Abstracts

INTRODUCTION

Psoriasis is a chronic multisystem inflammatory disorder with significant co-morbidities and also profound physical, emotional and social impacts on quality of life (Dvorakova, Markham, 2013DVORAKOVA, V.; MARKHAM, T. Psoriasis: current treatment options and recent advances. Prescriber, v.24, n.10, p.13-20, 2013.). It is clinically characterized by erythematous, sharply demarcated papules and rounded plaques, covered by silvery scale and epidermal hyper proliferation (Christophers, 2001CHRISTOPHERS, E. Psoriasis epidemiology and clinical spectrum. Clin. Exp. Dermatol., v.26, n.4, p.314-320, 2001.).

Dithranol (1,8-dihydroxy-9-anthrone, anthralin or cignolin) is an effective drug for the treatment of chronic stable plaque psoriasis and has been used to treat various psoriatic disorders for many years (Dvorakova, Markham, 2013DVORAKOVA, V.; MARKHAM, T. Psoriasis: current treatment options and recent advances. Prescriber, v.24, n.10, p.13-20, 2013.). Despite being effective and safe, its application is difficult and troublesome owing to its irritating, burning, staining and necrotizing effects on the normal as well as the diseased skin. Furthermore, this drug is highly lipophilic, poorly water soluble and unstable as it gets readily photo-oxidized (Mustakalio, 1981MUSTAKALIO, K.K. Irritation, staining and antipsoriatic activity of 10-acyl analogue of anthralin. Br. J. Dermatol., v.105, suppl.20, p.23-27, 1981.; Wang et al., 1987WANG, J.C.T.; PATEL, B.G.; EHMAN, C.W.; LOWE, N. The release and percutaneous permeation of anthralin products, using clinically involved and uninvolved psoriatic skin. J. Am. Acad. Dermatol., v.16, n.4, p.812-820, 1987.).

Dithranol oxidation is enhanced by day light, ultraviolet (UV) light, exposure to air and molecular oxygen and temperature increase (Mahrle, 1997MAHRLE, G. Dithranol. Clin. Dermatol., v.15, n.5, p.723-737, 1997.). This drug readily undergoes oxidation to a range of degradation products, including danthron and dithranol dimmer, which are thought to contribute to the undesired effects and are inactive or less active in terms of anti-psoriatic potency (Thoma, Holzmann, 1998THOMA, K.; HOLZMANN, C. Photostability of dithranol. Eur. J. Pharm. Biopharm., v.46, n.2, p.201-208, 1998.; Mahrle, 1997MAHRLE, G. Dithranol. Clin. Dermatol., v.15, n.5, p.723-737, 1997.). Dithranol has a yellow color, while its oxidation products are brown to black (Ashton, Andre, Lowe, 1983ALMEIDA, H.; AMARAL, M.H.; LOBÃO, P. Comparative study of sustained-release lipid microparticles and solid dispersions containing ibuprofen. Braz. J. Pharm. Sci., v.48, n.3, p.531-536, 2012.; Wiegrebe, Plumier, Mayer, 1985WIEGREBE, W.; PLUMIER, E.; MAYER, K.K. Experimental contribution to the dithranol-brown problems. Arch. Dermatol. Res., v.2277, n.2, p.153-155, 1985.). So, the color can be a good parameter to study the stability of new formulations.

The investigation of the influence of light on the stability of drugs has gained importance in recent years. For a variety of active substances, a considerable instability under the influence of light has been proved (Carlotti et al., 2009CARLOTTI, M.E.; SAPINO, S.; PEIRA, E.; GALLARATE, M.; UGAZIO, E. On the photodegradation of dithranol in different topical formulations: use of SLN to increase the stability of the drug. J. Dispersion Sci. Technol., v.30, n.10, p.1517-1524, 2009.). Although the semisolid topical formulations are protected by their packaging, light-induced degradation may occur during production or after application on the skin. As dithranol is very unstable, it seemed necessary to investigate its behavior under the influence of light and temperature (Thoma, Holzmann, 1998THOMA, K.; HOLZMANN, C. Photostability of dithranol. Eur. J. Pharm. Biopharm., v.46, n.2, p.201-208, 1998.).

