Transdermal delivery of anticholinergic bronchodilators methodological and clinical aspects /

Bosman, Ingrid Jolanda.

January 1996

Proefschrift Rijksuniversiteit Groningen. / Datum laatste controle: 30-07-1996. Met lit.opg. en samenvatting in het Nederlands.

Subcutaneous insulin infusion in type 1 diabetes mellitus

Hoogma, Roeland Petrus Leonardus Maria.

January 1900

Proefschrift Universiteit van Amsterdam. / Met bibliogr., lit. opg. - Met samenvatting in het Nederlands.

Formulation, in vitro release and transdermal diffusion of diclofenac salts by implementation of the delivery gap principle / Hanri Smith

Smith, Hanri

January 2013

Nonsteroidal anti-inflammatory drugs (NSAIDs) are widely used in the treatment of inflammation and pain (Escribano et al., 2003:203). Diclofenac, a classical NSAID, is considerably more effective as an analgesic, antipyretic and anti-inflammatory drug than other traditional NSAIDs, like indomethacin and naproxen (Grosser et al., 2011:986). However, the use of diclofenac is known for its many side effects, such as gastric disorders, while fluid and sodium retention are also commonly observed (Rossiter, 2012:391). Since topical diclofenac offers a more favourable safety profile, it is a valuable substitute for oral NSAID therapy in the treatment of osteoarthritis (Roth & Fuller, 2011:166). The benefits of topically applied NSAIDs, compared to oral administration and systemic delivery, include the easy cessation of treatment, should effects become troublesome (Brown et al., 2006:177), the avoidance of extensive, first-pass metabolism (Cleary, 1993:19; Kornick, 2003:953; Prausnitz & Langer, 2008:1261; Lionberger & Brennan, 2010:225), reduced systemic side effects (Colin Long, 2002:41), convenience of application and improved patient compliance (Cleary, 1993:19; Prausnitz & Langer, 2008:1261). An approach that is often applied in optimising the solubility and dissolution rate of poorly water soluble, weak electrolytes is to prepare a salt of the active pharmaceutical ingredient (API) (Minghetti et al., 2007:815; O’Connor & Corrigan, 2001:281-282). Diclofenac is frequently administered as a salt, due to the high partition coefficient and very low water solubility of this molecule (Fini et al., 1999:164). Formulating for efficacy (FFETM) is a software programme designed by JW Solutions to facilitate the formulation of cosmetic ingredients or solvents into a product that would optimally deliver active ingredients into the skin. The notion is built upon solubility, i.e. solubility of the active ingredient in the formulation and solubility of the formulation in the skin. This programme could also be employed to optimise amounts of predetermined ingredients, to propose formulations that would ensure optimal drug delivery, to calculate the skin delivery gap (SDG) and to demonstrate transdermal permeation of active ingredients and excipients (JW Solutions Software, 2013a). When the SDG is known, it mathematically indicates the optimal active ingredient and topical delivery vehicle to use (JW Solutions, 2013b). In this study, diclofenac sodium (DNa), diclofenac diethylamine (DDEA) and diclofenac N-(2- hydroxyethyl) pyrrolidine (DHEP) were each formulated in the following emulgels: * An emulgel optimised towards the stratum corneum (SC) (enhancing drug delivery into this layer and deeper tissues) (oily phase ~30%), * A more hydrophilic emulgel (oily phase ~15%), and * A more lipophilic emulgel (oily phase ~45%). Components of the oily phase and its respective amounts, as well as the SDG of formulations were determined by utilising the FFETM software of JW Solutions (2013a). The aqueous solubilities of DNa, DDEA and DHEP were determined and their respective values were 11.4 mg/ml, 8.0 mg/ml and 11.9 mg/ml, all indicative of effortless percutaneous delivery (Naik et al., 2000:319). Log D (octanol-buffer distribution coefficient) (pH 7.4) determinations for DNa, DDEA and DHEP were performed and their values established at 1.270 (DNa), 1.291 (DDEA) and 1.285 (DHEP). According to these values, diclofenac, when topically applied as a salt in a suitable vehicle, should permeate transdermally without the aid of radical intervention (Naik et al., 2000:319; Walters, 2007:1312). Membrane release studies were also carried out in order to determine the rate of API release from these new formulations. Results confirmed that diclofenac was indeed released from all nine of the formulated emulgels. The more hydrophilic DNa formulation released the highest average percentage of diclofenac (8.38%) after 6 hours. Subsequent transdermal diffusion studies were performed to determine the diclofenac concentration that permeated the skin. The more hydrophilic DNa emulgel showed the highest average percentage skin diffusion (0.09%) after 12 hours, as well as the highest average flux (1.42 ± 0.20 μg/cm2.h). The concentrations of diclofenac in the SC-epidermis (SCE) and epidermis-dermis (ED) were determined through tape stripping experiments. The more lipophilic DNa emulgel demonstrated the highest average concentration (0.27 μg/ml) in the ED, while the DNa emulgel that had been optimised towards the SC, had the highest concentration in the SCE (0.77 μg/ml). / MSc (Pharmaceutics), North-West University, Potchefstroom Campus, 2014

