Formulation, in vitro release and transdermal diffusion of acyclovir and ketoconazole for skin conditions in HIV/AIDS patients / Gerda Alida Jacobs

Jacobs, Gerda Alida

January 2009

The aim of this in vitro study was to investigate the efficacy of the novel Pheroid™ technology system in a semi-solid dosage form, for the topical delivery of acyclovir (5% w/w), an anti-viral agent and ketoconazole (2% w/w) an anti-fungal agent. The human immununodeficiency virus (HIV) had an immense impact on the spectrum of diagnosis of cutaneous diseases since its first manifestation in the late 1970's (Yen-More et al., 2000:432). The skin is the most commonly affected organ in HIV infected individuals with skin manifestations present in up to 92% of HIV-positive patients. According to Ramdial (2000:113) the skin may also be the first or the only organ affected throughout the course of the HIV/AIDS disease. HIV/AIDS patients are more susceptible to infections due to their compromised immune systems (Durden & Elewski, 1997:200) and an exceptionally wide range of infectious skin manifestations presents in HIV/AIDS infected individuals, some of which are viral and fungal. Acyclovir is an anti-viral active against herpes simplex virus type 1 and type 2, varicella-zoster virus, Epstein-Barr virus and the cytomegalovirus (Hayden, 2001:1317). The anti-fungal drug, ketoconazole has activity against the majority of pathogenic fungi which include Candida species and Histoplasma capsulatum (Bennett, 2001:1301). It is appropriate to formulate a topical product containing both acyclovir and ketoconazole because viral and fungal cutaneous manifestations are regularly encountered in combination in HIV/AIDS infected individuals,. This combination topical product may be useful in the treatment of viral and fungal opportunistic skin manifestations. Curing these skin lesions may also assist to improve the state of mind and wellbeing of infected individuals. The skin, however, acts as a barrier against diffusion of substances through the underlying tissue. The main problem in transdermal and dermal delivery of actives is to overcome the stratum corneum, the skin's natural barrier (Menon, 2002:4). The Pheroid™ delivery system can promote the absorption and increase the efficacy of a selection of active ingredients in dermatological preparations (Grobler et al., 2008:284). The aim of this study was to formulate a stable semi-solid product containing Pheroid™ to determine whether Pheroid™ technology would enhance the flux and/or delivery of acyclovir and ketoconazole to the epidermal and dermal layers of the skin. In vitro studies and tape stripping were used to determine the effect that the Pheroid™ delivery system had on skin permeation of acyclovir and ketoconazole in semi-solid formulations. The formulae containing no Pheroid™ were used as a control against which the efficacy of the formulations containing Pheroid™ was measured. The stability of the formulated semi-solid products was examined over a period of 6 months according to the International Conference of Harmonisation (ICH) Tripartite Guidelines (2003) and the Medicines control council (MCC) of South Africa (2006). The formulated products were stored at three different temperatures. The stability tests included the assay of the actives and other attributes in the formulation, pH, viscosity, mass loss and particle size observation. These tests were conducted at 0, 1, 2, 3 and 6 months. The results demonstrated that the transdermal flux, epidermal and dermal penetration of acyclovir was enhanced by the Pheroid™ cream formulation. Ketoconazole's transdermal flux as well as delivery to the epidermal and dermal layers of the skin was improved by the Pheroid™ emulgel formula. The topical delivery of ketoconazole and acyclovir was thus enhanced by Pheroid™ technology. The Pheroid™ formulations, however, did not meet the requirements for stability according to the ICH and MCC. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2010.

Acyclovir

Ketoconazole

Topical delivery

HIV/AIDS

PheroidTM technology

Formulation

Peroral and nasal delivery of insulin with PheroidTM technology / Ian D. Oberholzer

