The antioxidant properties of bufadienolides, analogous to the orbicusides of Cotyledon orbiculata L. var orbiculata (Haw.) DC / Janine Aucamp

Aucamp, Janine

January 2014

The use of traditional and natural medicines in primary healthcare or alternative therapy is on the increase. However, the safety and efficacy of these medicines have not yet been confirmed. Pharmacognosy, the study of the properties of drugs, potential drugs or drug substances of natural origin and the search for new drugs from natural resources, is therefore of extreme importance in today’s healthcare environment. Cotyledon orbiculata L. var. orbiculata (Haw.) DC., a succulent shrub that is widely distributed over the whole of southern Africa, is an example of a plant used in traditional medicine for its antiepileptic effects. Oxidative stress can either be the cause of, or be secondary to epilepsy pathogenesis. Lipid peroxidation causes the disruption of cell membranes which leads to cell destruction and, in the case of neurological disorders, neurodegeneration. Reactive species have also been found to influence neurotransmission by affecting neurotransmitter metabolism and functions. Reactive species can therefore be responsible for the development of convulsions. Conventional anti-epileptics have shown to exert neuroprotective effects but information or research regarding their ability to prevent epilepsy from becoming chronic does either not exist or is not promising. Antioxidants have potential in the treatment of epileptic seizures as well as the prevention of chronic epilepsy by preventing the effects that oxidative stress has on neurotransmitter metabolism and functions that cause alterations in neuronal excitability and seizure threshold, ultimately leading to epileptic foci. The aim of this study was to evaluate the potential of the bufadienolide orbicusides of C. orbiculata and analogues as anti-epileptic treatment through antioxidant activity. Initially the isolation of novel antioxidants from C. orbiculata leaf juice was attempted. The antioxidant activity of the concentrated juice and fractions resulting thereof were evaluated with two assays. The thiobarbituric acid (TBA) assay was used to measure the extent of lipid peroxidation and nitroblue tetrazolium (NBT) assay was used to measure superoxide scavenging activity in rat brain homogenate. The low concentrations of orbicusides prompted the determination of the activity of two commercial bufadienolides (bufalin and cinobufotalin) and two bufadienolide analogues, synthesised by the esterification of trans-androsterone and androstanolone, respectively, using coumalic acid, producing Compound 1 and Compound 2. The toxicity of the commercial bufadienolides and synthesised analogues were evaluated by using the MTT assay (a cell viability assay). C. orbiculata juice showed significant pro-oxidant activity in both assays. Bufalin showed significant pro-oxidant activity in the TBA assay. Cinobufotalin showed no significant activity. Compound 1 showed pro-oxidant activity in the TBA assay and Compound 2 showed slight antioxidant activity in the NBT assay. The commercial bufadienolides showed low cell viability, indicating significant toxicity. The synthesised analogues showed a significant reduction in toxicity (despite Compound 2 being moderately toxic) when compared to the toxicity of the commercial bufadienolides. The low concentrations of orbicusides in the plant material and the antioxidant assay results of the two commercial bufadienolides suggested that the orbicusides may not be involved in the antioxidant properties of C. orbiculata. However, the antioxidant activity of Compound 2 showed that altering the pyrone moiety of bufadienolides could possibly improve antioxidant activity. The reduced toxicity and slight antioxidant activity of the synthesised bufadienolide analogues motivates further investigation. / MSc (Pharmaceutical Chemistry), North-West University, Potchefstroom Campus, 2014

Cotyledon orbiculata

Orbicusides

Antioxidant

Anti-epileptic

Toxicity

Orbikosiede

Antioksidant

Anti-epilepties

Toksisiteit

The antioxidant properties of bufadienolides, analogous to the orbicusides of Cotyledon orbiculata L. var orbiculata (Haw.) DC / Janine Aucamp