Diclofenac

FFE TM

SDG

Formulation

Transdermal diffusion

Diklofenak

Formulering

Transdermale diffusie

Formulation, in vitro release and transdermal diffusion of diclofenac salts by implementation of the delivery gap principle / Hanri Smith

Smith, Hanri

January 2013

Nonsteroidal anti-inflammatory drugs (NSAIDs) are widely used in the treatment of inflammation and pain (Escribano et al., 2003:203). Diclofenac, a classical NSAID, is considerably more effective as an analgesic, antipyretic and anti-inflammatory drug than other traditional NSAIDs, like indomethacin and naproxen (Grosser et al., 2011:986). However, the use of diclofenac is known for its many side effects, such as gastric disorders, while fluid and sodium retention are also commonly observed (Rossiter, 2012:391). Since topical diclofenac offers a more favourable safety profile, it is a valuable substitute for oral NSAID therapy in the treatment of osteoarthritis (Roth & Fuller, 2011:166). The benefits of topically applied NSAIDs, compared to oral administration and systemic delivery, include the easy cessation of treatment, should effects become troublesome (Brown et al., 2006:177), the avoidance of extensive, first-pass metabolism (Cleary, 1993:19; Kornick, 2003:953; Prausnitz & Langer, 2008:1261; Lionberger & Brennan, 2010:225), reduced systemic side effects (Colin Long, 2002:41), convenience of application and improved patient compliance (Cleary, 1993:19; Prausnitz & Langer, 2008:1261). An approach that is often applied in optimising the solubility and dissolution rate of poorly water soluble, weak electrolytes is to prepare a salt of the active pharmaceutical ingredient (API) (Minghetti et al., 2007:815; O’Connor & Corrigan, 2001:281-282). Diclofenac is frequently administered as a salt, due to the high partition coefficient and very low water solubility of this molecule (Fini et al., 1999:164). Formulating for efficacy (FFETM) is a software programme designed by JW Solutions to facilitate the formulation of cosmetic ingredients or solvents into a product that would optimally deliver active ingredients into the skin. The notion is built upon solubility, i.e. solubility of the active ingredient in the formulation and solubility of the formulation in the skin. This programme could also be employed to optimise amounts of predetermined ingredients, to propose formulations that would ensure optimal drug delivery, to calculate the skin delivery gap (SDG) and to demonstrate transdermal permeation of active ingredients and excipients (JW Solutions Software, 2013a). When the SDG is known, it mathematically indicates the optimal active ingredient and topical delivery vehicle to use (JW Solutions, 2013b). In this study, diclofenac sodium (DNa), diclofenac diethylamine (DDEA) and diclofenac N-(2- hydroxyethyl) pyrrolidine (DHEP) were each formulated in the following emulgels: * An emulgel optimised towards the stratum corneum (SC) (enhancing drug delivery into this layer and deeper tissues) (oily phase ~30%), * A more hydrophilic emulgel (oily phase ~15%), and * A more lipophilic emulgel (oily phase ~45%). Components of the oily phase and its respective amounts, as well as the SDG of formulations were determined by utilising the FFETM software of JW Solutions (2013a). The aqueous solubilities of DNa, DDEA and DHEP were determined and their respective values were 11.4 mg/ml, 8.0 mg/ml and 11.9 mg/ml, all indicative of effortless percutaneous delivery (Naik et al., 2000:319). Log D (octanol-buffer distribution coefficient) (pH 7.4) determinations for DNa, DDEA and DHEP were performed and their values established at 1.270 (DNa), 1.291 (DDEA) and 1.285 (DHEP). According to these values, diclofenac, when topically applied as a salt in a suitable vehicle, should permeate transdermally without the aid of radical intervention (Naik et al., 2000:319; Walters, 2007:1312). Membrane release studies were also carried out in order to determine the rate of API release from these new formulations. Results confirmed that diclofenac was indeed released from all nine of the formulated emulgels. The more hydrophilic DNa formulation released the highest average percentage of diclofenac (8.38%) after 6 hours. Subsequent transdermal diffusion studies were performed to determine the diclofenac concentration that permeated the skin. The more hydrophilic DNa emulgel showed the highest average percentage skin diffusion (0.09%) after 12 hours, as well as the highest average flux (1.42 ± 0.20 μg/cm2.h). The concentrations of diclofenac in the SC-epidermis (SCE) and epidermis-dermis (ED) were determined through tape stripping experiments. The more lipophilic DNa emulgel demonstrated the highest average concentration (0.27 μg/ml) in the ED, while the DNa emulgel that had been optimised towards the SC, had the highest concentration in the SCE (0.77 μg/ml). / MSc (Pharmaceutics), North-West University, Potchefstroom Campus, 2014

