A comparative study of lamellar gel phase systems and emzaloids as transdermal drug delivery systems for acyclovir and methotrexate / Sonique Reynecke

Reynecke, Sonique

January 2004

The skin forms an attractive and accessible route for systemic delivery of drugs as alternative to other methods of administration, such as the oral and parental methods because of the problems associated with last mentioned methods. The lipophilic character of the stratum corneum, coupled with its intrinsic tortuosity, ensures that it almost always provides the principal barrier to the entry of drug molecules into the skin. Due to the fact that methotrexate (MTX) and acyclovir (ACV) have poor penetration properties through the skin, the aim of this study was to enhance the permeation of methotrexate and acyclovir with the use of two lamellar gel phase systems (LPGS) (Physiogel® NT and Physiogel® Dermaquadrille) and with Emzaloid® as transdermal drug delivery systems. Three different sets of experiments were done in this study: 1) the viscosity of the two Physiogel® creams was measured as an indication of stability and to determine whether the internal structure of the Physiogel® creams were affected by the investigated drugs; 2) the drug release rate from the three drug delivery vehicles was measured with a Vankel ® dissolution apparatus; 3) in vitro permeation studies were preformed using vertical Franz diffusion cells with human epidermal skin clamped between the donor and receptor compartments. The skin was hydrated with PBS buffer for one hour before 1% mixtures of the drugs in both the Physiogel® creams and Emzaloid® were applied to the donor chamber. Samples were taken at 2, 4, 6, 8, 10, 12 and 24 hours. It was then analysed by HPLC for methotrexate and acyclovir. The fluxes of drug permeation were determined. The viscosity measurements confirmed that the internal structure of the two Physiogel® creams was not influenced by the drugs. Acyclovir and methotrexate were both released from the delivery vehicles. There was an enhancement of acyclovir through the skin from one of the Physiogel® creams. The permeability of methotrexate in the presence of the two Physiogel® vehicles was not significantly enhanced. Emzaloid® as delivery vehicle increased the penetration of both drugs through the skin significantly. The lamellar gel phase system mimics the structure of the stratum corneum, but does not improve the drug permeation through the stratum corneum significantly. The utilisation of Emzaloid® as a drug delivery system could be advocated from these findings. As could be seen from the penetration profiles Emzaloid® was a superior delivery system for methotrexate and acyclovir compared to the lamellar gel phase systems. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2005.

Acyclovir

Methotrexate

Transdermal delivery

Permeation

Drug delivery vehicles

Emzaloid

Physiogel

Effect of Brij 97 in the presence and absence of carrageenan on the transdermal delivery of 5-Fluorouracil / Carli Neethling

Neethling, Catharina Elizabeth

January 2006

The skin is the largest and most easily accessible organ of the human body thus making it the ideal route for systemic drug delivery. The transdermal route of drug delivery offers several advantages compared to the traditional routes including elimination of first pass metabolism and higher patient compliance. However, many drugs are topically and systemically ineffective when applied onto the skin, due to their almost complete failure to penetrate the skin. The main limitation lies in the stratum corneum, the barrier of the skin, which prevent the drug from reaching the deeper skin strata. 5-Fluorouracil is a polar hydrophilic drug and is therefore not a good penetrant through skin. A popular technique to increase transdermal permeation is to use a penetration enhancer, which reversibly reduce the permeability barrier of the stratum corneum. The primary aim of this study was to determine the effect of Brij 97 in the presence and absence of carrageenan on the transdermal delivery of 5-fluorouracil. The formulations were identified by means of confocal laser scanning microscopy and measurement of the particle size. The zeta-potential was measured to determine whether the formulations were stable and the pH was measured to determine if the internal structures of the formulations were affected by the drug. The drug released from the formulations was measured with a VanKel dissolution apparatus. In vitro transdermal diffusion studies were performed using vertical Franz diffusion cells with human epidermal skin. Histopathological studies were carried out on human epidermis skin to determine if the surfactant, Brij 97, had any effect on the skin. Through confocal laser scanning microscopy and particle size measurements, the 4 and 8% Brij 97 formulations without carrageenan could be identified as emulsions while the 15 and 25% Brij 97 formulations without carrageenan could be identified as microemulsions. The 4, 8, 15 and 25% Brij 97 formulations containing carrageenan could be identified as gels. The results obtained from the zeta-potential analysis indicated that the 4 and 8% Brij 97 formulations without carrageenan and 4% Brij 97 formulation with carrageenan are the most electronegative and thus the most stable. The pH measurements confirmed that the internal structure of the formulations was not influenced by the drug. 5-Fluorouracil was released from the formulations. The 4 and 8% Brij 97 formulations without carrageenan had an enhancing effect on the penetration of 5-fluorouracil while the 4, 8, 15 and 25% Brij 97 formulations with carrageenan and the 15 and 25% Brij 97 formulations without carrageenan had an hindering effect on the penetration of 5-fluorouracil. Although carrageenan led to good adhesiveness of the formulation on the skin, it did not lead to the enhancement of the penetration of 5-fluorouracil through the skin. When histopathological studies were carried out on female human abdominal skin, Brij 97, the surfactant, was found to have no damaging effect on the skin structure. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2006.