Aucamp, Janine

January 2014

The use of traditional and natural medicines in primary healthcare or alternative therapy is on the increase. However, the safety and efficacy of these medicines have not yet been confirmed. Pharmacognosy, the study of the properties of drugs, potential drugs or drug substances of natural origin and the search for new drugs from natural resources, is therefore of extreme importance in today’s healthcare environment. Cotyledon orbiculata L. var. orbiculata (Haw.) DC., a succulent shrub that is widely distributed over the whole of southern Africa, is an example of a plant used in traditional medicine for its antiepileptic effects. Oxidative stress can either be the cause of, or be secondary to epilepsy pathogenesis. Lipid peroxidation causes the disruption of cell membranes which leads to cell destruction and, in the case of neurological disorders, neurodegeneration. Reactive species have also been found to influence neurotransmission by affecting neurotransmitter metabolism and functions. Reactive species can therefore be responsible for the development of convulsions. Conventional anti-epileptics have shown to exert neuroprotective effects but information or research regarding their ability to prevent epilepsy from becoming chronic does either not exist or is not promising. Antioxidants have potential in the treatment of epileptic seizures as well as the prevention of chronic epilepsy by preventing the effects that oxidative stress has on neurotransmitter metabolism and functions that cause alterations in neuronal excitability and seizure threshold, ultimately leading to epileptic foci. The aim of this study was to evaluate the potential of the bufadienolide orbicusides of C. orbiculata and analogues as anti-epileptic treatment through antioxidant activity. Initially the isolation of novel antioxidants from C. orbiculata leaf juice was attempted. The antioxidant activity of the concentrated juice and fractions resulting thereof were evaluated with two assays. The thiobarbituric acid (TBA) assay was used to measure the extent of lipid peroxidation and nitroblue tetrazolium (NBT) assay was used to measure superoxide scavenging activity in rat brain homogenate. The low concentrations of orbicusides prompted the determination of the activity of two commercial bufadienolides (bufalin and cinobufotalin) and two bufadienolide analogues, synthesised by the esterification of trans-androsterone and androstanolone, respectively, using coumalic acid, producing Compound 1 and Compound 2. The toxicity of the commercial bufadienolides and synthesised analogues were evaluated by using the MTT assay (a cell viability assay). C. orbiculata juice showed significant pro-oxidant activity in both assays. Bufalin showed significant pro-oxidant activity in the TBA assay. Cinobufotalin showed no significant activity. Compound 1 showed pro-oxidant activity in the TBA assay and Compound 2 showed slight antioxidant activity in the NBT assay. The commercial bufadienolides showed low cell viability, indicating significant toxicity. The synthesised analogues showed a significant reduction in toxicity (despite Compound 2 being moderately toxic) when compared to the toxicity of the commercial bufadienolides. The low concentrations of orbicusides in the plant material and the antioxidant assay results of the two commercial bufadienolides suggested that the orbicusides may not be involved in the antioxidant properties of C. orbiculata. However, the antioxidant activity of Compound 2 showed that altering the pyrone moiety of bufadienolides could possibly improve antioxidant activity. The reduced toxicity and slight antioxidant activity of the synthesised bufadienolide analogues motivates further investigation. / MSc (Pharmaceutical Chemistry), North-West University, Potchefstroom Campus, 2014

Cotyledon orbiculata

Orbicusides

Antioxidant

Anti-epileptic

Toxicity

Orbikosiede

Antioksidant

Anti-epilepties

Toksisiteit

The antioxidant properties of the methanol extract of Cotyledon orbiculata L. var orbiculata (Haw.) DC. Leaves / Wessel Cornelius Roux