Various authors have already studied novel carriers intended to stabilize dithranol, like solid lipid nanoparticles (SLN) prepared by pre-emulsion followed by ultrasonication (Gambhire, Bhalekar, Shrivastava, 2012GAMBHIRE, M.S.; BHALEKAR, M.R.; SHRIVASTAVA, B. Investigations in photostability of dithranol incorporated in solid lipid nanoparticles. Pharm. Chem. J., v.46, n.4, p.256-261, 2012.); phospholipid microemulsion (Raza et al., 2011RAZA, K.; NEGI, P.; TAKYAR, S.; SHUKLA, A.; AMARJI, B.; KATARE, O.P. Novel dithranol phospholipid microemulsion for topical application: development, characterization and percutaneous absorption studies. J. Microencapsul., v.28, n.3, p.190-199, 2011.); SLN prepared by solvent injection technique (Carlotti et al., 2009CARLOTTI, M.E.; SAPINO, S.; PEIRA, E.; GALLARATE, M.; UGAZIO, E. On the photodegradation of dithranol in different topical formulations: use of SLN to increase the stability of the drug. J. Dispersion Sci. Technol., v.30, n.10, p.1517-1524, 2009.) and liposomes (Mahrle et al., 1991MAHRLE, G.; BONNEKOH, B.; GHYEZY, M.; WIEGREBE, W. Stability of anthralin in liposomal phospholipids. Arch. Dermatol. Res., v.283, n.7, p.483-484, 1991.).

Solid dispersion (SD) is defined as the dispersion of one or more active ingredients in an inert hydrophilic carrier or matrix in a solid state, prepared by melting, using solvents or by a solvent-melting method (Chiou, Riegelman, 1971CHIOU, W.L.; RIEGELMAN, S. Pharmaceutical applications of solid dispersions. J. Pharm. Sci., v.60, n.9, p.1281-1302, 1971.). Although there is ample use of water soluble carriers with no intrinsic solubilizing properties such as high molecular weight polyethylene glycols (PEG) and polyvinylpyrrolidones (PVP), the use of lipid based carriers with solubilizing properties has also attracted much interest recently (Serajuddin, 1999SERAJUDDIN, A.T.M. Solid dispersions of poorly water-soluble drugs: early promises, subsequent problems and recent breakthroughs. J. Pharm. Sci., v.88, n.1, p.1058-1066, 1999.). This technique allows for reducing particle size to a nearly molecular level (Krishnamoorthy, Suchandrasen, Prasad, 2012KRISHNAMOORTHY, V.; SUCHANDRASEN; PRASAD, V.P.R. Physicochemical characterization and in vitro dissolution behavior of olanzapine-mannitol solid dispersions. Braz. J. Phar. Sci., v.48, n.2, p.243-255, 2012.). Several advantages of SD include the uniform and homogeneous distribution of small quantities of drug in the solid state, the stabilization of unstable drugs, the dispersion of liquid or gaseous compounds and the production of prolonged release systems (Almeida, Amaral, Lobão, 2012ALMEIDA, H.; AMARAL, M.H.; LOBÃO, P. Comparative study of sustained-release lipid microparticles and solid dispersions containing ibuprofen. Braz. J. Pharm. Sci., v.48, n.3, p.531-536, 2012.). The present study aims to develop solid lipid dispersions with dithranol and evaluates drug stability, through color evaluation. The stability of two different semisolid formulations that incorporate SD was evaluated. Since the properties of topical formulations have a major impact on patient compliance with treatment (Fouéré, Adjadj, Pawin, 2005FOUÉRÉ, S.; ADJADJ, L.; PAWIN, H. How patients experience psoriasis: results from a European survey. J. Eur. Acad. Dermatol. Venerol., v.19, suppl.3, p.2-6, 2005.; Brown, Rehmus, Kimball, 2006; Devaux et al., 2012DEVAUX, S.; CASTELA, A.; ARCHIER, E.; GALLINI, A.; JOLY, P.; MISERY, L.; ARACTINGI, S.; AUBIN, F.; BACHELEZ, H.; CRIBIER, B.; JULLIEN, D.; LE MAÎTRE, M.; RICHARD, M.A.; ORTONNE, J.P.; PAUL, C. Adherence to topical treatment in psoriasis: a systematic literature review. J. Eur. Acad. Dermatol. Venereol., v.26, suppl.3, p.61-67, 2012.), textural and rheological characterization of semisolid formulations were performed.