Oberholzer, Ian Dewald

January 2009

Since its initial discovery in 1922 by Banting and Best, the formulation of an oral insulin delivery system has ever been so troublesome. Unfortunately, insulin is indispensable in the treatment of diabetes mellitus, which affects approximately 350 million people worldwide. Various factors contribute to the peptide being such a persistently difficult hormone to be used in an oral formulation. The gastrointestinal tract is home to various protein digestive enzymes such as pepsins in the stomach and trypsin, chymotrypsin and carboxypeptidases in the small intestine, which digests insulin. Also the physical barrier of the gastrointestinal tract, i.e. the columnar epithelial layer which lines the tract, is a tightly bound collection of cells with minimal leakage and is thus a sound barrier for the absorption of peptides and hormones. The aim of this study is to determine whether a dosage form for insulin, entrapped in Pheroid™ vesicles and -micro sponges, can overcome these barriers and successfully deliver insulin at the site of action resulting in a significant therapeutic response. Initial phases of the study consisted of the manufacturing of Pheroid™ vesicles and - microsponges, entrapment of flourescein-isothiocyanate labelled insulin (FITC-insulin) into the Pheroid™. The Pheroid™-insulin complex was analysed with confocal laser scanning microscopy (CLSC) to determine drug loading. In vivo experiment in Sprague - Dawley rats were done where blood glucose levels as well as insulin blood levels were monitored after administration of different Pheroid insulin formulations. Firstly a standard reference was set by subcutaneous injection of insulin (0.5 IU/kg) in rats followed by a comparative study where administration to the stomach, colon and ileum (50.0 IUlkg insulin) were compared by means of blood insulin levels and therapeutic effect between the control and Pheroid™ complexes (Pheroid™ vesicles and microsponges). Each study was done by means of direct injection into the stomach, ileum or colon through which the insulin in saline (control) or insulin-Pheroid™ complex was administered. Nasal administration of 8.0 and 12.0 IU/kg insulin in saline (control) or insulin-Pheroid™ complex was done in the right nostril of Sprague - Dawley rats. Blood samples were taken from the artery carotis communis by means of an inserted cannula. Blood samples were taken just before administration and then at 5, 10, 15, 30, 60, 120 and 180 minutes after administration. Blood glucose levels were measured just after every blood sample was taken and plasma insulin levels were determined with a human insulin specific radioimmunoassay. The results were compared to the reference as well as the control to determine relative bioavailability. Through the results obtained it was discovered that in comparison with the various parts of the or tract, the ileum showed undoubtedly to be the best area of absorption where Pheroid™ vesicles revealed a peak 42.0 % lowering in blood glucose levels after 60 minutes and a peak plasma concentration of 244.0 /uID/ml after 5 minutes together with an 18.7 % lowering in blood glucose levels after just 5 minutes. After nasal administration of Pheroid™ microsponges (8.0 ID/kg insulin) a remarkable lowered blood glucose level of 19.2 % after 10 minutes and 36.5 % after 30 minutes as well as a peak plasma insulin level of220.2 /lID/ml after 3 hours was observed. Insulin entrapped in Pheroid™ microsponges administered at 12.0 ID/kg showed a maximum blood glucose lowering effect of72.4 % after 3 hours with a peak plasma level of 154.8 uID/ml also after 3 hours, thus showing a long acting effect. In conclusion, the delivery system based on Pheroid™ technology shows a sufficient therapeutic effect for insulin and is therefore promising for further in vivo evaluation and ultimately for medicinal use to patients suffering from diabetes mellitus. / Thesis (Ph.D. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2009.

Insulin

Nasal delivery

PheroidTM

Oral delivery

Microsponges

Diabetes mellitus

Formulation, in vitro release and transdermal diffusion of selected retinoids / Arina Krüger

Krüger, Arina

January 2010

Acne is a multifactorial skin disease affecting about 80 % of people aged 11 to 30. Several systemic and topical treatments are used to treat existing lesions, prevent scarring and suppress the development of new lesions. Topical therapy is often used as first line treatment for acne, due to the location of the target organ, the pilosebaceous unit, in the skin. Retinoids are widely used as oral or topical treatment for this disease, with tretinoin and adapalene being two of the most used topical retinoids. The transdermal route offers several challenges to drug delivery, e.g. the excellent resistance of the stratum corneum to diffusion, as well as variable skin properties such as site, age, race and disease. Some additional difficulties are associated with the dermatological delivery of tretinoin and adapalene, which include suboptimal water solubility of the retinoids, isomerisation of tretinoin in the skin, mild to severe skin irritation, as well as oxidation and photo–isomerisation of tretinoin, even before crossing the stratum corneum. Researchers constantly strive to improve dermatological retinoid formulations in order to combat low dermal flux, skin irritation and instability. The release kinetics of tretinoin varies greatly according to the way in which it is incorporated into the formulation and according to the type of formulation used. Little research has been conducted regarding improved formulations for adapalene. Pheroid technology is a patented delivery system employed in this study in order to improve the dermal delivery of retinoids. Tretinoin and adapalene were separately incorporated into castor oil, vitamin F and Pheroid creams. The creams were evaluated in terms of their in vitro retinoid release, in vitro transdermal diffusion and stability. Castor oil and Pheroid creams were superior in terms of release and dermal delivery of adapalene. Tretinoin was best released and delivered to the dermis by castor oil cream. The castor oil creams were the most stable formulations, whereas the Pheroid creams were the most unstable. In terms of release, dermal diffusion and stability, castor oil cream proved to be the most suitable cream for both tretinoin and adapalene. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2011.

