The effect of Pheroid® technology on the bioavailability of artemisone in primates / Lizette Grobler

Grobler, Lizette

January 2014

Malaria is one the world’s most devastating diseases. Several classes of drugs are used to treat malaria. Artemisinin combination therapy is the first line treatment of uncomplicated malaria. The artemisinin derivative, artemisone in conjunction with the Pheroid® drug delivery system, is the focus of this thesis. The impact of the Pheroid® on the bioavailability of artemisone was evaluated in vervet monkeys. The resulting artemisone plasma levels were much lower (Cmax of 47 and 114 ng/mL for reference and Pheroid® test formulations respectively) than expected for the dosages administered (60 mg/kg). The Pheroid® improved the pharmacokinetic profile of artemisone in a clinically significant manner. The metabolism of artemisone was assessed in vitro by using human and monkey liver and intestinal microsomes, and recombinant CYP3A4 enzymes. The Pheroid® inhibits the microsomal metabolism of artemisone. In addition, there is a species difference in artemisone metabolism between man and monkey since the in vitro intrinsic clearance of the reference formulation with monkey liver microsomes is ~8 fold higher in the monkey liver microsomes compared to the human liver microsomes and the estimated in vivo hepatic clearance for the monkey is almost twofold higher than in humans. Artemisone has potent antimalarial activity. Its in vitro efficacy was approximately twofold higher than that of either artesunate or dihydroartemisinin when evaluated against P. falciparum W2, D6, 7G8, TM90-C2B, TM91-C235 and TM93-C1088 parasite strains. The Pheroid® drug delivery system did not improve or inhibit the in vitro efficacy of artemisone or DHA. Artemisone (reference and Pheroid® test formulations) and metabolite M1 abruptly arrested the growth of P. falciparum W2 parasites and induced the formation of dormant ring stages in a manner similar to that of DHA. Interaction of artemisone with the p-glycoprotein (p-gp) efflux transporter was investigated. Artemisone stimulates ATPase activity in a concentration-dependent manner, whereas the Pheroid® inhibited this p-gp ATPase activity. P-gp ATPase activity stimulation was fourfold greater in human than cynomolgus monkey MDR1 expressed insect cell membranes. Artemisone alone and artemisone entrapped in Pheroid® vesicles showed moderate apical to basolateral and high basolateral to apical permeability (Papp) across Caco-2 cells. The Papp efflux ratio of artemisone and artemisone entrapped in Pheroid® vesicles were both >5, and decreased to ~1 when the p-gp inhibitor, verapamil, was added. Therefore, artemisone is a substrate for mammalian p-gp. The cytotoxic properties of Pheroid® on Caco-2 cells were assessed and the pro-Pheroid® seems to be non-toxic at concentrations of 1.25%. Vervet monkey plasma caused antibody-mediated growth inhibition of P. falciparum. Heat inactivated or protein A treatment proved useful in the elimination of the growth-inhibitory activity of the drug-free plasma. Plasma samples containing artemisone could not be analysed by the ex-vivo bioassay method. The dual labelling ROS assay did not prove to be useful in the evaluation of ROS production by artemisone and the Pheroid® delivery system. In conclusion, entrapment of artemisone in the Pheroid® delivery system improves the pharmacokinetic properties of artemisone, but does not improve or inhibit its antimalarial efficacy in vitro. The Pheroid® inhibited both the microsomal metabolism of artemisone and P-gp ATPase activity and was shown to be non-toxic at clinically usable concentrations. / PhD (Pharmaceutics), North-West University, Potchefstroom Campus, 2014

Artemisone

Bioavailability

Clearance

Drug delivery

Efficacy

Malaria

Metabolism

Monkey

Pheroid®

Aap

Artemisoon

Biobeskikbaarheid

Effektiwiteit geneesmiddel aflewering

Metabolisme

Opruiming

The effect of Pheroid® technology on the bioavailability of artemisone in primates / Lizette Grobler