5-Fluorouracil

Brij 97

Carrageenan

Transdermal delivery

Permeation

Stratum corneum

The transdermal delivery of arginine vasopressin with pheroid technology / Hanneri Coetzee

Coetzee, Hanneri

January 2007

The aim of this study was to investigate in vitro transdermal diffusion of a small peptide namely arginine vasopressin (AVP) with the aid of the novel PheroidTM drug delivery system. Generally, peptides seem unfit for transdermal permeation, but it was thought prudent to explore the suitability of this lipid-based system after success was achieved with entrapment of tuberculostatics, bacteria and viruses. Bestatin (a selective aminopeptidase inhibitor) was employed to circumvent any skin-related degradation of the active. Therefore, the effect of bestatin on the preservation of AVP during diffusion was investigated. Vertical Franz cell diffusion studies were conducted with female abdominal skin, with AVP at a concentration of 150 pglml in the donor phase and Hepes buffer as the receptor phase over a twelve-hour period. To prove entrapment of AVP within the lipid structures of the PheroidsTM, fluorescentlylabelled samples were monitored by means of confocal laser scanning microscopy (CLSM), which revealed definite entrapment. In vitro permeation profiles for AVP exhibited a biphasic character, with the majority of permeation occurring during the first two hours. The PheroidTM delivery system proved to be advantageous when applied as delivery medium. The inclusion of bestatin has an enhancing effect on permeation probably due to its protection of AVP. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2007.

Arginine vasopressin

Transdermal diffusion

Confocal microscopy

Pheroid

Delivery system

Bestatin

The effect of emulsifiers and penetration enhancers in emulsions on dermal and transdermal delivery / Anja Otto

Otto, Anja

January 2008

Thesis (Ph.D. (Pharmacy))--North-West University, Potchefstroom Campus, 2008.

Dermal delivery

Emulsifier

Emulsion

Penetration modifier

Transdermal delivery

Pheroid technology for the transdermal delivery of lidocaine and prilocaine / Lorraine Kruger

Kruger, Lorraine

January 2008

Local anaesthetics have been implemented extensively in the case of a variety of painful superficial procedures, venipuncture, skin graft harvesting, anal or genital pruritus, poison ivy rashes, postherpetic neuralgia and several other dermatoses. The dilemma with commercially available local acting anaesthetics is that it may take well up to an hour to produce an anaesthetic effect. Anaesthetics have to traverse the highly efficient barrier, the stratum corneum, in order to reach the intended target site which is the free nerve endings located in the dermis. The objective of this study was to compare the transdermal delivery of an eutectic combination of two ionisable amide types of local anaesthetics, lidocaine HCI and prilocaine HCI, delivered with the novel Pheroid™ technology to that of a commercially available product in order to establish whether the lag time could be significantly reduced. Several techniques of promoting the penetration of these anaesthetics have previously been employed, including occlusive dressing, entrapment in liposomes and miscelles, iontophoretic delivery and so forth. The Pheroid™ delivery system is novel technology that entails improved delivery of several active compounds. It is a submicron emulsion type formulation that possesses the ability to be transformed in morphology and size, thereby affording it tremendous flexibility. Since it primarily consists of unsaturated essential fatty acids, it is not seen as foreign to the body but rather as a skin-friendly carrier. Vertical Franz cell diffusion studies were performed over a 12 hour period using Caucasian female abdominal skin obtained, with the consent of the donor, from abdominoplastic surgery. Comparison was made between the commercial product EMLA® cream, the active local anaesthetics dissolved in phosphate buffered solution (PBS) and the active ingredients entrapped within Pheroid™ vesicles. Distinct entrapment could be ascertained visually by confocal laser scanning microscopy (CLSM). The amount of drug that traversed the epidermal membrane into the receptor phase was then assayed by high performance liquid chromatography (HPLC). The results obtained with the Pheroid™ vesicles revealed a biphasic character with rapid permeation during the first two hours, followed by a plateau between 3 to 12 hours. The initial dramatic increase in percentage yield and flux indicates that the Pheroid™ carrier enhances the transdermal delivery of the actives in order to accelerate the onset of action. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2009.