MATERIAL AND METHODS

Material

Dithranol (Lot. No. 04JP19, Roig Farma, Spain), stearic acid (Lot.No. L12020240-OF-5419A, Fagron, Spain), argan oil (Lot.No. 121111-P-4, Acofarma, Spain), glyceryl behenate (Compritol E ATO) (Lot. No. 108540, Gattefossé, France), sodium lauryl sulphate (Lot. No. 18622400, José M. Vaz Pereira, Portugal), cetyl alcohol (Lanette 16) (Lot. No. 5383040010, José M. Vaz Pereira, Portugal), white petrolatum (Lot. No. L12120119, Fagron, Spain), liquid paraffin (Lot. No. 122403-P-1, Acofarma, Spain), glycerin (Lot. No. 12A31-B11-268316, Fagron, Spain) and methylparaben (Nipagin M) (Lot. No. GB6A039548, José M. Vaz Pereira, Portugal).

Methods

Preparation of solid dispersions containing dithranol

SD at a 1:9 ratio of dithranol/excipient was prepared using the fusion method. This ratio was used to make certain that all dithranol dissolved in the excipient. Two different SDs were prepared, one of them using glyceryl behenate (SD C) as excipient and the other using a mixture of argan oil with stearic acid (1:8 ratio) as excipient (SD SA).

Excipient melting (variable temperature according to the melting point of the excipients) on a hot plate with stirring was used, followed by addition of dithranol to the excipient, and then cooled until solidified, when it was ground with pestle and mortar.

SDs with particle size less than 180 µm were incorporated in an oil-in-water (O/W) cream and in a hydrophobic ointment in a drug/dermatological base ratio of 1:10, using a mechanical stirrer. Additionally, the same formulations with 1% (w/w) of pure dithranol were prepared. The qualitative and quantitative composition of the different developed formulations is presented in Table I.

Preparation of O/W cream and hydrophobic ointment

O/W cream was prepared by heating the aqueous and oily phases at 60-70 °C. When the two phases were at the same temperature, the aqueous phase was slowly added to the oily phase, at a stirring speed of 500-600 rpm. Stirring was maintained until cooling.

Hydrophobic ointment was prepared by mechanical stirring of white petrolatum with liquid paraffin.

Textural analysis

The textural analysis was performed using a texturometer (Stable Micro Systems, TA-XT2i, UK) by carrying out a penetration test using a load cell of 5 kg, a cylindrical probe with 13 mm diameter (25 mm in the case of FD formulation), a penetration depth of 5 mm, a test speed of 3 mm/s and a trigger force of 0.049 N. After penetrating the sample, the probe returned to a position 50 mm above the platform surface. From the obtained graphic force versusdistance, the maximum force (firmness) and the negative area (adhesiveness) were calculated. All the measurements were performed in triplicate.

The spreadability was performed using the same test; a TTC spreadability probe, a penetration depth of 23 mm, a test speed of 3 mm/s and a post-test speed of 10.0 mm/s. In this test, the sample was placed into the female cone, avoiding the incorporation of air. The sample surface was leveled, the probe was placed at a defined position (25 mm) and the assay began with the male cone downward (23 mm penetration and 3 mm/s speed), which spread the sample between the surfaces of the two cones.