Tretinoin

Adapalene

Dermal delivery

PheroidTM

Castor oil

Vitamin F

Stability

Tretinoïen

Adapaleen

Dermale aflewering

PheroidTM

Kasterolie

Vitamien F

Stabiliteit

Pharmaceutical applications of PheroidTM technology / Anne F. Grobler

Grobler, Anne Frederica

January 2009

For a drug to have a therapeutic effect, it has to reach its site of action in sufficient quantities. The Pheroid drug delivery system enhances the absorption of drugs in various pharmacological categories and is the focus of this study. A number of patents are registered in various countries to protect its application. Pheroid technology is trademarked, but may for ease of reading, be called Pheroid(s) only. The Pheroid itself is composed of an organic carbon backbone composed of unsaturated fatty acids with some side-chain interactions that result in self-emulsifying characteristics. The resulting vesicles and nano-sponges can entrap hydrophilic, hydrophobic or amphiphilic compounds for biomedical and agricultural application and can be manipulated as to loading ability, mechanical resistance, permeability, size and solubility. Pheroid was investigated for its potential use in the areas of vaccines, peptide drugs, topical products and cosmeceuticals, antimicrobial treatments and agriculture. In all of these areas, the Pheroid has indeed shown applicability: the results showed improved uptake and/or efficacy of the entrapped chemical or biological compounds after administration by a number of administration routes. For oral administration, a precursor format, the pro-Pheroid, was used, wherein the vesicles and/or sponges are formed post-administration. Proof of concept studies on the in vivo absorption and bioavailability, as well as studies on in vitro efficacy of Pheroid-based formulations were carried out for antimicrobials, such as tuberculosis drugs, antimalarials and antiretrovirals. In all cases, the in vitro efficacy of the active compounds was increased, compared to well-known standard drug treatments. In a phase I bio-equivalence study, a Pheroid-containing combination formulation was compared against the comparative market leader. The results demonstrated that the bioavailability of the active compounds in the Pheroid was at least as good but mostly significantly better than that of the comparative medication. In addition, the incidence of side-effects was decreased in the case of the Pheroid formulations. Furthermore, in vitro results indicate that drug resistance can at least partially be negated. Pheroid technology may also be capable of protecting labile drugs such as peptides against degradation and increasing efficacy so that lower dosages can be administered less frequently and with fewer side effects. Based on in vitro and in vivo results, a number of products are currently in development. The application of Pheroid technology is potentially limitless and includes such areas as TB, malaria, cancer, AIDS, gene delivery, vaccines, patented medicines and generics and agriculture. / Thesis (Ph.D. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2010.

Delivery system

PheroidTM technology

Cosmetics

Anti-infective

Vaccines

Peptides

Plants

Afleweringsisteem

PheroidTM tegnologie

Kosmetika

Anti-infektief

Entstowwe

Peptiede

Plante

Formulation, in vitro release and transdermal diffusion of selected retinoids / Arina Krüger