Roux, Wessel Cornelius

January 1900

South Africa is a country of great diversity. Different climate zones and a host of different habitats make South Africa the perfect platform for rich floral diversity. This floral diversity lends itself to the study of natural products by discovering new natural drugs that can be used in the treatment of many illnesses. Studies into the antioxidant properties of plants that are used in traditional medicine are an important aspect of research to determine the rationale of the use of plants by traditional healers. Many neurodegenerative diseases, like epilepsy, Parkinson s and Alzheimer s diseases, are linked to oxidative stress. Antioxidants could play a major role as neuroprotective agents and could alter the progression of these diseases. Epilepsy is one of the world s most prevalent central nervous system disorders and affects more than seventy per one thousand children in South Africa. Most of these cases are people in rural areas of South Africa where communities rely on the use of traditional medicine. Cotyledon orbiculata L. var orbiculata (Haw.) DC. is widely used in traditional medicine to treat epilepsy and other central nervous system disorders. The need to screen these plants for activity and toxicity is very important to understand the complex mechanism of action in the treatment of patients. In this study the methanol extract and three different fractions of the methanol extract of Cotyledon orbiculata were used to test for antioxidant activity and toxicity towards neuroblastoma cells. The freeze dried leaves of Cotyledon orbiculata were extracted with methanol using a Soxhlet apparatus. The concentrated extracts were analysed using HPLC (high pressure liquid chromatography) and three major peaks were selected for isolation. Three assays were performed to assess the antioxidant activity and toxicity of the isolated compounds. The thiobarbituric acid assay (TBA) quantifies the extent of the inhibition of lipid peroxidation in rat brain homogenates by the isolated fractions. All of the samples were able to attenuate lipid peroxidation as seen from the results obtained from the TBA assay. The methanol extract showed the best attenuation of lipid peroxidation in the rat brain homogenate with fraction 1 and 2 showing greater attenuation of lipid peroxidation than fraction 3. The nitroblue tetrazolium assay (NBT) quantifies the ability of the fractions to scavenge superoxide radicals in a rat brain homogenate. All samples were able to scavenge superoxide radicals as indicated by the NBT assay. The methanol extract showed the best superoxide scavenging abilities in the assay whereas fraction 1 showed better scavenging abilities than fraction 2 and 3. The 3–(4,5–dimethylthiazol–2–yl)–2,5–diphenyltetrazolium bromide assay (MTT) indicates the toxicity of the fractions towards neuroblastoma cells. The methanol extract and fraction 2 in the highest concentration of 10 mg/ml were the only samples that showed toxicity towards neuroblastoma cells. The molecular structure of a compound from fraction 2 was determined by using nuclear magnetic resonance spectroscopy (NMR), infrared spectroscopy (IR), and mass spectroscopy (MS). This compound was identified as diethyl malate. Diethyl malate is an artefact that is generated in HPLC procedures in the presence of malic acid (which naturally occurs in the leaves of Cotyledon orbiculata) and ethanol. The methanol extract of Cotyledon orbiculata has high antioxidant activity and could be due to the presence of malic acid in the leaves of the plant. The rationale in the use of Cotyledon orbiculata in the treatment of epilepsy could not be determined due to the isolation of an artefact, diethyl malate, obtained from the fraction. Further research should include methods to prevent artefact formation and purification of the samples that are obtained. / Thesis (MSc (Pharmaceutical Chemistry))--North-West University, Potchefstroom Campus, 2012.

Cotyledon orbiculata

Methanol extract

HPLC

Antioxidants

Toxicity

Metanolekstrak

HDVC

Anti-oksidant

Toksisiteit

The antioxidant properties of the methanol extract of Cotyledon orbiculata L. var orbiculata (Haw.) DC. Leaves / Wessel Cornelius Roux

Roux, Wessel Cornelius

January 1900

South Africa is a country of great diversity. Different climate zones and a host of different habitats make South Africa the perfect platform for rich floral diversity. This floral diversity lends itself to the study of natural products by discovering new natural drugs that can be used in the treatment of many illnesses. Studies into the antioxidant properties of plants that are used in traditional medicine are an important aspect of research to determine the rationale of the use of plants by traditional healers. Many neurodegenerative diseases, like epilepsy, Parkinson s and Alzheimer s diseases, are linked to oxidative stress. Antioxidants could play a major role as neuroprotective agents and could alter the progression of these diseases. Epilepsy is one of the world s most prevalent central nervous system disorders and affects more than seventy per one thousand children in South Africa. Most of these cases are people in rural areas of South Africa where communities rely on the use of traditional medicine. Cotyledon orbiculata L. var orbiculata (Haw.) DC. is widely used in traditional medicine to treat epilepsy and other central nervous system disorders. The need to screen these plants for activity and toxicity is very important to understand the complex mechanism of action in the treatment of patients. In this study the methanol extract and three different fractions of the methanol extract of Cotyledon orbiculata were used to test for antioxidant activity and toxicity towards neuroblastoma cells. The freeze dried leaves of Cotyledon orbiculata were extracted with methanol using a Soxhlet apparatus. The concentrated extracts were analysed using HPLC (high pressure liquid chromatography) and three major peaks were selected for isolation. Three assays were performed to assess the antioxidant activity and toxicity of the isolated compounds. The thiobarbituric acid assay (TBA) quantifies the extent of the inhibition of lipid peroxidation in rat brain homogenates by the isolated fractions. All of the samples were able to attenuate lipid peroxidation as seen from the results obtained from the TBA assay. The methanol extract showed the best attenuation of lipid peroxidation in the rat brain homogenate with fraction 1 and 2 showing greater attenuation of lipid peroxidation than fraction 3. The nitroblue tetrazolium assay (NBT) quantifies the ability of the fractions to scavenge superoxide radicals in a rat brain homogenate. All samples were able to scavenge superoxide radicals as indicated by the NBT assay. The methanol extract showed the best superoxide scavenging abilities in the assay whereas fraction 1 showed better scavenging abilities than fraction 2 and 3. The 3–(4,5–dimethylthiazol–2–yl)–2,5–diphenyltetrazolium bromide assay (MTT) indicates the toxicity of the fractions towards neuroblastoma cells. The methanol extract and fraction 2 in the highest concentration of 10 mg/ml were the only samples that showed toxicity towards neuroblastoma cells. The molecular structure of a compound from fraction 2 was determined by using nuclear magnetic resonance spectroscopy (NMR), infrared spectroscopy (IR), and mass spectroscopy (MS). This compound was identified as diethyl malate. Diethyl malate is an artefact that is generated in HPLC procedures in the presence of malic acid (which naturally occurs in the leaves of Cotyledon orbiculata) and ethanol. The methanol extract of Cotyledon orbiculata has high antioxidant activity and could be due to the presence of malic acid in the leaves of the plant. The rationale in the use of Cotyledon orbiculata in the treatment of epilepsy could not be determined due to the isolation of an artefact, diethyl malate, obtained from the fraction. Further research should include methods to prevent artefact formation and purification of the samples that are obtained. / Thesis (MSc (Pharmaceutical Chemistry))--North-West University, Potchefstroom Campus, 2012.