Grobler, Lizette

January 2014

Malaria is one the world’s most devastating diseases. Several classes of drugs are used to treat malaria. Artemisinin combination therapy is the first line treatment of uncomplicated malaria. The artemisinin derivative, artemisone in conjunction with the Pheroid® drug delivery system, is the focus of this thesis. The impact of the Pheroid® on the bioavailability of artemisone was evaluated in vervet monkeys. The resulting artemisone plasma levels were much lower (Cmax of 47 and 114 ng/mL for reference and Pheroid® test formulations respectively) than expected for the dosages administered (60 mg/kg). The Pheroid® improved the pharmacokinetic profile of artemisone in a clinically significant manner. The metabolism of artemisone was assessed in vitro by using human and monkey liver and intestinal microsomes, and recombinant CYP3A4 enzymes. The Pheroid® inhibits the microsomal metabolism of artemisone. In addition, there is a species difference in artemisone metabolism between man and monkey since the in vitro intrinsic clearance of the reference formulation with monkey liver microsomes is ~8 fold higher in the monkey liver microsomes compared to the human liver microsomes and the estimated in vivo hepatic clearance for the monkey is almost twofold higher than in humans. Artemisone has potent antimalarial activity. Its in vitro efficacy was approximately twofold higher than that of either artesunate or dihydroartemisinin when evaluated against P. falciparum W2, D6, 7G8, TM90-C2B, TM91-C235 and TM93-C1088 parasite strains. The Pheroid® drug delivery system did not improve or inhibit the in vitro efficacy of artemisone or DHA. Artemisone (reference and Pheroid® test formulations) and metabolite M1 abruptly arrested the growth of P. falciparum W2 parasites and induced the formation of dormant ring stages in a manner similar to that of DHA. Interaction of artemisone with the p-glycoprotein (p-gp) efflux transporter was investigated. Artemisone stimulates ATPase activity in a concentration-dependent manner, whereas the Pheroid® inhibited this p-gp ATPase activity. P-gp ATPase activity stimulation was fourfold greater in human than cynomolgus monkey MDR1 expressed insect cell membranes. Artemisone alone and artemisone entrapped in Pheroid® vesicles showed moderate apical to basolateral and high basolateral to apical permeability (Papp) across Caco-2 cells. The Papp efflux ratio of artemisone and artemisone entrapped in Pheroid® vesicles were both >5, and decreased to ~1 when the p-gp inhibitor, verapamil, was added. Therefore, artemisone is a substrate for mammalian p-gp. The cytotoxic properties of Pheroid® on Caco-2 cells were assessed and the pro-Pheroid® seems to be non-toxic at concentrations of 1.25%. Vervet monkey plasma caused antibody-mediated growth inhibition of P. falciparum. Heat inactivated or protein A treatment proved useful in the elimination of the growth-inhibitory activity of the drug-free plasma. Plasma samples containing artemisone could not be analysed by the ex-vivo bioassay method. The dual labelling ROS assay did not prove to be useful in the evaluation of ROS production by artemisone and the Pheroid® delivery system. In conclusion, entrapment of artemisone in the Pheroid® delivery system improves the pharmacokinetic properties of artemisone, but does not improve or inhibit its antimalarial efficacy in vitro. The Pheroid® inhibited both the microsomal metabolism of artemisone and P-gp ATPase activity and was shown to be non-toxic at clinically usable concentrations. / PhD (Pharmaceutics), North-West University, Potchefstroom Campus, 2014

Artemisone

Bioavailability

Clearance

Drug delivery

Efficacy

Malaria

Metabolism

Monkey

Pheroid®

Aap

Artemisoon

Biobeskikbaarheid

Effektiwiteit geneesmiddel aflewering

Metabolisme

Opruiming

Preparation and characterisation of pheroid vesicles / Charlene Ethel Uys

Uys, Charlene Ethel

January 2006

Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2007.