Krüger, Arina

January 2010

Acne is a multifactorial skin disease affecting about 80 % of people aged 11 to 30. Several systemic and topical treatments are used to treat existing lesions, prevent scarring and suppress the development of new lesions. Topical therapy is often used as first line treatment for acne, due to the location of the target organ, the pilosebaceous unit, in the skin. Retinoids are widely used as oral or topical treatment for this disease, with tretinoin and adapalene being two of the most used topical retinoids. The transdermal route offers several challenges to drug delivery, e.g. the excellent resistance of the stratum corneum to diffusion, as well as variable skin properties such as site, age, race and disease. Some additional difficulties are associated with the dermatological delivery of tretinoin and adapalene, which include suboptimal water solubility of the retinoids, isomerisation of tretinoin in the skin, mild to severe skin irritation, as well as oxidation and photo–isomerisation of tretinoin, even before crossing the stratum corneum. Researchers constantly strive to improve dermatological retinoid formulations in order to combat low dermal flux, skin irritation and instability. The release kinetics of tretinoin varies greatly according to the way in which it is incorporated into the formulation and according to the type of formulation used. Little research has been conducted regarding improved formulations for adapalene. Pheroid technology is a patented delivery system employed in this study in order to improve the dermal delivery of retinoids. Tretinoin and adapalene were separately incorporated into castor oil, vitamin F and Pheroid creams. The creams were evaluated in terms of their in vitro retinoid release, in vitro transdermal diffusion and stability. Castor oil and Pheroid creams were superior in terms of release and dermal delivery of adapalene. Tretinoin was best released and delivered to the dermis by castor oil cream. The castor oil creams were the most stable formulations, whereas the Pheroid creams were the most unstable. In terms of release, dermal diffusion and stability, castor oil cream proved to be the most suitable cream for both tretinoin and adapalene. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2011.

Tretinoin

Adapalene

Dermal delivery

PheroidTM

Castor oil

Vitamin F

Stability

Tretinoïen

Adapaleen

Dermale aflewering

PheroidTM

Kasterolie

Vitamien F

Stabiliteit

Pharmaceutical applications of PheroidTM technology / Anne F. Grobler

Grobler, Anne Frederica

January 2009

For a drug to have a therapeutic effect, it has to reach its site of action in sufficient quantities. The Pheroid drug delivery system enhances the absorption of drugs in various pharmacological categories and is the focus of this study. A number of patents are registered in various countries to protect its application. Pheroid technology is trademarked, but may for ease of reading, be called Pheroid(s) only. The Pheroid itself is composed of an organic carbon backbone composed of unsaturated fatty acids with some side-chain interactions that result in self-emulsifying characteristics. The resulting vesicles and nano-sponges can entrap hydrophilic, hydrophobic or amphiphilic compounds for biomedical and agricultural application and can be manipulated as to loading ability, mechanical resistance, permeability, size and solubility. Pheroid was investigated for its potential use in the areas of vaccines, peptide drugs, topical products and cosmeceuticals, antimicrobial treatments and agriculture. In all of these areas, the Pheroid has indeed shown applicability: the results showed improved uptake and/or efficacy of the entrapped chemical or biological compounds after administration by a number of administration routes. For oral administration, a precursor format, the pro-Pheroid, was used, wherein the vesicles and/or sponges are formed post-administration. Proof of concept studies on the in vivo absorption and bioavailability, as well as studies on in vitro efficacy of Pheroid-based formulations were carried out for antimicrobials, such as tuberculosis drugs, antimalarials and antiretrovirals. In all cases, the in vitro efficacy of the active compounds was increased, compared to well-known standard drug treatments. In a phase I bio-equivalence study, a Pheroid-containing combination formulation was compared against the comparative market leader. The results demonstrated that the bioavailability of the active compounds in the Pheroid was at least as good but mostly significantly better than that of the comparative medication. In addition, the incidence of side-effects was decreased in the case of the Pheroid formulations. Furthermore, in vitro results indicate that drug resistance can at least partially be negated. Pheroid technology may also be capable of protecting labile drugs such as peptides against degradation and increasing efficacy so that lower dosages can be administered less frequently and with fewer side effects. Based on in vitro and in vivo results, a number of products are currently in development. The application of Pheroid technology is potentially limitless and includes such areas as TB, malaria, cancer, AIDS, gene delivery, vaccines, patented medicines and generics and agriculture. / Thesis (Ph.D. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2010.

Delivery system

PheroidTM technology

Cosmetics

Anti-infective

Vaccines

Peptides

Plants

Afleweringsisteem

PheroidTM tegnologie

Kosmetika

Anti-infektief

Entstowwe

Peptiede

Plante

Transdermal delivery of 5-Fluorouracil with PheroidTM technology / C.P. van Dyk

Van Dyk, Christina Petronella

January 2008

Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2008.