Cotyledon orbiculata

Methanol extract

HPLC

Antioxidants

Toxicity

Metanolekstrak

HDVC

Anti-oksidant

Toksisiteit

Characterisation, toxicology and clinical effects of crocodile oil in skin products / by Telanie Venter.

Venter, Telanie

January 2012

Natural oils are regularly used in cosmetics and as treatment for numeral skin conditions (Nielsen, 2006:575). The natural products industry is a multibillion dollar industry and has grown tremendously over the past few years. Natural oils used in cosmetics contain a range of fatty acids which contribute to several valuable properties in cosmetic- and personal care products. Fatty acids are divided into saturated acids and unsaturated acids (Vermaak et al., 2011:920,922). Because of the popularity and wide diversity of skin care products, it is necessary to create products that will distinguish themselves from the rest of the commercial products. To include natural oils in skin care products is a new way to prevent skin ageing, as well as other dermatological conditions. In this study, a natural oil, namely crocodile oil was used. Crocodile oil is obtained from the fat of the Nile crocodile (Crocodylus niloticus). Crocodile oil has the same composition as human skin oil. It only differs with regard to the percentages of the ingredients present. Crocodile oil contains saturated and unsaturated fatty acids. Because of the similar composition as human skin oil, crocodile oil will rarely be allergenic when applied to human skin and therefore will be a very accepted and harmless product to use (Croc city, 2012). There are many claims of positive results when crocodile oil containing products have been used. It includes fading of freckles, treatment of acne and pimple marks, dark lines, wrinkles and laugh lines. It also includes vanishing of dark shadows, sun spots and other discolorations. It helps prevent discolorations from forming and makes the skin softer, brighter and more attractive. It also controls rashness and dryness (Croc city, 2012). Because of crocodile oil’s anti-ageing, anti-fungal and anti-bacterial effects claimed by crocodile oil suppliers, and due to the fact that little scientific data is available on crocodile oil, it was decided to investigate the claims. In this study, the aims and objectives were to use natural oil, namely crocodile oil, and investigate the fatty acid profile, anti-microbial and anti-fungal activity, anti-oxidant activity, toxicity studies, stability determination of crocodile oil lotion and clinical efficacy testing of the anti-ageing effects. To determine the fatty acid profile of crocodile oil, fatty acid methyl ester (FAME) analysis with gas chromatography were used. Identification of FAME peaks in the samples was made by comparing the relative retention times of FAME peaks from samples to those of reference standards. The composition of fatty acids in crocodile oil compared well to fatty acids found in human skin oil. Anti-microbial and anti-fungal tests were done by Envirocare Laboratories, North-West University, Potchefstroom. Staphylococcus aureus, Esterichia coli, Pseudomanas aeruginosa, Candida albicans, Brasiliensis, Propionibacterium acnes and Trichophyton rubrum cultures were used to determine the anti-microbial and anti-fungal activity of crocodile oil. Unfortunately no activity was observed. The anti-oxidant properties of crocodile oil and crocodile oil lotion were determined by using the most commonly used method for measuring Malondialdehyde (MDA) in biological samples, namely the thiobarbituric acid (TBA) test. This method is based on spectrophotometric quantification of the pink complex formed after reaction of MDA with two molecules of TBA. No anti-oxidant activity was observed in the oil or the lotion. Toxicity studies were performed by Dr. D. Goosen (BVSc Hons. Pret.) from Tswane University of Technology (Pretoria, South Africa). The studies showed that the lotion had no toxicity in the skin sensitisation, acute dermal toxicity and acute dermal irritation studies. To determine the stability of the crocodile oil lotion, the formulated products were store at 25 °C / 60% RH (relative humidity), 30 °C / 60% RH and 40 °C / 75% RH for 6 months in the original packaging as well as a glass container. The stability tests included pH, viscosity, visual appearance assessment, zeta-potential, droplet size and mass loss. The crocodile cream lotion was stable over the 6 months period in both containers. Clinical efficacy testing was performed at the CEL (Clinical Efficacy Laboratory) of the North-West University, Potchefstroom, South Africa. A short-term study over a period of 3 h was performed to investigate the hydrating effects of crocodile oil lotion. A long-term study over a period of 12 weeks was performed to examine the anti-ageing effects of crocodile oil lotion. An erythema study was also conducted to test the anti-erythema properties of crocodile oil lotion. Although the crocodile oil lotion as well as the placebo lotion showed an increase in skin hydration, there was no significant difference between the two treatments. Crocodile oil lotion also showed no anti-erythema properties. / Thesis (PhD (Pharmaceutics))--North-West University, Potchefstroom Campus, 2013.