Rheological analysis

Rheological analysis was performed on a rotational viscometer HAAKE Viscotester 550 (Thermo Scientific, Germany), with a coaxial cylinder sensor SV-DIN. The flow behavior was studied by continuous shear investigations, which were performed in order to evaluate the shear stress (Pa) as a function of shear rate (s^-1). The study was started with a shear rate of 1 s^-1up to a maximum of 500 s^-1 and back to 1 s^-1, and the resulting shear stress was measured. To reduce the influence of temperature on the rheological behavior, a thermostatic water bath was used to accurately maintain the sample temperature (20 °C) during all experiments.

Color evaluation

Since dithranol is a very unstable drug and its degradation products confer a formulation change in color, the stability of solid dispersions and respective semisolid formulations were evaluated by color measurements.

The samples of each semisolid formulation and solid dispersion were maintained at different conditions, namely, light exposure (at room temperature), high temperature exposition (37 °C) (protected from light) and protected from light (at room temperature), for one month duration.

L*a*b* color space parameters were determined weekly for each sample stored at different conditions, using a Minolta CR-400 Chroma meter (Japan) and SpectraMagic^TM software. Using this device, the sample surface is illuminated by a pulsed xenon lamp and the light reflected is collected for a tristimulus color analysis at 450, 560 and 600 nm, using the L*a*b* color system. The L*a*b* system is very comprehensive with the L* parameter expressing color brightness (varying between 100 for a white surface and 0 for a black surface). The a* parameter represents changes along a red-green axis with changes from +60 for a red surface to -60 to a green surface. The b* parameter changes from +60 for yellow surface to -60 for a blue surface (Clarys et al., 2000CLARYS, P.; ALEWAETERS, K.; LAMBRECHT, R.; BAREL, A.O. Skin color measurements: comparison between three instruments: the chromameter(r), the dermaspectrometer(r) and the mexameter(r). Skin Res. Technol., v.6, n.4, p.230-238, 2000.; Zhou et al., 2011ZHOU, L.; VOGT, F.G.; OVERSTREET, P.-A.; DOUGHERTY, J.T.; CLAWSON, J.S.; KORD, A.S. A Systematic method development strategy for quantitative color measurement in drug substances, starting materials, and synthetic intermediates. J. Pharm. Innovation, v.6, n.4, p.217-231, 2011.). The surface measured is 8 mm in diameter. The Chroma meter is calibrated using a white calibration plate. For each sample, measurements were made in triplicate. Color difference (ΔE) is calculated using coordinate geometry according to the equation:

ΔE = [(ΔL*)² + Δa*)² + Δb*)²]^1/2 (1)

pH determination

The pH of semisolid formulations was determined weekly in triplicate in each sample stored at different conditions, using a Crison Basic 20 pH meter (Spain).

Statistical analysis

The data were statistically analyzed. A Student's t test was performed to understand if the differences were significant.

RESULTS AND DISCUSSION

Textural analysis

Figure 1 shows the results of firmness and adhesiveness of the different formulations.

The FD results of firmness and adhesiveness are not presented in the graphs because the textural analysis of this formulation was performed with another probe (25 mm), since this sample was more fluid than the other formulations. The results of firmness and adhesiveness for FD formulation were 0.124 ± 0.002 N and -0.716 ± 0.008 N• mm, respectively. Formulations based on hydrophobic ointment had higher firmness and adhesiveness values than O/W creams. Additionally, formulations containing SD showed higher firmness and adhesiveness values than the corresponding formulations with pure dithranol. Moreover, formulations with SD of glyceryl behenate (SD C) had a small increase in textural parameters compared to formulations with SD of stearic acid and argan oil (SD SA).

Figure 2 shows the values of spreadability for the semisolid formulations. The results were interpreted as the difficulty of spreading, as the smaller the maximum positive force, the easier the spreading (Savary, Grisel, Picard, 2013SAVARY, G.; GRISEL, M.; PICARD, C. Impact of emollients on the spreading properties of cosmetic products: A combined sensory and instrumental characterization. Colloids Surf. B Biointerfaces, v.102, n.1, p.371-378, 2013.). The formulation for which it was necessary to apply a smaller force to spread was the O/W cream FD, whereas, hydrophobic ointments HSA and HC required the greatest forces to spread.