5-Fluorouracil

Franz diffusion cell

Heat separated epidermis

Skin penetration

Transdermal

Drug delivery system

PheroidTM

Transdermal delivery of 5-Fluorouracil with PheroidTM technology / C.P. van Dyk

Van Dyk, Christina Petronella

January 2008

5-Fluorouracil (5FU) is a pyrimidine analogue, indicated for the therapy of proliferative skin diseases such as actinic keratosis (AK), superficial basal cell carcinoma and psoriasis. It has also been used for the treatment of solid tumours like colorectal, breast and liver carcinomas for nearly 40 years. Although 5FU has always been administered parenterally and orally, metabolism is rapid and absorption is erratic. Several severe side-effects are also commonly associated with 5FU therapy, including myelosuppression, hand-foot syndrome and gastrointestinal effects. Seeing that 5FU is an important part of the treatment of several malignant and pre-malignant disorders, it would be advantageous to find a delivery route and delivery system that negate absorption and metabolic variation and decrease side-effects. The transdermal route provides a promising alternative to the above-mentioned conventional delivery routes, solving most of the problems associated with parenteral and oral administration. That being said, the formidable barrier situated in the skin is not easily breached. The stratum corneum, the outermost skin layer, is mostly lipophilic in nature, preventing hydrophilic molecules such as 5FU from entering. 5FU-containing creams and lotions are currently commercially available, but absorption is still very limited. The transdermal absorption from these formulations has been compared to that obtained with the use of new transdermal delivery vehicles, with the newer formulations proving to be promising. It was decided to entrap 5FU in a novel therapeutic system, in the form of the Pheroid™ system, to increase its transdermal penetration. Pheroid™ vesicles are stable spherical structures in a unique, emulsion-like formulation, and fall in the submicron range. The main components of the Pheroid™ system are the ethyl esters of the essential fatty acids linoleic acid and linolenic acid, as well as the cys-form of oleic acid, and water. The formulation is saturated with nitrous oxide (N20). Although Pheroid™ vesicles may resemble other lipid-based vehicles, such as liposomes and micro-emulsions, they are unique in the sense that they have inherent therapeutic qualities as well. The Pheroid™ formulation can be specifically manipulated to yield different types of vesicles, ensuring a fast transport rate, high entrapment efficiency, rapid delivery and stability of the delivery system for a specific drug. In this study, 5FU was entrapped in the Pheroid™ formulation. Transdermal permeation studies were then performed to evaluate the influence of this delivery system on the transdermal flux of 5FU. Vertical Franz diffusion cells were utilised to determine the transdermal penetration of 5FU. Only Caucasian female abdominal skin was used to minimise physiological variables. Diffusion studies were done over 12 hour periods, with the entire receptor phase being withdrawn at predetermined intervals. Samples were analysed using high performance liquid chromatography (HPLC), after which the cumulative concentration of active was plotted against time. The linear portion of this graph represents the flux of 5FU through the skin. It was found that there were differences in the results between formulations containing 5FU in a phosphate buffer solution (PBS)-based Pheroid™ and water-based Pheroid™, though the difference was not statistically significant. The 0.5 % 5FU in water-based Pheroid™ resulted in a significantly bigger yield than the control (1 % 5FU in water) as well as a significant difference to the 1 % 5FU in PBS-based Pheroid™ formulation. In general the water-based Pheroid™ formulations had greater average cumulative concentrations, yields and fluxes than the other formulations. The fluxes obtained with the water-based Pheroid™ formulations also correlated well with a previous study done by Kilian (2004). Thus it can be concluded that the Pheroid™ therapeutic delivery system enhances the transdermal penetration of 5FU. Water-based Pheroid™ formulations proved to be more effective than PBS-based Pheroid™ formulations. It can also be concluded that a 0.5 % 5FU in water-based Pheroid™ formulation can be used instead of a 1 % formulation, because there were no statistically significant differences between the two formulations. This would be advantageous - patient compliance can be enhanced because of a more tolerable formulation with fewer side effects, while manufacturing cost is lowered by using a lower concentration of active. It is recommended that some aspects of the study be investigated further to optimise the transdermal delivery of 5FU using the Pheroid™ therapeutic system. These aspects include optimising the composition of the Pheroid formulation, investigating the entrapment process of 5FU within Pheroid™ spheres, the influence of PBS and water as basis of the Pheroid™ formulation and the amount of 5FU remaining in the epidermis after the 12 hour period of the diffusion study. Keywords: 5-Fluorouracil, Franz diffusion cell, Heat separated epidermis, Skin penetration, Transdermal, Drug delivery system, Pheroid™ / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2008.