Diclofenac

FFE TM

SDG

Formulation

Transdermal diffusion

Diklofenak

Formulering

Transdermale diffusie

Formulation and topical delivery of lidocaine and prilocaine with the use of Pheroid™ technology / Dirkie Cornelia Nell.

Nell, Dirkie Cornelia

January 2012

Local anaesthetics are used regularly in the medical world for a variety of different procedures. Topical anaesthetics are used largely in minor skin breaking procedures, laceration repair and minor surgical procedures such as laryngoscopy, oesophagoscopy or urethroscopy (Franchi et al., 2008:186e1). The topical means of application of a local anaesthetic is non-invasive and painless that results in a good patient acceptability profile (Little et al., 2008:102). An existing commercial topical anaesthetic product contains a eutectic mixture of the amide-type local anaesthetics lidocaine hydrochloride (HCl) and prilocaine hydrochloride (HCl). This commercial product takes up to an hour to produce an anaesthetic effect. This is considered as a disadvantage in the use of topical anaesthetics, an hour waiting time is not always ideal in certain medical circumstances (Wahlgren & Quiding, 2000:584). This study compared the lag times, transdermal and topical delivery of lidocaine HCl and prilocaine HCl from four different semi-solid formulations with the inclusion of a current commercial product. One of the formulated semi-solid formulations included Pheroid™ technology, a novel skin-friendly delivery system developed by the Unit for Drug Research and Development at the North-West University, Potchefstroom Campus, South Africa. The skin is the body’s first line of defence against noxious external stimuli. It is considered the largest organ in the body with an intensive and complex structure. It consists of five layers with the first outer layer, the stratum corneum, the most impermeable (Williams, 2003:1). The stratum corneum has excellent barrier function characteristics and is the cause for the time delay in the transdermal delivery of active pharmaceutical ingredients (API) (Barry, 2007:569). Local anaesthetics need to penetrate all the epidermal skin layers in order to reach their target site, the dermis. Skin appendages as well as blood vessels and skin nerve endings are located in the dermis. Local anaesthetics have to reach the free nerve endings in the dermis in order to cause a reversible block on these nerves for a local anaesthetic effect (Richards & McConachie, 1995:41). Penetration enhancement strategies for the transdermal delivery of lidocaine and prilocaine have been investigated and include methods like liposomal entrapment (Franz-Montan et al., 2010; Müller et al., 2004), micellisation (Scherlund et al., 2000), occlusive dressing (Astra Zeneca, 2006), heating techniques (Masud et al., 2010) and iontophoresis (Brounéus et al., 2000). The Pheroid™ delivery system has improved the transdermal delivery of several compounds with its enhanced entrapment capabilities. Pheroid™ consists mainly of unsaturated essential fatty-acids, non-harmful substances that are easily recognised by the body (Grobler et al., 2008:285). The morphology and size of Pheroid™ is easily manipulated because it is a submicron emulsion type formulation which provides it with a vast flexibility profile (Grobler et al., 2008:284). Vesicular entrapment was used to entrap lidocaine HCl and prilocaine HCl in the Pheroid™ and