 days following once-off oral dosing at 13.23± 0.11%, 16.81± 0.11%, 54.89± 0.95%, 15.61± 1.15%, 48.48± 2.28% and 5.73± 0.21%, respectively. This was further confirmed by drug analysis demonstrating the presence of INH, RIF and ETB at different time points up to 7 days in the lungs, kidneys, liver and spleen. However, PZA was not detected. Nanoencapsulated RIF and INH exhibited MICs and MBCs in vitro over 14 days and these drugs were also observed in plasma for up to 7 days post once-off oral dosing. ETB and PZA were observed up to 3 days. From the results generated, it can be concluded that the nanoparticles were taken up by macrophages without eliciting an immune response. This provides a platform for drug delivery to specific sites. Furthermore, the nanoparticulate DDS exhibited sustained drug release in vitro and in vivo over a number of days above the MIC for the drugs analysed. Sustained drug distribution was also observed. It can therefore be concluded that the hypothesised reduction in dose frequency and duration of therapy for this DDS is a possibility / Thesis (PhD (Pharmaceutics))--North-West University, Potchefstroom Campus, 2013

Tuberculosis

PLGA nanoparticles

Drug delivery systems

Pharmacodynamics

Pharmacokinetics

Protein-binding

Biodistribution

Cytokine expression

Drug release

The in vitro and in vivo pharmacokinetic parameters of polylactic-co-glycolic acid nanoparticles encapsulating anti-tuberculosis drugs / L.L.I.J. Booysen

Booysen, Laetitia Lucretia Ismarelda Josephine

January 2012

Tuberculosis (TB) is an infectious, deadly disease, caused by Mycobacterium tuberculosis (M.tb). In 2010, there were 8,8 million incident cases of TB globally. South Africa currently has the third highest TB incident cases worldwide. In an attempt to address the challenges facing TB chemotherapy, among which frequent dosing and long duration of therapy resulting in poor patient compliance, a novel poly(DL-lactic-co-glycolic) acid (PLGA) nanoparticulate drug delivery system (DDS) encapsulating anti-TB drugs was developed. It is hypothesised that this nanoparticulate DDS will address the challenges mentioned by enabling decreased dosing frequency, shortening duration of therapy and minimising adverse side effects. Therefore, favourable modification of pharmacodynamic (PD) and pharmacokinetic (PK) properties of the conventional anti-TB drugs was demonstrated. Furthermore, the nanoparticles will provide a platform for drug delivery to macrophages that serve as hosts for M.tb. The study design was based on determining specific physicochemical properties of the nanoparticulate DDS to elucidate the hypothesis. Spray-dried PLGA nanoparticles were prepared using the double emulsion solvent evaporation technique. In vivo analysis of macrophage uptake and possible immunological response in mice were evaluated. In vitro protein-binding assays of PLGA nanoparticles encapsulating anti-TB drugs isoniazid (INH) and rifampicin (RIF) were performed with subsequent in vivo tissue distribution assays to support protein-binding data generated. Finally, PK/PD analyses were conducted to evaluate the effect of nanoencapsulation on the anti-TB drugs. These involved in vitro assays to determine if sufficient drug was released from the nanoparticles to exhibit minimum inhibitory concentration (MIC) and minimum bactericidal concentrations (MBC). Furthermore, in vivo drug distribution and drug release kinetics assays of encapsulated RIF, INH, pyrazinamide (PZA) and ethambutol (ETB) in a mouse model were performed. The results confirmed that the PLGA nanoparticles (<250 nm, low positive zeta potential) were taken up by macrophages in vivo with no significant immunological effect. Furthermore the nanoparticles were present in the brain, heart, kidneys, lungs, liver and spleen for up to 7 days following once-off oral dosing at 13.23± 0.11%, 16.81± 0.11%, 54.89± 0.95%, 15.61± 1.15%, 48.48± 2.28% and 5.73± 0.21%, respectively. This was further confirmed by drug analysis demonstrating the presence of INH, RIF and ETB at different time points up to 7 days in the lungs, kidneys, liver and spleen. However, PZA was not detected. Nanoencapsulated RIF and INH exhibited MICs and MBCs in vitro over 14 days and these drugs were also observed in plasma for up to 7 days post once-off oral dosing. ETB and PZA were observed up to 3 days. From the results generated, it can be concluded that the nanoparticles were taken up by macrophages without eliciting an immune response. This provides a platform for drug delivery to specific sites. Furthermore, the nanoparticulate DDS exhibited sustained drug release in vitro and in vivo over a number of days above the MIC for the drugs analysed. Sustained drug distribution was also observed. It can therefore be concluded that the hypothesised reduction in dose frequency and duration of therapy for this DDS is a possibility / Thesis (PhD (Pharmaceutics))--North-West University, Potchefstroom Campus, 2013