5-Fluorouracil

Franz diffusion cell

Heat separated epidermis

Skin penetration

Transdermal

Drug delivery system

PheroidTM

PheroidTM technology for the topical application of selected cosmeceutical actives / Lizelle Triféna Fox

Fox, Lizelle Triféna

January 2008

Aging can be described as an extremely complex occurrence from which no organism can be excluded. Intrinsic and extrinsic aging make out the two components of skin aging and they differ on the macromolecular level while sharing specific molecular characteristics which include elevated levels of reactive oxygen species (ROS) and matrix metalloproteinase (MMP) while collagen synthesis decreases. The skin functions as a protective barrier against the harsh environment and is essential for regulating body temperature. The stratum corneum (SC) is responsible for the main resistance to the penetration of most compounds; nevertheless the skin represents as an appropriate target for delivery. The target site for anti-aging treatment includes the epidermal and dermal layers of the skin. Calendula oil and L-carnitine L-tartrate was utilised as the cosmeceutical actives as they can be classified as a mixed category of compounds/products that lie between cosmetics and drugs. Both show excellent properties which can prove valuable during anti-aging treatment, whether it is due to the scavenging of ROS (calendula oil), moisturising effects (calendula oil and L-carnitine L-tartrate) or the improvement of the skin turnover rate (L-carnitine L-tartrate). The Pheroid™ delivery system can enhance the absorption of a selection of active ingredients. The aim of this study was to determine whether the Pheroid™ delivery system will enhance the flux and/or delivery of the named actives to the target site by performing Franz cell diffusion studies over an 8 h period, followed by tape stripping experiments. The Pheroid™ results of the actives were compared to the results obtained when 1 00 % calendula oil was applied and the L-carnitine L-tartrate was dissolved in phosphate buffer solution (PBS), respectively. In the case of calendula oil only a qualitative gas chromatography mass spectrometry (GC/MS) method could be employed. No calendula oil was observed to permeate through the skin, but linoleic acid (marker compound) was present in the epidermis and dermis layers. Components in the Pheroid™ delivery system hampered the results as the marker compound identified is a fundamental component of the Pheroid™, making it difficult to determine whether or not the Pheroid™ delivery system enhanced calendula oil's penetration. The aqueous solubility and log D partition coefficient of L-carnitine L-tartrate was determined. Inspection of the log D value of -1.35 indicated that the compound is unfavourable to penetrate the skin, whereas the aqueous solubility of 16.63 mg/ml in PBS at a temperature of 32º C indicated favourable penetration. During the Franz cell diffusion and tape stripping studies it was determined by liquid chromatography mass spectrometry (LC/MS) that carnitine may be inherent to human skin. Pheroid™ enhanced the flux (average of 0.0361 µg/cm2.h, median of 0.0393 µg/cm2.h) of the L-carnitine L-tartrate when compared to PBS (average of 0.0180 µg/cm2.h, median of 0.0142 µg/cm2.h ) for the time interval of 2 -8 h. The PBS was more effective in delivering the active to the target site (0.270 µg/ml in the epidermis and 2.403 µg/ml in the dermis) than Pheroid™ (0.111 µg/ml and 1.641 µg/ml in the epidermis and dermis respectively). Confocal laser scanning microscopy (CLSM) confirmed the entrapment of L-carnitine L-tartrate in the Pheroid™ vesicle, while in the case of calendula oil it was impossible to differentiate between the oil and the Pheroid™ components. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2009.

Calendula oil

L-carnitine L-tartrate

PheroidTM

Skin aging

Topical delivery

The impact of PheroidTM technology on the bioavailability and efficacy of anti-tuberculosis drugs in an animal model / L. Nieuwoudt

Nieuwoudt, Liezl-Marié

January 2009

Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2010.

Tuberculosis

Ethambutol

Pyrazinamide

Isonaizid

Rifampicin

PheroidTM

Bioavailability

Murine model

In vivo efficacy

In vivo efficacy