incorporated into an emulgel formulation. An emulgel without the inclusion of Pheroid™ was formulated for comparison with the Pheroid™ emulgel as well as with a hydrogel. Pheroid™ solution was prepared and compared to a phosphate buffer solution (PBS) without Pheroid™, both containing lidocaine HCl and prilocaine HCl as APIs. Franz cell type transdermal diffusion studies were performed on the four semi-solid formulations (emulgel, Pheroid™ emulgel, hydrogel and the commercial product) and two solutions (PBS and Pheroid™). The diffusion studies were performed over a 12 h period followed by the tape stripping of the skin after each diffusion study. Caucasian female abdominal skin was obtained with consent from the donors. The skin for the diffusion cells were prepared by using a Zimmer Dermatome®. PBS (pH 7.4) was prepared as the receptor phase of the diffusion studies. The receptor phase was extracted at certain pre-determined time intervals and analysed with high performance liquid chromatography (HPLC) to determine the amount of API that had traversed the skin. Stratum corneum-epidermis samples and epidermis-dermis samples were prepared and left over night at 4 °C and analysed the next day with HPLC. This was done to determine the amount of API that accumulated in the epidermis-dermis and the amount of API that were left on the outer skin layers (stratum corneum-epidermis). The results from the Franz cell diffusion studies indicated that the emulgel formulation without Pheroid™ shortened the lag time of lidocaine HCl and that the emulgel formulated with Pheroid™ shortened the lag time of prilocaine HCl, when compared to the commercial product. Pheroid™ did not enhance the flux of lidocaine HCl and prilocaine HCl into the skin. The hydrogel formulation demonstrated a high transdermal flux of prilocaine HCl due to the hydrating effect it had on the stratum corneum. The commercial product yielded high flux values for both APIs but it did not result in a high concentration of the APIs delivered to the epidermis-dermis. Pheroid™ technology did, however, enhance the epidermal-dermal delivery of lidocaine HCl and prilocaine HCl into the skin epidermis-dermis. The stability of the emulgel formulation, Pheroid™ emulgel formulation and the hydrogel formulation was examined over a 6 month period. The formulations were stored at 25 °C/60% RH, 30 °C/60% RH and 40 °C/75% RH. The API concentration, mass, pH, zeta potential, particle size, viscosity and visual appearance for each formulation at the different storage conditions were noted and compared at month 0, 1, 2, 3 and 6 to determine if the formulations remained stable for 6 months. The results obtained from the stability study demonstrated that none of the formulations were stable for 6 months. The emulgel remained stable for the first 3 months. At 6 months, large decreases in API concentration and pH occurred which could cause a loss of anaesthetic action in the formulations. The Pheroid™ emulgel formulation did not remain stable for 6 months. / Thesis (MSc (Pharmaceutics))--North-West University, Potchefstroom Campus, 2013.

Lidocaine HCl

prilocaine HCl

Pheroid™

transdermal

local anaesthesia

dermis

lidokaïenhidrochloried

prilokaïenhidrochloried

transdermale aflewering

lokale verdower

Formulation and topical delivery of lidocaine and prilocaine with the use of Pheroid™ technology / Dirkie Cornelia Nell.