Tuberculosis

PLGA nanoparticles

Drug delivery systems

Pharmacodynamics

Pharmacokinetics

Protein-binding

Biodistribution

Cytokine expression

Drug release

Pharmacotherapy for Parkinson's Disease - Observations and Innovations

Nyholm, Dag

January 2003

Pharmacotherapy for Parkinson’s disease (PD) is based on levodopa, the most effective dopaminergic drug. The development of motor complications constitutes the major challenge for new or refined therapies. To evaluate the impact of levodopa pharmacokinetics on motor function, an observational study in the patients’ home environment was carried out. A high variability in plasma levodopa levels was found in all patients, irrespective of treatment regimen. The impact of levodopa pharmacokinetics was further studied in a crossover trial comparing sustained-release tablets and continuous daytime intestinal infusion. Infusion produced significantly decreased variability in plasma levels of levodopa, resulting in significantly normalised motor function. A permanent system for long-term levodopa infusion has been developed and 28 patients have been followed for 87 patient-years. Motor response was generally preserved during the long-term observation period, implying that there is no development of tolerance to infusion therapy. Levodopa tablets are normally used in multiples of 50 or 100 mg, thus a rough estimate of individual dosage. A new concept for individualising levodopa/carbidopa doses with microtablets of 5/1.25 mg is under development. An electronic drug-dispensing device for administering the microtablets was tested on patients with PD. All were able to handle the dispenser and most were interested in future use of the concept. Self-assessment of symptoms is accurate in PD, but traditional paper diaries are associated with low compliance. A wireless electronic diary was compared with a corresponding paper diary. The time-stamped and thus completely reliable patient compliance was 88% with the electronic diary. To conclude, pharmacokinetics of levodopa is the major determinant for motor fluctuations in PD. Every effort to individualise dosage and to smooth out the fluctuations in levodopa concentrations should be made, e.g. by means of microtablets or enteral infusion. Electronic patient diaries for real-time data capture are suitable for PD studies.

Neurosciences

Parkinson's disease

levodopa

pharmacokinetics

infusion

drug delivery systems

electronic patient diary

Neurovetenskap

Neurology

Neurologi

Development of a small molecule drug delivery vehicle for treatment of chronic pulmonary diseases

Lofton, Megan Christina

10 July 2008

Chronic pulmonary disorders, marked by excessive extracellular matrix deposition (ECM) or fibrosis, are the most resistant to present clinical therapies resulting in prognoses of 50% life expectancy three years from diagnosis. Inadequacies of current treatments may be attributable to limitations in non-invasive therapeutic administration modalities. However, with the use of polyketal microparticles (PKMs), a novel drug delivery vehicle, a myriad of therapeutic schemes may be explored. Polyketals are a new polymeric family characterized by tissue biocompatibility, rapid hydrolysis, and benign degradation byproducts making it attuned for pulmonary applications. Potential treatments such as siRNA, oligo nucleotides, enzymes and other biomolecules can be encapsulated within PKMs and administered non-invasively via inhalation. For this study, we selected a model therapeutic peptide, Ac-SDKP, with established anti-fibrotic properties as the load for PKMs. For lung dysfunctions accompanied by fibrotic scarring, Ac-SDKP possesses promise in restoring the normal ECM framework. To assess PKMs viability as a pulmonary drug delivery vehicle three objectives were initially defined: 1) Synthesize particles possessing aerodynamic properties conducive for aerosolization 2) Optimization of the therapeutic load, Ac-SDKP, in PKMs to levels that will translate to clinical dosing concentrations, and 3) Determine the biocompatibility of the PKMs in the lung. Optimization of the Ac-SKDP loading within PKMs and size analysis revealed that a solid in oil in water double emulsion particle synthesis technique produced the most ideal microspheres. Based on previous reports, the loading efficiency attained, when locally dispensed, should reach clinical dosing requirements. Synthesized particles were compatible with aerosolization criteria; i.e., diameters below 3 μm and low polydispersities. In addition, we evaluated PKM tissue biocompatibility using a murine lung model. Examination of bronchoalveolar lavage fluid demonstrated only a slight inflammatory response to intratracheal particle injections of PKMs whereas PLGA, a commonly used biomaterial, elicited a significantly higher response. Histological assessment of the lungs following particle injection verified PKMs biocompatibility superiority. In conclusion, small-diameter PKMs are a suitable delivery system for pulmonary drug delivery, capable of delivering small peptide therapeutics and evading the local inflammatory response. The present work will enable expansion of therapeutic avenues capable of combating chronic lung disease.