Formulations with pure dithranol were easier to spread than formulations containing solid dispersions. However, there were not considerable differences between formulations with SD SA (FSA and FC) and with SD C (HSA and HC).

Rheological analysis

Figure 3 depicts the plots of the shear stress as a function of shear rate of the semisolid formulations.

The flow curves of the tested formulations revealed a non-Newtonian shear-thinning behavior, with yield value. The yield value, i.e. the stress above which the structure of the system is broken down, is greater in hydrophobic ointments HD, HSA and HC than in oil-in-water creams. These systems start flowing after achieving a yield value and the viscosity of the formulations decrease with increasing shear rate. As it was observed in the studies of Gilbert et al., the formulations with higher yield values showed higher values of viscosity and shear stress than the other formulations (Gilbert et al., 2013GILBERT, L.; PICARD, C.; SAVARY, G.; GRISEL, M. Rheological and textural characterization of cosmetic emulsions containing natural and synthetic polymers: relationships between both data. Colloids Surface A, v.421, n.20, p.150-163, 2013.). The rheograms of FSA and FC are not shown, because there was been a lack of uniformity in the obtained results.

Thixotropy, a reversible variation of viscosity with time, was observed in all formulations, demonstrated by the presence of hysteresis area between ascending and descending curves of the rheograms. This feature is desirable in topical formulations, since it could facilitate the application of the product on the skin surface (Silva et al., 2012SILVA, A.C.; AMARAL, M.H.; GONZÁLEZ-MIRA, E.; SANTOS, D.; FERREIRA, D. Solid Lipid Nanoparticles (SLN) - based hydrogels as potential carriers for oral transmucosal delivery of Risperidone: Preparation and characterization studies. Colloids Surf. B Biointerfaces, v.93, n.1, p.241-248, 2012.; Korhonen et al., 2001KORHONEN, M.; HELLEN, L.; HIRVONEN, J.; YLIRUUSI, J. Rheological properties of creams with four different surfactant combinations - effect of storage time and conditions. Int. J. Pharm., v.221, n.1-2, p.187-196, 2001.). Regarding the hysteresis area, this was greater in the case of formulations HD, HSA, HC and also FC.

The knowledge about mechanical properties of topical formulations, with special emphasis on rheology, is useful because the information can be used as a technological tool to predict their spreading capacity on the skin (Van de Kerkof et al., 2002).

In a study performed by Marty and co-workers, in which the rheological characterization of topical ointments used in psoriasis treatment were compared with the consumer acceptability, it was found that the formulation with optimal rheological characteristics (shear-thinning) is also preferred by psoriatic patients (Marty et al., 2005MARTY, J.P.; LAFFORGUE, C.; GROSSIORD, J.L.; SOTO, P. Rheological properties of three different vitamin D ointments and their clinical perception by patients with mild to moderate psoriasis. J. Eur. Acad. Dermatol., v.19, suppl.3, p.7-10, 2005.).

Color evaluation

The ΔE, determined according to equation 1, for samples at different times, stored under different conditions are shown in Table II.

A change or difference in color corresponding to a value of ΔE>1.5 can be perceived by the human eye (Stark et al., 1996STARK, G.; FAWCETT, J.P.; TUCKER, I.G.; WEATHERALL, I.L. Instrumental evaluation of color of solid dosage forms during stability testing. Int. J. Pharm., v.143, n.1, p.93-100, 1996.). The significant differences observed were correlated with the ΔE greater than 1.5. With the exception of SD SA, all samples presented values of ΔE greater than 1.5 and showed an increase of this parameter over time. All formulations with pure dithranol showed greater ΔE values than semisolid formulations with SD containing dithranol. Considering the different SD, in general, SD SA and formulations with SD SA showed more stability than SD C and formulations containing this SD. In the majority of cases, the values of ΔE obtained each week for SD SA and their semisolid formulations were lower than the results of ΔE values of SD C and their formulations, with the exception of HSA at 37 °C.

