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

Intraperitoneal 5-Fluorouracil treatment of cancer - clinical and experimental studies

Öman, Mikael

January 2004

Background:Pancreas cancer is a most aggressive malignancy. More than 80% of patients diagnosed with pancreas cancer, exhibit such advanced disease, that curative surgery is impossible. Systemic chemotherapy prolongs survival to 5-9 months. High concentrations of chemotherapeutic agents in the abdominal cavity and in the lymphatics draining the area is achieved by intraperitoneal administration. Vasopressin decreases splanchnic blood flow, reducing the intraperitoneal uptake of drugs, thus raising the local and lymphatic dose intensity. Aim: The aim of the study was to investigate the feasibility and tumour response of intraperitoneal 5-Fluorouracil (5-FU) treatment in non-resectable pancreas cancer, using vasopressin to improve the pharmacokinetic profile. Further, to study the effect of vasopressin on peritoneal blood flow, altered by intraperitoneal 5-FU or the presence of peritoneal carcinomatosis. Methods: In the animal experiments, the 133Xe-clearance technique and as a comparison Laser doppler flow, were used to identify changes of peritoneal blood flow caused by vasopressin in unmanipulated animals and in animals with peritoneal carcinomatosis or animals given intraperitoneal 5-FU. In the clinical studies, 68 (39 women/29 men) patients, with a non-resectable ductal pancreas cancer and a Karnovsky Index ≥70 were included. Patients were treated with 750-1500 mg/m2 5-FU intraperitoneally through a Port-a-cath and Leucovorin 100 mg/m2 intravenously on two consecutive days every 21 days until progression. Seventeen patients, receiving 750 mg/m2 5-FU, were given concomitant vasopressin 0.1 IU/min during 180 minutes, alternatively day 1 or 2. Results: In the animal experiments, vasopressin 0.07 IU/kg/min significantly reduced the 133Xe-clearance. Intraperitoneal 5-FU decreased the basal peritoneal blood flow and abrogated the vasopressin effect for 1-2 days. The presence of peritoneal carcinomatosis did not influence the basal peritoneal blood flow, nor the reduction of peritoneal blood flow caused by vasopressin. In the clinical studies, the treatment with intraperitoneal 5-FU was well tolerated, with no WHO Grade 3 or 4 toxicity with doses up to 1250 mg/m2. Thirty patients achieved at least stable disease at three months. The median survival time was 8.0 (range 0.8-54.1) months. There was a significant reduction of 5-FU Cmax on day 2, but no significant reduction of AUC, when vasopressin was given. Conclusion: Peritoneal blood flow changes caused by vasopressin can be estimated with the 133Xe-clearance technique. Intraperitoneal 5-FU but not peritoneal carcinomatosis decreases the vasopressin induced 133Xe-clearance reduction, 1-2 days after administration. In patients with non-resectable pancreas cancer, intraperitoneal 5-FU up to 1250 mg/m2 for two days every third week can be given without WHO grade 3 and 4 toxicity. The treatment is well tolerated with few and minor side effects. Tumour responses were observed. Addition of vasopressin does not significantly enhance the pharmacokinetics of intraperitoneal 5-Flurorouracil, but adds toxicity.

Surgery

intraperitoneal

5-fluorouracil

pancreas cancer

vasopressin

Xenon-clearance

Kirurgi

Surgery

Kirurgi

A comparative study between two lamellar gel phase systems and Emzaloids as delivery vehicles for the transdermal delivery of 5-fluorouracil and idoxuridine / Dewald Kilian