Transdermal delivery

Pheroid

Lidocaine hydrochloride

Prilocaine hydrochloride

Local anaesthesia

Formulation, in vitro release and transdermal diffusion of anti-inflammatory gel preparations containing diclofenac salts / by Heidi Steyn

Steyn, Heidi

January 2010

Most individuals are influenced by pain at some stage in their lives. It can either be of acute or chronic nature. An acute pain condition initiates and is treated within a time span of 12 weeks. Chronic pain can, however, take substantially longer to treat. Chronic pain may last up to 6 months after the original injury was sustained. The after effects of chronic pain can, however, take years to heal, but physical and emotional scars may even last much longer than the initial chronic ailment. In this study the skin was chosen as an area for delivery of non-steroidal anti-inflammatory drugs for the treatment of pain at the joint and muscle tissue regions. The stratum corneum (the topmost horny layer of the skin), however bars the effective movement of chemical substances across the skin as it forms part of the skin's function to protect the superficial tissue of the body against the external environment. It furthermore plays an important role in regulation of the movement of chemicals across the skin. Sweat pores and hair follicles can be utilised as pathways for the movement of chemical substances through the stratum corneum. Physical deformation ie, hydration of the top layer of the skin, may also enhance the movement of chemicals The non-steroidal anti-inflammatory drug, diclofenac, has been evaluated for transdermal diffusion. Three different diclofenac salts were evaluated, namely diclofenac diethylamine, diclofenac hydroxyethyl pyrrolidine and diclofenac sodium. These salts have the potential to relieve systemic pain conditions. Diclofenac salts, however, possess physicochemical characteristics that are unfavourable for transdermal diffusion. Pheroid™ delivery technology, as patented by the Northwest-University, was implemented as a method to enhance transdermal delivery of the diclofenac salts. During the study each of the diclofenac salts was formulated in a Pheroid™ and non-Pheroid™ formulation. All the formulations as well as corresponding retail products containing similar diclofenac salts were evaluated in order to determine which preparation had the most effective transdermal diffusion. High performance liquid chromatograhphy was implemented in order to determine the concentration of each salt in their various preparations. The Pheroid™ and non-Pheroid™ formulations were also compared to retail products currently available. An active ingredient flux was determined by means of Franz cell diffusion studies. Membrane diffusion studies were utilised in order to determine whether the active ingredients were effectively released from the formulated preparations and market products. Membrane diffusion studies determined that Arthruderm (the retail product containing diclofenac sodium) had the most potential to effectively release the active ingredient from the formulation (median flux 28.36 ± 0.26 ug/cm2.h"1). Franz cell diffusion studies showed no flux values for any of the evaluated preparations, including the retail products. Concentrations obtained within the epidermis and dermis were determined through tape stripping of these areas. The largest concentration of active ingredient within the epidermis was obtained from the studies done on Voltaren® (the retail product containing diclofenac diethylamine) which was 7.27 |ig/cm2.h"1 the largest value in the dermis was obtained from a non-Pheroid™ formulation containing diclofenac sodium (4.47 ug/ml). Confocal laser scanning microscopy was utilised and the micrographs where evaluated to ensure that the diclofenac salts were effectively entrapped in the Pheroid™ delivery system. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2010.