Nell, Dirkie Cornelia

January 2012

Local anaesthetics are used regularly in the medical world for a variety of different procedures. Topical anaesthetics are used largely in minor skin breaking procedures, laceration repair and minor surgical procedures such as laryngoscopy, oesophagoscopy or urethroscopy (Franchi et al., 2008:186e1). The topical means of application of a local anaesthetic is non-invasive and painless that results in a good patient acceptability profile (Little et al., 2008:102). An existing commercial topical anaesthetic product contains a eutectic mixture of the amide-type local anaesthetics lidocaine hydrochloride (HCl) and prilocaine hydrochloride (HCl). This commercial product takes up to an hour to produce an anaesthetic effect. This is considered as a disadvantage in the use of topical anaesthetics, an hour waiting time is not always ideal in certain medical circumstances (Wahlgren & Quiding, 2000:584). This study compared the lag times, transdermal and topical delivery of lidocaine HCl and prilocaine HCl from four different semi-solid formulations with the inclusion of a current commercial product. One of the formulated semi-solid formulations included Pheroid™ technology, a novel skin-friendly delivery system developed by the Unit for Drug Research and Development at the North-West University, Potchefstroom Campus, South Africa. The skin is the body’s first line of defence against noxious external stimuli. It is considered the largest organ in the body with an intensive and complex structure. It consists of five layers with the first outer layer, the stratum corneum, the most impermeable (Williams, 2003:1). The stratum corneum has excellent barrier function characteristics and is the cause for the time delay in the transdermal delivery of active pharmaceutical ingredients (API) (Barry, 2007:569). Local anaesthetics need to penetrate all the epidermal skin layers in order to reach their target site, the dermis. Skin appendages as well as blood vessels and skin nerve endings are located in the dermis. Local anaesthetics have to reach the free nerve endings in the dermis in order to cause a reversible block on these nerves for a local anaesthetic effect (Richards & McConachie, 1995:41). Penetration enhancement strategies for the transdermal delivery of lidocaine and prilocaine have been investigated and include methods like liposomal entrapment (Franz-Montan et al., 2010; Müller et al., 2004), micellisation (Scherlund et al., 2000), occlusive dressing (Astra Zeneca, 2006), heating techniques (Masud et al., 2010) and iontophoresis (Brounéus et al., 2000). The Pheroid™ delivery system has improved the transdermal delivery of several compounds with its enhanced entrapment capabilities. Pheroid™ consists mainly of unsaturated essential fatty-acids, non-harmful substances that are easily recognised by the body (Grobler et al., 2008:285). The morphology and size of Pheroid™ is easily manipulated because it is a submicron emulsion type formulation which provides it with a vast flexibility profile (Grobler et al., 2008:284). Vesicular entrapment was used to entrap lidocaine HCl and prilocaine HCl in the Pheroid™ and incorporated into an emulgel formulation. An emulgel without the inclusion of Pheroid™ was formulated for comparison with the Pheroid™ emulgel as well as with a hydrogel. Pheroid™ solution was prepared and compared to a phosphate buffer solution (PBS) without Pheroid™, both containing lidocaine HCl and prilocaine HCl as APIs. Franz cell type transdermal diffusion studies were performed on the four semi-solid formulations (emulgel, Pheroid™ emulgel, hydrogel and the commercial product) and two solutions (PBS and Pheroid™). The diffusion studies were performed over a 12 h period followed by the tape stripping of the skin after each diffusion study. Caucasian female abdominal skin was obtained with consent from the donors. The skin for the diffusion cells were prepared by using a Zimmer Dermatome®. PBS (pH 7.4) was prepared as the receptor phase of the diffusion studies. The receptor phase was extracted at certain pre-determined time intervals and analysed with high performance liquid chromatography (HPLC) to determine the amount of API that had traversed the skin. Stratum corneum-epidermis samples and epidermis-dermis samples were prepared and left over night at 4 °C and analysed the next day with HPLC. This was done to determine the amount of API that accumulated in the epidermis-dermis and the amount of API that were left on the outer skin layers (stratum corneum-epidermis). The results from the Franz cell diffusion studies indicated that the emulgel formulation without Pheroid™ shortened the lag time of lidocaine HCl and that the emulgel formulated with Pheroid™ shortened the lag time of prilocaine HCl, when compared to the commercial product. Pheroid™ did not enhance the flux of lidocaine HCl and prilocaine HCl into the skin. The hydrogel formulation demonstrated a high transdermal flux of prilocaine HCl due to the hydrating effect it had on the stratum corneum. The commercial product yielded high flux values for both APIs but it did not result in a high concentration of the APIs delivered to the epidermis-dermis. Pheroid™ technology did, however, enhance the epidermal-dermal delivery of lidocaine HCl and prilocaine HCl into the skin epidermis-dermis. The stability of the emulgel formulation, Pheroid™ emulgel formulation and the hydrogel formulation was examined over a 6 month period. The formulations were stored at 25 °C/60% RH, 30 °C/60% RH and 40 °C/75% RH. The API concentration, mass, pH, zeta potential, particle size, viscosity and visual appearance for each formulation at the different storage conditions were noted and compared at month 0, 1, 2, 3 and 6 to determine if the formulations remained stable for 6 months. The results obtained from the stability study demonstrated that none of the formulations were stable for 6 months. The emulgel remained stable for the first 3 months. At 6 months, large decreases in API concentration and pH occurred which could cause a loss of anaesthetic action in the formulations. The Pheroid™ emulgel formulation did not remain stable for 6 months. / Thesis (MSc (Pharmaceutics))--North-West University, Potchefstroom Campus, 2013.