Kilian, Dewald

January 2004

The distinctive architecture of the stratum corneum with its unique nature of an interstitial lipoidal environment plays the major role in regulating the barrier function of the skin. The major problem with the transdermal delivery of 5-fluorouracil or idoxuridine is the permeation of sufficient amounts to the deeper layers of the skin and into the systemic circulation. In an attempt to enhance the transdermal permeability of 5-fluorouracil and idoxuridine, the aim of this study was to evaluate two lamellar gel phase systems (Physiogel dermaquadrille® and Physiogel NT®) and Emzaloids® as transdermal delivery vehicles for the two actives. Lamellar gel phase systems (LGPS) and Emzaloids® are both novel drug delivery systems. The epidermis of female abdominal skin was used in vertically mounted Franz diffusion cell experiments. An average amount of 250 mg of the 1% m/m LGPS was applied to cover the entire diffusion area of 1,075 cm2 of the skin, which contained 2,5 mg of the active. Samples of the actives in Emzaloids® were prepared and applied in the same way. The control solutions of the actives in water were prepared so that 1 ml of the applied solution contained the same amount of drug that was applied to the experimental cells. The entire receptor phase of the cells was removed at 2,4,6, 8, 10, 12 and 24 hours and was replaced with fresh 37°C receptor phase. The amount of active in the receptor phase was determined by HPLC analysis. Graphs of the cumulative amount of the active that permeated the skin over the 24 hour period were drawn and the slope of the graphs represented the flux in µg/ml/h. The average flux values of six experimental cells and six control cells were compared. Entrapment of the actives in the Emzaloid® vesicles was confirmed with the use of confocal laser scanning microscopy. Results for the LGPS indicate an enhancement ratio in the order of 4,2 for 5-fluorouracil and 1,7 for idoxuridine when compared to the control cells. There were no viscosity changes in the LGPS samples containing 1% m/m of the active when compared with the blank LGPS samples, suggesting that no change in the internal structure of the LGPS occurred after the addition of the actives to it. There were also no significant changes in the pH of the samples. Entrapment of the actives in the Emzaloid® vesicles occurred readily. The Emzaloid® vehicle showed a lower rate of release for idoxuridine than the LGPS did during the VanKel dissolution experiments. This suggests that higher flux values would be obtained with the LGPS for idoxuridine than with the Emzaloid® formulation, since more drug was available for permeation through the skin. This was, however, not the case. The Emzaloid® formulation showed much higher flux values, showing that even with a smaller amount of active available to permeate the skin higher flux values were obtained. Enhancement ratios of 20,33 and 3,50 were achieved with the Emzaloid® formulation for 5-fluorouracil and idoxuridine respectively. The internal LGPS structure which mimics the skins lipid components remained unchanged after the addition of the actives. Greater success might be achieved with the LGPS for different model drugs, since the drugs' physicochemical properties play an important part in its permeation through the skin. The Emzaloid® formulation, which is closely related to liposomes and transfersomes, showed great potential for commercially marketable formulations for the drugs tested but further research on the formulation has to be done. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2005.

Lamellar gel phase systems5-Fluorouracil

Idoxuridine

Premeation

Transdermal deliver

Lamellar gel phase systems

Emzaloid

Elevated Fatty Acid Content in Muscle is Prevented by EPA and DHA in an Animal Model of Colorectal Cancer Receiving CPT-11 / 5-FU

Almasud, Alaa A

Unknown Date

No description available.

Essential Fatty Acids

EPA and DHA

Cachexia

Sarcopenia

Colorectal Cancer

irinotecan / 5-fluorouracil

Skeletal Muscle

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

A comparative study between two lamellar gel phase systems and Emzaloids as delivery vehicles for the transdermal delivery of 5-fluorouracil and idoxuridine / Dewald Kilian