Transdermal delivery

Stability testing

PheroidTM formulations

Diclofenac salts

Formulation, in-vitro release and transdermal diffusion of alpha-lipoic acid / Tizane Snyman

Snyman, Tizane

January 2009

Acne is a common disease characterised by follicular hyperkeratinisation, bacterial hipercolonisation as well as immune reactions and inflammation. In acne, reactive oxygen species (ROS) may be released from the damaged follicular walls, which could cause the advancement of inflammation in the pathogenesis of the disease. The topical application of antioxidants is a promising approach to support the endogenous antioxidant defence and avoid oxidative injury that may lead to acne. The skin provides a painless and patient-friendly approach for systemic drug administration. Transdermal drug delivery not only improves patient compliance, but also avoids the first-pass effect. The major hurdle to penetration of matter through the skin is provided by an outward layer of the skin, the stratum corneurm (SC). Overcoming this barrier safely and reversibly is a fundamental problem in the field of transdermal drug delivery. Alpha-lipoic acid was utilised as the cosmeceutical active and can be classified in a mixed category of compounds that lie between cosmetics and drugs. Alpha-lipoic acid and its reduced form, dihydrolipoic acid, have been described as the "universal antioxidants" because of their capacity to quench a number of free radicals in both aqueous and lipid environments, their metal-chelating properties and ability to restore other antioxidants from their inactive form. The Pheriod™ system is a new manner of drug delivery aimed at overcoming the barrier function of the skin. It consists of vesicular structures, the sizes of which vary from 200-440 nm. These vesicles, prepared from customised essential fatty acids, were found to advance the efficacy of topically administered compounds. The aim of this study was to determine whether the Pheroid™ delivery system would enhance the transdermal delivery of formulations containing alpha-lipoic acid to the target site by performing Franz cell diffusion studies over a 12 hour period, followed by tape-stripping experiments. The results of the formulations containing Pheroid™ were compared to those of the formulations without Pheroid™. Experimental determination of transdermal flux of the alpha-lipoic acid formulations revealed that Pheroid™ improved the transdermal delivery of alpha-lipoic acid. The average flux of Pheroid™ cream from 0 to 2 hours wass 58.01 ± 6.63 ug/cm2.h. The average flux of Pheroid™ gel from 4 to 12 hours was 22.18 ± 3.33 ug/cm2.h. Tape-stripping experiments proved that the concentrations of alpha-lipoic acid in Pheroid™ cream and cream that remained in the epidermis after application to the skin were 569.10 ug/ml and 764.93 ug/ml respectively. The concentrations of alpha-lipoic acid in Pheroid gel and gel that diffused into the dermis were 23.62 ug/ml and 61.06 ug/ml respectively. Aqueous solubility and log D partition coefficient of alpha-lipoic acid were determined. Inspection of the log D value of -0.78 indicated that the compound was unfavourable to penetrate the skin, whereas the aqueous solubility of 8.602 mg/ml in PBS at a temperature of 32 °C indicated favourable penetration. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2010.

Alpha-lipoic acid

Acne

Transdermal diffusion

PheroidTM

Formulation

Formulation, in vitro release and transdermal diffusion of azelaic acid with topical niacinamide / J.M. Moolman

Moolman, Judith Margaretha

January 2010

Acne is a common skin disease that affects the follicular unit of the skin. Inflammatory- and noninflammatory forms of acne exist. The most affected areas on the body include the face, upper part of the chest and the back. These are the areas with the most sebaceous follicles. Acne occurs when hyperkeratinisation causes the cells of the hair follicle to shed too fast. These cells then block the follicle opening. Thus, sebum cannot pass through the hair follicle onto the skin. The human skin is composed of three layers, namely the epidermis, which acts as a waterproof layer and a barrier to infections; the dermis, which contains the skin appendages; and the subcutaneous fat layer. Skin acts as a protective layer against pathogens and damage to the body. It also provides a semi-impermeable barrier to prevent water loss. Azelaic acid and niacinamide are both currently used in the treatment of acne. Azelaic acid is a saturated dicarboxylic acid which is used to treat mild to moderate acne. It has antibacterial, keratolytic and comedolytic properties. Niacinamide, on the other hand, is the amide of nicotinic acid and is beneficial in the treatment of both papular and pustular acne. It has a demonstrated anti-inflammatory action and causes dose-dependent inhibition of sebocyte secretions. The Pheroid™ delivery system is a colloidal system that consists of even lipid-based submicron-and micron-sized structures that are very unique in nature. This technology is able to improve the absorption and/or efficacy of various active ingredients, as well as other compounds. In this study, a cream, Pheroid™ cream, a gel and a Pheroid™ gel were formulated, containing both azelaic acid and niacinamide. Stability tests were conducted on these formulations for six months, and it was established that none of the formulations were stable under the different storage conditions. Tests that were conducted during stability testing, as determined by the Medicines Control Council, included: assay, mass variation, appearance, viscosity, pH determination and confocal laser scanning microscopy (CLSM). Diffusion studies (12 hours long in total) with vertical Franz cells were conducted with Caucasian female skin obtained after abdominoplastic surgery. Tape-stripping followed in order to establish the epidermis and dermis concentrations of azelaic acid and niacinamide. Significant concentrations of both active ingredients were found in the epidermis and the dermis after 12 hours. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2010.