Lidocaine HCl

prilocaine HCl

Pheroid™

transdermal

local anaesthesia

dermis

lidokaïenhidrochloried

prilokaïenhidrochloried

transdermale aflewering

lokale verdower

Formulation, in vitro release and transdermal diffusion of Vitamin A and Zinc for the treatment of acne / Nadia Naudé

Naudé, Nadia

January 2010

Acne vulgaris is the single, most common disease that presents a significant challenge to dermatologists, due to its complexity, prevalence and range of clinical expressions. This condition can be found in 85% of teenage boys and 80% of girls (Gollnick, 2003:1580). Acne can cause serious psychological consequences (low self–esteem, social inhibition, depression, etc.), if left untreated, and should therefore be recognised as a serious disorder (Webster, 2001:15). The pathogenesis of acne is varied, with factors that include plugging of the follicle, accumulation of sebum, growth of Propionibacterium acnes (P. acnes), and inflammatory tissue responses (Wyatt et al., 2001:1809). Acne treatment focuses on the reduction of inflammatory and non–inflammatory acne lesions, and thus halts the scarring process (Railan & Alster, 2008:285). Non–inflammatory acne lesions can be expressed as open and closed comedones, whereas inflammatory lesions comprise of papules, pustules, nodules and cysts (Gollnick, 2003:1581). Acne treatment may be topical, or oral. Topical treatment is the most suitable first–line therapy for non–inflammatory comedones, or mildly inflammatory disease states, with the advantage of avoiding the possible systemic effects of oral medications (Federman & Kirsner, 2000:80). Topical retinoids were very successfully used for the treatment of acne in the 1980s. Their effectiveness in long–term therapies was limited though, due to local skin irritations that occurred in some individuals (Julie & Harper, 2004:S36). Vitamin A acetate presented a new approach in the treatment of acne, showing less side effects (Cheng & Depetris, 1998:7). In this study, vitamin A acetate and zinc acetate were formulated into semisolid, combination formulations for the possible treatment of acne. Whilst vitamin A controls the development of microcomedones, reduces existing comedones, diminishes sebum production and moderately reduces inflammation (Verschoore et al., 1993:107), zinc normalises hormone imbalances (Nutritional–supplements–health–guide.com, 2005:2) and normalises the secretion of sebum (Hostýnek & Maibach, 2002:35). Although the skin presents many advantages to the delivery of drugs, it unfortunately has some limitations. The biggest challenge in the transdermal delivery of drugs is to overcome the natural skin barrier. Its physicochemical properties are a good indication(s) of the transdermal behaviour of a drug. The ideal drug to be used in transdermal delivery would have sufficient lipophilic properties to partition into the stratum corneum, but it would also have sufficient hydrophilic properties to partition into the underlying layers of the skin (Kalia & Guy, 2001:159). Pheroid technology was also implemented during this study, in order to establish whether it would enhance penetration of the active ingredients across the skin. The Pheroid consists of vesicular structures that contain no phospholipids, nor cholesterol, but consists of the same essential fatty acids that are present in humans (Grobler et al., 2008:283). The aim of this study hence was to investigate the transdermal delivery of vitamin A acetate and zinc acetate, jointly formulated into four topical formulations for acne treatment. Vitamin A acetate (0.5%) and zinc acetate (1.2%) were formulated into a cream, Pheroid cream, emulgel and Pheroid emulgel. An existing commercial product, containing vitamin A acetate, was used to compare the results of the formulated products with. The transdermal, epidermal and dermal diffusion of the formulations were determined during a 6 h diffusion study, using Franz diffusion cells and tape stripping techniques. Experimental determination of the diffusion studies proved that vitamin A acetate did not penetrate through the skin. These results applied to both the formulations being developed during this study, as well as to the commercial product. Tape stripping studies were done to determine the concentration of drug present in the epidermis and dermis. The highest epidermal concentration of vitamin A acetate was obtained with the Pheroid emulgel (0.0045 ug/ml), whilst the emulgel formulation provided the highest vitamin A acetate concentration in the dermis (0.0029 ug/ml). Contrary, for the commercial product, the total concentration of vitamin A acetate in the epidermis was noticeably lower than for all the new formulations studied. Vitamin A acetate concentrations of the commercial product in the dermis were within the same concentration range as the newly developed formulations, with the exception of the emulgel that delivered approximately 31% more vitamin A acetate to the dermis, than the commercial product. Zinc acetate was able to diffuse through full thickness skin, although no flux values were obtained. To eliminate the possibility of endogenous zinc diffusion, placebo formulations (without zinc) were prepared for use as control samples during the skin diffusion investigation. The emulgel and Pheroid emulgel formulations were unable to deliver significant zinc acetate concentrations transdermally, although transdermal diffusion was attained from both the cream and Pheroid cream. Tape stripping experiments with placebo formulations relative to the formulated products revealed that zinc acetate concentrations in the epidermis and dermis were significantly higher when the placebo formulations were applied. However, the average zinc acetate concentration in the dermis, after application of the cream formulation, was significantly higher, compared to when the placebo cream was applied. It could therefore be concluded that no zinc acetate had diffused into the epidermis and dermis from the new formulations, except from the cream formulation. The zinc acetate concentration being measured in the epidermis thus rather represented the endogenous zinc acetate. The cream formulation, however, was probably able to deliver detectable zinc acetate concentrations to the epidermis. Stability of the formulated products was tested under a variety of environmental conditions to determine whether the functional qualities would remain within acceptable limits over a certain period of time. The formulated products were tested for a period of three months under storage conditions of 25°C/60% RH (relative humidity), 30°C/60% RH and 40°C/75% RH. Stability studies included stability indicating assay testing, the determination of rheology, pH, droplet size, zeta–potential, mass loss, morphology of the particles and physical assessment. The formulations were unstable over the three months stability test period. A change in viscosity, colour and concentration of the active ingredients were observed. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2011.