Kilian, Dewald

January 2004

The distinctive architecture of the stratum corneum with its unique nature of an interstitial lipoidal environment plays the major role in regulating the barrier function of the skin. The major problem with the transdermal delivery of 5-fluorouracil or idoxuridine is the permeation of sufficient amounts to the deeper layers of the skin and into the systemic circulation. In an attempt to enhance the transdermal permeability of 5-fluorouracil and idoxuridine, the aim of this study was to evaluate two lamellar gel phase systems (Physiogel dermaquadrille® and Physiogel NT®) and Emzaloids® as transdermal delivery vehicles for the two actives. Lamellar gel phase systems (LGPS) and Emzaloids® are both novel drug delivery systems. The epidermis of female abdominal skin was used in vertically mounted Franz diffusion cell experiments. An average amount of 250 mg of the 1% m/m LGPS was applied to cover the entire diffusion area of 1,075 cm2 of the skin, which contained 2,5 mg of the active. Samples of the actives in Emzaloids® were prepared and applied in the same way. The control solutions of the actives in water were prepared so that 1 ml of the applied solution contained the same amount of drug that was applied to the experimental cells. The entire receptor phase of the cells was removed at 2,4,6, 8, 10, 12 and 24 hours and was replaced with fresh 37°C receptor phase. The amount of active in the receptor phase was determined by HPLC analysis. Graphs of the cumulative amount of the active that permeated the skin over the 24 hour period were drawn and the slope of the graphs represented the flux in µg/ml/h. The average flux values of six experimental cells and six control cells were compared. Entrapment of the actives in the Emzaloid® vesicles was confirmed with the use of confocal laser scanning microscopy. Results for the LGPS indicate an enhancement ratio in the order of 4,2 for 5-fluorouracil and 1,7 for idoxuridine when compared to the control cells. There were no viscosity changes in the LGPS samples containing 1% m/m of the active when compared with the blank LGPS samples, suggesting that no change in the internal structure of the LGPS occurred after the addition of the actives to it. There were also no significant changes in the pH of the samples. Entrapment of the actives in the Emzaloid® vesicles occurred readily. The Emzaloid® vehicle showed a lower rate of release for idoxuridine than the LGPS did during the VanKel dissolution experiments. This suggests that higher flux values would be obtained with the LGPS for idoxuridine than with the Emzaloid® formulation, since more drug was available for permeation through the skin. This was, however, not the case. The Emzaloid® formulation showed much higher flux values, showing that even with a smaller amount of active available to permeate the skin higher flux values were obtained. Enhancement ratios of 20,33 and 3,50 were achieved with the Emzaloid® formulation for 5-fluorouracil and idoxuridine respectively. The internal LGPS structure which mimics the skins lipid components remained unchanged after the addition of the actives. Greater success might be achieved with the LGPS for different model drugs, since the drugs' physicochemical properties play an important part in its permeation through the skin. The Emzaloid® formulation, which is closely related to liposomes and transfersomes, showed great potential for commercially marketable formulations for the drugs tested but further research on the formulation has to be done. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2005.

Lamellar gel phase systems5-Fluorouracil

Idoxuridine

Premeation

Transdermal deliver

Lamellar gel phase systems

Emzaloid

Formulation of 5–Fluorouracil for transdermal delivery / Vermaas M.