Ac-SDKP

Polyketal microparticles

Pulmonary fibrosis

Lungs Diseases

Polymeric drug delivery systems

Biocompatibility

A biocompatible, heparin-binding polycation for the controlled delivery of growth factors

Zern, Blaine Joseph

06 April 2009

The delivery of growth factors has been attempted for a number of different therapies. The approach of delivering therapeutic growth factors in a safe and efficient manner is difficult and certain criteria should be met. These criteria include: binding the appropriate growth factors, maintaining their bioactivity, and delivering these proteins with controllable release kinetics for an extended period of time. These criteria encompass a set of guidelines that hope to mimic in vivo biological events such as neovascularization. The central goal of this thesis is to meet these criteria by introducing a novel delivery strategy for growth factors using a biocompatible polycation and heparin. It was hypothesized that a polycation could interact with heparin to form a complex with the potential to deliver bioactive growth factors with an adaptable release. This hypothesis was tested by examining the release kinetics of bFGF from the complex and investigating whether the released bFGF maintained its bioactivity. The [polycation:heparin:bFGF] complex was formed by mixing the components in water, resulting in a precipitate. This precipitate was able to deliver bFGF with controllable release kinetics and the bioactivity of the released bFGF was higher than bolus bFGF and comparable to heparin stabilized bFGF. This system is expected to have the ability to bind and deliver numerous heparin-binding growth factors. In conclusion, the delivery system developed in this research provides a novel mechanism for controlled release of growth factors. This delivery strategy has met the criteria listed earlier and this research has laid the foundation for a successful delivery vehicle. Further, a biocompatible polycation was synthesized, which is a critical component of the delivery system. This polycation exhibited in vitro and in vivo biocompatibility that was orders of magnitude higher than existing polycations and has the potential to be very useful in a variety of biomedical applications. This design principle is also expected to serve as a platform for the synthesis of other biocompatible polycations.

Polycation

Growth factor delivery

Heaprin

Growth factors

Drug delivery systems

Heparin

Biocompatibility

Quantification and control of ultrasound-mediated cell death modes

Hutcheson, Joshua Daniel

09 July 2008

Ultrasound has been identified as a possible non-invasive drug delivery device that could avoid many of the problems found in traditional therapeutics. Studies have shown that ultrasound can deliver molecules into cells; however, the applicability of ultrasound has been limited due to uncontrollable cellular viability losses after sonication. In this study, we sought to quantify the heterogeneous bioeffects of ultrasound in order to gain more insight into how ultrasound affects cells. We were also concerned with identifying the causes of and preventing programmed cell death caused by ultrasound exposure. In order to accomplish these objectives, we used flow cytometry to group cells into quantifiable characteristic populations. This allowed us to identify the relative importance of different forms of rapid cell death. We found that up to 65% of cells (at the highest ultrasound pressure studied) can lose viability rapidly and, for the first time, quantified them among three distinct populations: (1) cells that retain normal size but lose plasma membrane integrity; (2) intact nuclei surrounded by plasma membrane remnants; (3) debris resulting from cellular lysis. Our analysis was supported by mechanical sorting of these populations and subsequent imaging using confocal microscopy. We then monitored the viable populations for 6 h after ultrasound exposure. Results indicated that up to 15% of viable cells (at the highest ultrasound pressure studied) underwent apoptosis, which we showed was associated with an influx of intracellular Ca2+; therefore, we developed a method of chelating intracellular Ca2+ after sonication in an effort to maintain viability of those cells. Using this technique, we showed for the first time that cells could be saved, and we were able to prevent apoptosis by 50%, thereby increasing the overall viability of cells exposed to ultrasound. We conclude that ultrasound is a useful method to deliver molecules into cells and that appropriate selection of sonication conditions can minimize cell death by rapid and apoptotic mechanisms.

Flow cytometry

Ultrasound

Apoptosis

Cell death

Drug delivery systems

Ultrasonics in medicine

Ultrasonic waves Therapeutic use

Delivery of DNA vaccines against cancer /

Roos, Anna-Karin,

January 2006

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2006. / Härtill 4 uppsatser.

Studies on a novel powder formulation for nasal drug delivery /

Fransén, Nelly,

January 2008

Diss. (sammanfattning) Uppsala : Uppsala universitet, 2008. / Härtill 5 uppsatser.

Modelling nanostructures as nano-oscillators for applications in nanomedicine

Hilder, Tamsyn A.

January 2008

Thesis (Ph.D.)--University of Wollongong, 2008. / Typescript. Includes bibliographical references: leaf 190-205.

Molecular bonding in product engineering

Thote, Amol Janardan, Gupta, Ram B.

January 2005

Dissertation (Ph.D.)--Auburn University, / Abstract. Vita. Includes bibliographic references.