Vitamin A

Zinc

Acne

Transdermal diffusion

Formulation

PheroidTM

Vitamien A

Sink

Aknee

Transdermale diffusie

Formulering

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, in vitro release and transdermal diffusion of Vitamin A and Zinc for the treatment of acne / Nadia Naudé

Naudé, Nadia

January 2010

Acne vulgaris is the single, most common disease that presents a significant challenge to dermatologists, due to its complexity, prevalence and range of clinical expressions. This condition can be found in 85% of teenage boys and 80% of girls (Gollnick, 2003:1580). Acne can cause serious psychological consequences (low self–esteem, social inhibition, depression, etc.), if left untreated, and should therefore be recognised as a serious disorder (Webster, 2001:15). The pathogenesis of acne is varied, with factors that include plugging of the follicle, accumulation of sebum, growth of Propionibacterium acnes (P. acnes), and inflammatory tissue responses (Wyatt et al., 2001:1809). Acne treatment focuses on the reduction of inflammatory and non–inflammatory acne lesions, and thus halts the scarring process (Railan & Alster, 2008:285). Non–inflammatory acne lesions can be expressed as open and closed comedones, whereas inflammatory lesions comprise of papules, pustules, nodules and cysts (Gollnick, 2003:1581). Acne treatment may be topical, or oral. Topical treatment is the most suitable first–line therapy for non–inflammatory comedones, or mildly inflammatory disease states, with the advantage of avoiding the possible systemic effects of oral medications (Federman & Kirsner, 2000:80). Topical retinoids were very successfully used for the treatment of acne in the 1980s. Their effectiveness in long–term therapies was limited though, due to local skin irritations that occurred in some individuals (Julie & Harper, 2004:S36). Vitamin A acetate presented a new approach in the treatment of acne, showing less side effects (Cheng & Depetris, 1998:7). In this study, vitamin A acetate and zinc acetate were formulated into semisolid, combination formulations for the possible treatment of acne. Whilst vitamin A controls the development of microcomedones, reduces existing comedones, diminishes sebum production and moderately reduces inflammation (Verschoore et al., 1993:107), zinc normalises hormone imbalances (Nutritional–supplements–health–guide.com, 2005:2) and normalises the secretion of sebum (Hostýnek & Maibach, 2002:35). Although the skin presents many advantages to the delivery of drugs, it unfortunately has some limitations. The biggest challenge in the transdermal delivery of drugs is to overcome the natural skin barrier. Its physicochemical properties are a good indication(s) of the transdermal behaviour of a drug. The ideal drug to be used in transdermal delivery would have sufficient lipophilic properties to partition into the stratum corneum, but it would also have sufficient hydrophilic properties to partition into the underlying layers of the skin (Kalia & Guy, 2001:159). Pheroid technology was also implemented during this study, in order to establish whether it would enhance penetration of the active ingredients across the skin. The Pheroid consists of vesicular structures that contain no phospholipids, nor cholesterol, but consists of the same essential fatty acids that are present in humans (Grobler et al., 2008:283). The aim of this study hence was to investigate the transdermal delivery of vitamin A acetate and zinc acetate, jointly formulated into four topical formulations for acne treatment. Vitamin A acetate (0.5%) and zinc acetate (1.2%) were