Vermaas, Monique

January 2010

Non–melanoma skin cancer (NMSC) is the most common human malignancy and it is estimated that over 1.3 million cases are diagnosed each year in the United States (Neville et al., 2007:462). There are three main types of NMSC, which include basal–cell carcinoma (BCC), squamous–cell carcinoma (SCC) and cutaneous malignant melanoma (CMM). Exposure to ultra–violet (UV) radiation plays a major role in the aetiology of these three skin cancer types (Franceschi et al., 1996:24). 5–Fluorouracil is an antineoplastic pyrimidine analogue that functions as an anti–metabolite. It interferes with DNA (deoxyribonucleic acid), and to a lesser extent, with RNA (ribonucleic acid) synthesis by blocking the methylation of deoxyuridylic acid into thymidylic acid. It is used in topical preparations for the treatment of actinic keratosis (AK) and NMSC. The cure rate with topical 5–fluorouracil is partly reflected by the degree of erythema, erosions, and eventual crusting which develop at the sites of treatment. This reaction often attains the best clinical response, but in turn, frustrates patients, which may lead to patient incompliance (McGillis & Fein, 2004:175). Due to the hydrophilic nature of 5–fluorouracil, the transdermal permeation through the lipophilic stratum corneum is very low and trivial (Singh et al., 2005:99). Transdermal drug delivery is the delivery of a chemical substance across the skin to reach the systemic circulation (Prausnitz et al., 2004:115). This unique drug transport mechanism suggests many advantages that include safety, patient compliance, user–friendliness, efficiency and non–invasiveness (Fang et al., 2004:241). The stratum corneum is a specialised structure that forms part of several anatomically distinct layers of the skin. Seeing that it is the outermost layer, it provides protection to the skin. It is known as the main barrier to percutaneous absorption of compounds, as well as water loss, through the skin (Bouwstra et al., 2003:4). This study focussed on the formulation of six different types of semisolid formulations, containing 0.5% 5–fluorouracil. The formulations included: a cream, Pheroid cream, emulgel, Pheroid emulgel, lotion and Pheroid lotion. Pheroid refers to a delivery system which was incorporated in the formulations in an attempt to enhance the penetration of 5–fluorouracil into the skin. This drug delivery system consists of unique and stable lipid–based submicronand micron–sized structures, formulated in an emulsion. The dispersed Pheroid structures largely comprise of natural essential fatty acids, which have an affinity for the cell membranes of the human body (Grobler et al., 2008:284–285). These formulations were manufactured in large quantities and stored at three different temperatures, each with their respective relative humidity (RH): 25 °C/60% RH, 30 °C/60% RH and 40 °C/70% RH, for a period of six months. Stability tests were conducted on each of these formulations on the day of manufacture (month 0), and then after 1, 2, 3 and 6 months. The tests included: determination of concentration of the analytes (assay) by means of high performance liquid chromatography (HPLC); determination of zeta–potential and droplet size; pH measurement; viscosity; mass loss determination; physical appearance; and particle size distribution. Franz cell skin diffusion tests were performed with these six 5–fluorouracil containing semisolid formulations (0.5%), as well as with a 0.5% Pheroid solution, 0.5% non–Pheroid solution. A 5.0% Pheroid solution and a 5.0% non–Pheroid solution were also prepared in order to compare the skin diffusion test results to a 5.0% commercially available ointment. The data of the 0.5% formulations and solutions, as well as the 5.0% solutions and commercial ointment, were statistically compared and those formulations (and solutions) that yielded the best results, with regard to % diffused, epidermis and dermis concentrations, were identified. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2011.

5-fluorouracil

Skin cancer

Transdermal delivery

Formulation

Stability

5-fluorourasiel

Velkanker

Transdermale aflewering

Formulering

Stabiliteit

Formulation of 5–Fluorouracil for transdermal delivery / Vermaas M.