Natural oils

crocodile oil

stability testing

anti-oxidant

clinical efficacy

toxicity testing

natuurlike olies

krokodil olie

stabiliteitstoetse

anti-oksidant

kliniese effektiwiteit

toksisiteit bepaling

Characterisation, toxicology and clinical effects of crocodile oil in skin products / by Telanie Venter.

Venter, Telanie

January 2012

Natural oils are regularly used in cosmetics and as treatment for numeral skin conditions (Nielsen, 2006:575). The natural products industry is a multibillion dollar industry and has grown tremendously over the past few years. Natural oils used in cosmetics contain a range of fatty acids which contribute to several valuable properties in cosmetic- and personal care products. Fatty acids are divided into saturated acids and unsaturated acids (Vermaak et al., 2011:920,922). Because of the popularity and wide diversity of skin care products, it is necessary to create products that will distinguish themselves from the rest of the commercial products. To include natural oils in skin care products is a new way to prevent skin ageing, as well as other dermatological conditions. In this study, a natural oil, namely crocodile oil was used. Crocodile oil is obtained from the fat of the Nile crocodile (Crocodylus niloticus). Crocodile oil has the same composition as human skin oil. It only differs with regard to the percentages of the ingredients present. Crocodile oil contains saturated and unsaturated fatty acids. Because of the similar composition as human skin oil, crocodile oil will rarely be allergenic when applied to human skin and therefore will be a very accepted and harmless product to use (Croc city, 2012). There are many claims of positive results when crocodile oil containing products have been used. It includes fading of freckles, treatment of acne and pimple marks, dark lines, wrinkles and laugh lines. It also includes vanishing of dark shadows, sun spots and other discolorations. It helps prevent discolorations from forming and makes the skin softer, brighter and more attractive. It also controls rashness and dryness (Croc city, 2012). Because of crocodile oil’s anti-ageing, anti-fungal and anti-bacterial effects claimed by crocodile oil suppliers, and due to the fact that little scientific data is available on crocodile oil, it was decided to investigate the claims. In this study, the aims and objectives were to use natural oil, namely crocodile oil, and investigate the fatty acid profile, anti-microbial and anti-fungal activity, anti-oxidant activity, toxicity studies, stability determination of crocodile oil lotion and clinical efficacy testing of the anti-ageing effects. To determine the fatty acid profile of crocodile oil, fatty acid methyl ester (FAME) analysis with gas chromatography were used. Identification of FAME peaks in the samples was made by comparing the relative retention times of FAME peaks from samples to those of reference standards. The composition of fatty acids in crocodile oil compared well to fatty acids found in human skin oil. Anti-microbial and anti-fungal tests were done by Envirocare Laboratories, North-West University, Potchefstroom. Staphylococcus aureus, Esterichia coli, Pseudomanas aeruginosa, Candida albicans, Brasiliensis, Propionibacterium acnes and Trichophyton rubrum cultures were used to determine the anti-microbial and anti-fungal activity of crocodile oil. Unfortunately no activity was observed. The anti-oxidant properties of crocodile oil and crocodile oil lotion were determined by using the most commonly used method for measuring Malondialdehyde (MDA) in biological samples, namely the thiobarbituric acid (TBA) test. This method is based on spectrophotometric quantification of the pink complex formed after reaction of MDA with two molecules of TBA. No anti-oxidant activity was observed in the oil or the lotion. Toxicity studies were performed by Dr. D. Goosen (BVSc Hons. Pret.) from Tswane University of Technology (Pretoria, South Africa). The studies showed that the lotion had no toxicity in the skin sensitisation, acute dermal toxicity and acute dermal irritation studies. To determine the stability of the crocodile oil lotion, the formulated products were store at 25 °C / 60% RH (relative humidity), 30 °C / 60% RH and 40 °C / 75% RH for 6 months in the original packaging as well as a glass container. The stability tests included pH, viscosity, visual appearance assessment, zeta-potential, droplet size and mass loss. The crocodile cream lotion was stable over the 6 months period in both containers. Clinical efficacy testing was performed at the CEL (Clinical Efficacy Laboratory) of the North-West University, Potchefstroom, South Africa. A short-term study over a period of 3 h was performed to investigate the hydrating effects of crocodile oil lotion. A long-term study over a period of 12 weeks was performed to examine the anti-ageing effects of crocodile oil lotion. An erythema study was also conducted to test the anti-erythema properties of crocodile oil lotion. Although the crocodile oil lotion as well as the placebo lotion showed an increase in skin hydration, there was no significant difference between the two treatments. Crocodile oil lotion also showed no anti-erythema properties. / Thesis (PhD (Pharmaceutics))--North-West University, Potchefstroom Campus, 2013.