Azelaic acid

Niacinamide

Transdermal diffusion

Stability testing

PheroidTM

The effect of emulsifiers and penetration enhancers in emulsions on dermal and transdermal delivery / Anja Otto

Otto, Anja

January 2008

Thesis (Ph.D. (Pharmacy))--North-West University, Potchefstroom Campus, 2008.

Dermal delivery

Emulsifier

Emulsion

Penetration modifier

Transdermal delivery

Formulation, in vitro release and transdermal diffusion of anti-inflammatory gel preparations containing diclofenac salts / by Heidi Steyn

Steyn, Heidi

January 2010

Most individuals are influenced by pain at some stage in their lives. It can either be of acute or chronic nature. An acute pain condition initiates and is treated within a time span of 12 weeks. Chronic pain can, however, take substantially longer to treat. Chronic pain may last up to 6 months after the original injury was sustained. The after effects of chronic pain can, however, take years to heal, but physical and emotional scars may even last much longer than the initial chronic ailment. In this study the skin was chosen as an area for delivery of non-steroidal anti-inflammatory drugs for the treatment of pain at the joint and muscle tissue regions. The stratum corneum (the topmost horny layer of the skin), however bars the effective movement of chemical substances across the skin as it forms part of the skin's function to protect the superficial tissue of the body against the external environment. It furthermore plays an important role in regulation of the movement of chemicals across the skin. Sweat pores and hair follicles can be utilised as pathways for the movement of chemical substances through the stratum corneum. Physical deformation ie, hydration of the top layer of the skin, may also enhance the movement of chemicals The non-steroidal anti-inflammatory drug, diclofenac, has been evaluated for transdermal diffusion. Three different diclofenac salts were evaluated, namely diclofenac diethylamine, diclofenac hydroxyethyl pyrrolidine and diclofenac sodium. These salts have the potential to relieve systemic pain conditions. Diclofenac salts, however, possess physicochemical characteristics that are unfavourable for transdermal diffusion. Pheroid™ delivery technology, as patented by the Northwest-University, was implemented as a method to enhance transdermal delivery of the diclofenac salts. During the study each of the diclofenac salts was formulated in a Pheroid™ and non-Pheroid™ formulation. All the formulations as well as corresponding retail products containing similar diclofenac salts were evaluated in order to determine which preparation had the most effective transdermal diffusion. High performance liquid chromatograhphy was implemented in order to determine the concentration of each salt in their various preparations. The Pheroid™ and non-Pheroid™ formulations were also compared to retail products currently available. An active ingredient flux was determined by means of Franz cell diffusion studies. Membrane diffusion studies were utilised in order to determine whether the active ingredients were effectively released from the formulated preparations and market products. Membrane diffusion studies determined that Arthruderm (the retail product containing diclofenac sodium) had the most potential to effectively release the active ingredient from the formulation (median flux 28.36 ± 0.26 ug/cm2.h"1). Franz cell diffusion studies showed no flux values for any of the evaluated preparations, including the retail products. Concentrations obtained within the epidermis and dermis were determined through tape stripping of these areas. The largest concentration of active ingredient within the epidermis was obtained from the studies done on Voltaren® (the retail product containing diclofenac diethylamine) which was 7.27 |ig/cm2.h"1 the largest value in the dermis was obtained from a non-Pheroid™ formulation containing diclofenac sodium (4.47 ug/ml). Confocal laser scanning microscopy was utilised and the micrographs where evaluated to ensure that the diclofenac salts were effectively entrapped in the Pheroid™ delivery system. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2010.

Transdermal delivery

Stability testing

PheroidTM formulations

Diclofenac salts