Vermaas, Monique

January 2010

Non–melanoma skin cancer (NMSC) is the most common human malignancy and it is estimated that over 1.3 million cases are diagnosed each year in the United States (Neville et al., 2007:462). There are three main types of NMSC, which include basal–cell carcinoma (BCC), squamous–cell carcinoma (SCC) and cutaneous malignant melanoma (CMM). Exposure to ultra–violet (UV) radiation plays a major role in the aetiology of these three skin cancer types (Franceschi et al., 1996:24). 5–Fluorouracil is an antineoplastic pyrimidine analogue that functions as an anti–metabolite. It interferes with DNA (deoxyribonucleic acid), and to a lesser extent, with RNA (ribonucleic acid) synthesis by blocking the methylation of deoxyuridylic acid into thymidylic acid. It is used in topical preparations for the treatment of actinic keratosis (AK) and NMSC. The cure rate with topical 5–fluorouracil is partly reflected by the degree of erythema, erosions, and eventual crusting which develop at the sites of treatment. This reaction often attains the best clinical response, but in turn, frustrates patients, which may lead to patient incompliance (McGillis & Fein, 2004:175). Due to the hydrophilic nature of 5–fluorouracil, the transdermal permeation through the lipophilic stratum corneum is very low and trivial (Singh et al., 2005:99). Transdermal drug delivery is the delivery of a chemical substance across the skin to reach the systemic circulation (Prausnitz et al., 2004:115). This unique drug transport mechanism suggests many advantages that include safety, patient compliance, user–friendliness, efficiency and non–invasiveness (Fang et al., 2004:241). The stratum corneum is a specialised structure that forms part of several anatomically distinct layers of the skin. Seeing that it is the outermost layer, it provides protection to the skin. It is known as the main barrier to percutaneous absorption of compounds, as well as water loss, through the skin (Bouwstra et al., 2003:4). This study focussed on the formulation of six different types of semisolid formulations, containing 0.5% 5–fluorouracil. The formulations included: a cream, Pheroid cream, emulgel, Pheroid emulgel, lotion and Pheroid lotion. Pheroid refers to a delivery system which was incorporated in the formulations in an attempt to enhance the penetration of 5–fluorouracil into the skin. This drug delivery system consists of unique and stable lipid–based submicronand micron–sized structures, formulated in an emulsion. The dispersed Pheroid structures largely comprise of natural essential fatty acids, which have an affinity for the cell membranes of the human body (Grobler et al., 2008:284–285). These formulations were manufactured in large quantities and stored at three different temperatures, each with their respective relative humidity (RH): 25 °C/60% RH, 30 °C/60% RH and 40 °C/70% RH, for a period of six months. Stability tests were conducted on each of these formulations on the day of manufacture (month 0), and then after 1, 2, 3 and 6 months. The tests included: determination of concentration of the analytes (assay) by means of high performance liquid chromatography (HPLC); determination of zeta–potential and droplet size; pH measurement; viscosity; mass loss determination; physical appearance; and particle size distribution. Franz cell skin diffusion tests were performed with these six 5–fluorouracil containing semisolid formulations (0.5%), as well as with a 0.5% Pheroid solution, 0.5% non–Pheroid solution. A 5.0% Pheroid solution and a 5.0% non–Pheroid solution were also prepared in order to compare the skin diffusion test results to a 5.0% commercially available ointment. The data of the 0.5% formulations and solutions, as well as the 5.0% solutions and commercial ointment, were statistically compared and those formulations (and solutions) that yielded the best results, with regard to % diffused, epidermis and dermis concentrations, were identified. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2011.

5-fluorouracil

Skin cancer

Transdermal delivery

Formulation

Stability

5-fluorourasiel

Velkanker

Transdermale aflewering

Formulering

Stabiliteit

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

Studies of Intracellular Transport and Anticancer Drug Action by Functional Genomics in Yeast

Gustavsson, Marie

January 2008

This thesis describes the use of functional genomics screens in yeast to study anticancer drug action and intracellular transport. The yeast Saccharomyces cerevisiae provides a particularly useful model system for global drug screens, due to the availability of knockout mutants for all yeast genes. A complete collection of yeast deletion mutants was screened for sensitivity to monensin, a drug that affects intracellular transport. A total of 63 deletion mutants were recovered, and most of them were in genes involved in transport beyond the Golgi. Surprisingly, none of the V-ATPase subunits were identified. Further analysis showed that a V-ATPase mutant interacts synthetically with many of the monensin-sensitive mutants. This suggests that monensin may act by interfering with the maintenance of an acidic pH in the late secretory pathway. The second part of the thesis concerns identification of the underlying causes for susceptibility and resistance to the anticancer drug 5-fluorouracil (5-FU). In a functional genomics screen for 5-FU sensitivity, 138 mutants were identified. Mutants affecting tRNA modifications were particularly sensitive to 5-FU. The cytotoxic effect of 5-FU is strongly enhanced in these mutants at higher temperature, which suggests that tRNAs are destabilized in the presence of 5-FU. Consistent with this, higher temperatures also potentiate the effect of 5-FU on wild type yeast cells. In a plasmid screen, five genes were found to confer resistance to 5-FU when overexpressed. Two of these genes, CPA1 and CPA2 encode the two subunits of the arginine-specific carbamoyl-phosphate synthase. The three other genes, HMS1, YAE1 and YJL055W are partially dependent on CPA1 and CPA2 for their effects on 5-FU resistance. The specific incorporation of [14C]5-FU into tRNA is diminished in all overexpressor strains, which suggest that they may affect the pyrimidine biosynthetic pathway.

5-fluorouracil

tRNA modifications

Saccharomyces cerevisiae

carbamoyl phosphate synthase

V-ATPase

Functional genomics

Funktionsgenomik