formulated into a cream, Pheroid cream, emulgel and Pheroid emulgel. An existing commercial product, containing vitamin A acetate, was used to compare the results of the formulated products with. The transdermal, epidermal and dermal diffusion of the formulations were determined during a 6 h diffusion study, using Franz diffusion cells and tape stripping techniques. Experimental determination of the diffusion studies proved that vitamin A acetate did not penetrate through the skin. These results applied to both the formulations being developed during this study, as well as to the commercial product. Tape stripping studies were done to determine the concentration of drug present in the epidermis and dermis. The highest epidermal concentration of vitamin A acetate was obtained with the Pheroid emulgel (0.0045 ug/ml), whilst the emulgel formulation provided the highest vitamin A acetate concentration in the dermis (0.0029 ug/ml). Contrary, for the commercial product, the total concentration of vitamin A acetate in the epidermis was noticeably lower than for all the new formulations studied. Vitamin A acetate concentrations of the commercial product in the dermis were within the same concentration range as the newly developed formulations, with the exception of the emulgel that delivered approximately 31% more vitamin A acetate to the dermis, than the commercial product. Zinc acetate was able to diffuse through full thickness skin, although no flux values were obtained. To eliminate the possibility of endogenous zinc diffusion, placebo formulations (without zinc) were prepared for use as control samples during the skin diffusion investigation. The emulgel and Pheroid emulgel formulations were unable to deliver significant zinc acetate concentrations transdermally, although transdermal diffusion was attained from both the cream and Pheroid cream. Tape stripping experiments with placebo formulations relative to the formulated products revealed that zinc acetate concentrations in the epidermis and dermis were significantly higher when the placebo formulations were applied. However, the average zinc acetate concentration in the dermis, after application of the cream formulation, was significantly higher, compared to when the placebo cream was applied. It could therefore be concluded that no zinc acetate had diffused into the epidermis and dermis from the new formulations, except from the cream formulation. The zinc acetate concentration being measured in the epidermis thus rather represented the endogenous zinc acetate. The cream formulation, however, was probably able to deliver detectable zinc acetate concentrations to the epidermis. Stability of the formulated products was tested under a variety of environmental conditions to determine whether the functional qualities would remain within acceptable limits over a certain period of time. The formulated products were tested for a period of three months under storage conditions of 25°C/60% RH (relative humidity), 30°C/60% RH and 40°C/75% RH. Stability studies included stability indicating assay testing, the determination of rheology, pH, droplet size, zeta–potential, mass loss, morphology of the particles and physical assessment. The formulations were unstable over the three months stability test period. A change in viscosity, colour and concentration of the active ingredients were observed. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2011.

Vitamin A

Zinc

Acne

Transdermal diffusion

Formulation

PheroidTM

Vitamien A

Sink

Aknee

Transdermale diffusie

Formulering

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