Natural oils

crocodile oil

stability testing

anti-oxidant

clinical efficacy

toxicity testing

natuurlike olies

krokodil olie

stabiliteitstoetse

anti-oksidant

kliniese effektiwiteit

toksisiteit bepaling

Preparation, stability and in vitro evaluation of liposomes containing amodiaquine / Jacques C. Scholtz

Scholtz, Jacques Coenraad

January 2010

Malaria is a curable disease that claims nearly one million lives each year. Problems with the treatment of malaria arise as resistance spreads and new treatment options are becoming less effective. The need for new treatments are of the utmost importance. Liposomes combined with antimalarials are a new avenue for research as liposomes can increase the efficacy of drugs against pathogens, as well as decreasing toxicity. Amodiaquine is a drug with known toxicity issues, but has proven to be effective and is, therefore, a prime candidate to be incorporated into the liposomal drug delivery system. The aim of this study was to prepare, characterize and evaluate the toxicity of the liposomes with incorporated amodiaquine. The solubility of amodiaquine was determined and liposomes formulated with, and without, amodiaquine entrapped. Accelerated stability studies (at 5 'C, 25 'C with relative humidity of 60% and 40 'C with a relative humidity of 40%) were conducted during which the size, pH, morphology and the entrapment efficacy was determined. The toxicity was determined in vitro by analysing the levels of reactive oxidative species and lipid peroxidation caused by the formulations to erythrocytes infected with P. falciparum as well as uninfected erythrocytes with flow cytometry. The solubility study of amodiaquine in different pH buffers showed that amodiaquine was more soluble at lower pH values. Solubility in solution with pH 4.5 was 36.3359 ± 0.7904mg/ml when compared to the solubility at pH 6.8, which was 15.6052 ± 1.1126 mg/ml. A buffer with a pH of 6 was used to ensure adequate solubility and acceptable compatibility with cells. Liposomes with incorporated amodiaquine were formulated with entrapment efficacies starting at 29.038 ± 2.599% and increasing to 51.914 ± 1.683%. The accelerated stability studies showed the median sizes and span values remained constant for both liposome and amodiaquine incorporated liposomes at 5 'C. The higher temperatures, i.e. 25 'C and 40 'C, displayed increases in the median size, and decreases in the span for both formulations. The conclusion can, therefore, be made that both liposome and amodiaquine incorporated liposomes are stable at lower temperatures. The entrapment efficacy increased from initial values to nearly 100% during the course of the stability study. This was attributed to amodiaquine precipitating from the solution. The pH values of the liposomes and amodiaquine incorporated liposomes remained constant for each formulation; though the amodiaquine incorporated liposomes had a lower starting pH, the formulations are both thought to be stable in terms of the pH. Toxicity studies revealed low levels of reactive oxygen species as well as low levels of lipid peroxidation for both liposome and amodiaquine incorporated liposomes, on both erythrocyte and Plasmodium infected erythrocytes. From the toxicity studies it can be concluded that liposomes and amodiaquine incorporated liposomes are not toxic to erythrocytes and infected erythrocytes. It was concluded that liposomes incorporating amodiaquine could possibly be used as a treatment option for malaria. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2011.