Pheroid

Emulsion stability

Particle size and size distribution

Zeta potential

Turbidity

pH

Current

Accelerated stability testing

Preparation and characterisation of pheroid vesicles / Charlene Ethel Uys

Uys, Charlene Ethel

January 2006

Pheroid is a patented system comprising of a unique submicron emulsion type formulation. Pheroid vesicles consist mainly of plant and essential fatty acids and can entrap, transport and deliver pharmacologically active compounds and other useful molecules. The aim of this study was to show that a modulation of components and parameters is necessary to obtain the optimum formula to be used in pharmaceutical preparations. Non-optimal or non-predictable stability properties of emulsions can be limiting for the applications of emulsions (Bjerregaard et al., 2001:23). Careful consideration was given to the apparatus used during the processing along with the ratios of the various components added to the formulation and the storage conditions of the Pheroid vesicles. A preliminary study was performed to optimize the most accurate processing parameters during emulsification. The effect of emulsification rate and time, the temperature of the aqueous phase, the number of days the water phase were gassed, the concentration of the surfactant, cremophor® RH 40, used and the concentration of Vitamin F Ethyl Ester CLR added to the oil phase of the o/w emulsion has been studied. Quantification of the mean particle size, zeta potential, turbidity, pH and current values were used to characterize the emulsions. The samples were characterised after 1, 2, 3, 7, 14, 21 and 28 days of storage. The emulsions were also characterised with confocal laser scanning microscopy (CLSM) to measure the number and size and size distribution of the vesicles. After determination of the processing variables influencing the emulsion stability an accelerated stability test was conducted on a final formula. In the present study, accelerated stability testing employing elevated temperatures and relative humidity were used with good accuracy to predict long-term stability of an o/w emulsion kept at both 5 and 25 OC with 60 % relative humidity and 40 OC with 75 % relative humidity. The results of the stability tests were presented in histograms of the physical properties 24 hours, 1 month, 2 months and 3 months after preparation of the emulsion. It was concluded that Pheroid vesicles demonstrate much potential as a drug delivery system. The high stability of this formula allows its use in a wide variety of applications in the pharmaceutical industry. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2007.

Pheroid

Emulsion stability

Particle size and size distribution

Zeta potential

Turbidity

pH

Current

Accelerated stability testing

Preparation and characterisation of pheroid vesicles / Charlene Ethel Uys

Uys, Charlene Ethel

January 2006

Pheroid is a patented system comprising of a unique submicron emulsion type formulation. Pheroid vesicles consist mainly of plant and essential fatty acids and can entrap, transport and deliver pharmacologically active compounds and other useful molecules. The aim of this study was to show that a modulation of components and parameters is necessary to obtain the optimum formula to be used in pharmaceutical preparations. Non-optimal or non-predictable stability properties of emulsions can be limiting for the applications of emulsions (Bjerregaard et al., 2001:23). Careful consideration was given to the apparatus used during the processing along with the ratios of the various components added to the formulation and the storage conditions of the Pheroid vesicles. A preliminary study was performed to optimize the most accurate processing parameters during emulsification. The effect of emulsification rate and time, the temperature of the aqueous phase, the number of days the water phase were gassed, the concentration of the surfactant, cremophor® RH 40, used and the concentration of Vitamin F Ethyl Ester CLR added to the oil phase of the o/w emulsion has been studied. Quantification of the mean particle size, zeta potential, turbidity, pH and current values were used to characterize the emulsions. The samples were characterised after 1, 2, 3, 7, 14, 21 and 28 days of storage. The emulsions were also characterised with confocal laser scanning microscopy (CLSM) to measure the number and size and size distribution of the vesicles. After determination of the processing variables influencing the emulsion stability an accelerated stability test was conducted on a final formula. In the present study, accelerated stability testing employing elevated temperatures and relative humidity were used with good accuracy to predict long-term stability of an o/w emulsion kept at both 5 and 25 OC with 60 % relative humidity and 40 OC with 75 % relative humidity. The results of the stability tests were presented in histograms of the physical properties 24 hours, 1 month, 2 months and 3 months after preparation of the emulsion. It was concluded that Pheroid vesicles demonstrate much potential as a drug delivery system. The high stability of this formula allows its use in a wide variety of applications in the pharmaceutical industry. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2007.

Pheroid

Emulsion stability

Particle size and size distribution

Zeta potential

Turbidity

pH

Current

Accelerated stability testing

Pheroid technology for the topical delivery of depigmenting agents transforming growth factor–ß1 and tumor necrosis factor–a / Berenice Campbell

Campbell, Berenice

January 2010

Pigmentation disorders occur in multiple conditions (Hakozaki et al., 2006:105). Although many modalities of treatments are available, none are completely satisfactory (Briganti et al., 2003:101). Two cytokines normally present in the skin, transforming growth factor–beta1 (TGF–81) and tumour necrosis factor–alpha (TNF–9), have been shown to inhibit melanin synthesis (Martinez–Esparza, 2001:972). The stratum corneum has been commonly accepted as the main barrier to percutaneous absorption. Many techniques have been applied to overcome this barrier properties and to enhance penetration with varying success (Pellet et al., 1997:92). The objective of this study was to investigate the topical delivery of the above mentioned peptide drugs with aid of the Pheroid drug delivery system. Pheroid technology is a delivery system that promotes the absorption and increases the efficacy of dermatological, biological and oral medicines in various pharmacological groups (Grobler et al., 2008:4). Pheroid entraps drugs with high efficiency and delivers them with remarkable speed to target sites (Grobler, 2004:4). In order to avoid degradation of these peptides, bestatin hydrochloride (an aminopeptidase inhibitor), was used (Lkhagvaa et al., 2008:386). Topical drug delivery was achieved by means of vertical Franz cell diffusion studies performed over a 6 and 12 h period. ELISA (enzyme linked immunosorbent assay) detection was used to detect cytokine concentrations. Entrapped cytokine solutions were monitored by confocal laser scanning microscopy (CLSM). Upon removal of donor and receptor compartments, skin discs were subjected to tape stripping in order to establish the amount of active present within the stratum corneum and epidermis as well as the remaining dermis (Pellet et al., 1997:92). When comparing the two studies with each other, it is evident that the diffused concentration values obtained with PBS (phosphate buffer solution, pH 7.4) was lower than that obtained with the Pheroid drug delivery system. Both cytokine concentrations were successfully delivered topically as a minimum of concentrations for both actives were detected. This positive result was confirmed as well by the amount of active detected in stratum corneum–epidermis and epidermis–dermis solutions. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2011.

Pigmentation

Topical delivery

Pheroid

Transforming growth factor-beta1

Tumour necrosis factor-alpha

Bestatin

Tape stripping

Pigmentasie

Topikale aflewering

Transformerende groei faktor-beta1

Tumor nekrosis faktor-alpha

Bestatien

Bandstroping

Pheroid technology for the topical delivery of depigmenting agents transforming growth factor–ß1 and tumor necrosis factor–a / Berenice Campbell

Campbell, Berenice

January 2010

Pigmentation disorders occur in multiple conditions (Hakozaki et al., 2006:105). Although many modalities of treatments are available, none are completely satisfactory (Briganti et al., 2003:101). Two cytokines normally present in the skin, transforming growth factor–beta1 (TGF–81) and tumour necrosis factor–alpha (TNF–9), have been shown to inhibit melanin synthesis (Martinez–Esparza, 2001:972). The stratum corneum has been commonly accepted as the main barrier to percutaneous absorption. Many techniques have been applied to overcome this barrier properties and to enhance penetration with varying success (Pellet et al., 1997:92). The objective of this study was to investigate the topical delivery of the above mentioned peptide drugs with aid of the Pheroid drug delivery system. Pheroid technology is a delivery system that promotes the absorption and increases the efficacy of dermatological, biological and oral medicines in various pharmacological groups (Grobler et al., 2008:4). Pheroid entraps drugs with high efficiency and delivers them with remarkable speed to target sites (Grobler, 2004:4). In order to avoid degradation of these peptides, bestatin hydrochloride (an aminopeptidase inhibitor), was used (Lkhagvaa et al., 2008:386). Topical drug delivery was achieved by means of vertical Franz cell diffusion studies performed over a 6 and 12 h period. ELISA (enzyme linked immunosorbent assay) detection was used to detect cytokine concentrations. Entrapped cytokine solutions were monitored by confocal laser scanning microscopy (CLSM). Upon removal of donor and receptor compartments, skin discs were subjected to tape stripping in order to establish the amount of active present within the stratum corneum and epidermis as well as the remaining dermis (Pellet et al., 1997:92). When comparing the two studies with each other, it is evident that the diffused concentration values obtained with PBS (phosphate buffer solution, pH 7.4) was lower than that obtained with the Pheroid drug delivery system. Both cytokine concentrations were successfully delivered topically as a minimum of concentrations for both actives were detected. This positive result was confirmed as well by the amount of active detected in stratum corneum–epidermis and epidermis–dermis solutions. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2011.

Pigmentation

Topical delivery

Pheroid

Transforming growth factor-beta1

Tumour necrosis factor-alpha

Bestatin

Tape stripping

Pigmentasie

Topikale aflewering

Transformerende groei faktor-beta1

Tumor nekrosis faktor-alpha

Bestatien

Bandstroping