Malaria

Liposomes

Amodiaquine

Plasmodium falciparum

Stability

Toxicity

Entrapment efficacy

Size determination

Reactive oxygen species

Lipid peroxidation

Liposome

Amodiakien

Stabiliteit

Toksisiteit

Inkorporerings effektiwiteit

Groottebepaling

Reaktiewe suurstof spesies

Lipied peroksidasie

Preparation, stability and in vitro evaluation of liposomes containing amodiaquine / Jacques C. Scholtz

Scholtz, Jacques Coenraad

January 2010

Malaria is a curable disease that claims nearly one million lives each year. Problems with the treatment of malaria arise as resistance spreads and new treatment options are becoming less effective. The need for new treatments are of the utmost importance. Liposomes combined with antimalarials are a new avenue for research as liposomes can increase the efficacy of drugs against pathogens, as well as decreasing toxicity. Amodiaquine is a drug with known toxicity issues, but has proven to be effective and is, therefore, a prime candidate to be incorporated into the liposomal drug delivery system. The aim of this study was to prepare, characterize and evaluate the toxicity of the liposomes with incorporated amodiaquine. The solubility of amodiaquine was determined and liposomes formulated with, and without, amodiaquine entrapped. Accelerated stability studies (at 5 'C, 25 'C with relative humidity of 60% and 40 'C with a relative humidity of 40%) were conducted during which the size, pH, morphology and the entrapment efficacy was determined. The toxicity was determined in vitro by analysing the levels of reactive oxidative species and lipid peroxidation caused by the formulations to erythrocytes infected with P. falciparum as well as uninfected erythrocytes with flow cytometry. The solubility study of amodiaquine in different pH buffers showed that amodiaquine was more soluble at lower pH values. Solubility in solution with pH 4.5 was 36.3359 ± 0.7904mg/ml when compared to the solubility at pH 6.8, which was 15.6052 ± 1.1126 mg/ml. A buffer with a pH of 6 was used to ensure adequate solubility and acceptable compatibility with cells. Liposomes with incorporated amodiaquine were formulated with entrapment efficacies starting at 29.038 ± 2.599% and increasing to 51.914 ± 1.683%. The accelerated stability studies showed the median sizes and span values remained constant for both liposome and amodiaquine incorporated liposomes at 5 'C. The higher temperatures, i.e. 25 'C and 40 'C, displayed increases in the median size, and decreases in the span for both formulations. The conclusion can, therefore, be made that both liposome and amodiaquine incorporated liposomes are stable at lower temperatures. The entrapment efficacy increased from initial values to nearly 100% during the course of the stability study. This was attributed to amodiaquine precipitating from the solution. The pH values of the liposomes and amodiaquine incorporated liposomes remained constant for each formulation; though the amodiaquine incorporated liposomes had a lower starting pH, the formulations are both thought to be stable in terms of the pH. Toxicity studies revealed low levels of reactive oxygen species as well as low levels of lipid peroxidation for both liposome and amodiaquine incorporated liposomes, on both erythrocyte and Plasmodium infected erythrocytes. From the toxicity studies it can be concluded that liposomes and amodiaquine incorporated liposomes are not toxic to erythrocytes and infected erythrocytes. It was concluded that liposomes incorporating amodiaquine could possibly be used as a treatment option for malaria. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2011.

Malaria

Liposomes

Amodiaquine

Plasmodium falciparum

Stability

Toxicity

Entrapment efficacy

Size determination

Reactive oxygen species

Lipid peroxidation

Liposome

Amodiakien

Stabiliteit

Toksisiteit

Inkorporerings effektiwiteit

Groottebepaling

Reaktiewe suurstof spesies

Lipied peroksidasie