Comparing O/W cream with hydrophobic ointment, it can be concluded that the latter conferred more stability since the ΔE values were lower than those obtained with the emulsified dermatological base. This can be due to the presence of water in the cream. Even when color change correlates with drug decomposition, this does not necessarily imply a causal relationship. Indeed color may arise due to decomposition of excipients or due to interaction between drug and excipients (Stark et al., 1996STARK, G.; FAWCETT, J.P.; TUCKER, I.G.; WEATHERALL, I.L. Instrumental evaluation of color of solid dosage forms during stability testing. Int. J. Pharm., v.143, n.1, p.93-100, 1996.).

Thoma and Holzmann investigated the photostability of dithranol 0.1% (w/w) in various solvents and excipients and have shown that in macrogol 400 (hydrophilic excipient), the drug is already unstable without irradiation and the influence of light plays only a minor role for the degradation reaction. However, in a paraffin base, that offers high stability for dithranol under the exclusion of light, a distinct instability exists under the influence of light (Thoma, Holzmann, 1998THOMA, K.; HOLZMANN, C. Photostability of dithranol. Eur. J. Pharm. Biopharm., v.46, n.2, p.201-208, 1998.).

It is possible to observe that in some cases (FC, HSA and HD) the temperature affects the ΔE values more so than the light. Previous results obtained by other authors demonstrate that various formulations containing dithranol were more stable at refrigerated conditions (5 ± 3 °C) than the same formulations stored at 45 ± 2 °C (Raza et al., 2011RAZA, K.; NEGI, P.; TAKYAR, S.; SHUKLA, A.; AMARJI, B.; KATARE, O.P. Novel dithranol phospholipid microemulsion for topical application: development, characterization and percutaneous absorption studies. J. Microencapsul., v.28, n.3, p.190-199, 2011.).

There was a correlation between color and time for FD (dark/room temperature) and FSA (dark/room temperature) where linear regressions of ΔE versus time (weeks) were: y = 9.75x + 0.06; R² = 0.99 and y = 4.13x - 0.1; R² = 0.99; respectively.

Considering CIEL*a*b* color space parameters, it is possible to conclude that dithranol degradation corresponds to a significant increase in a* value and a decrease in L* and b* parameters. The formulation where this observation was more pronounced was FD, which gained a brown color with time.

Rhee et al., have observed that the change in color value in a formulation of rabeprazole as measured by the total difference ΔE showed an exponential relationship with drug degradation products, which suggested that color changes could be detected before chemical degradation amassed to a noticeable extent (Rhee et al., 2008RHEE, Y.S.; PARK, C.W.; SHIN, Y.S.; KAM, S.H.; LEE, K.Y.; PARK, E.S. Application of instrumental evaluation of color for the pre-formulation and formulation of rabeprazole. Int. J. Pharm., v.350, n.1-2, p.122-129, 2008.).

pH determination of O/W formulations

Table III shows the pH values of each semisolid formulation.

The formulation containing SD SA (FSA) showed lower pH variations than the other formulations, which suffered significant pH variations with time. The formulations FD, FSA and FC stored at 37 °C during four weeks suffered the highest pH variation. The pH of FSA (dark/room temperature) and FSA (light/room temperature) remained more stable than the formulations with pure dithranol and SD C. Since the dermatological base is the same, we can presume that the observed differences are due to the fact that preparations contain pure dithranol or SD, instead of eventual alterations in the O/W cream constituents. Some authors have already related pH changes during storage with chemical stability. Dragicevic-Curic et al. developed liposomal hydrogels and the pH value and drug content was determined after their preparation and at predetermined time intervals during 6 months of storage at 4 and 23 °C. The drug content and pH values did not show remarkable changes during the storage of gels, which indicate chemical stability during storage at both temperatures (Dragicevic-Curic et al., 2010DRAGICEVIC-CURIC, N.; WINTER, S.; KRAJISNIK, D.; STUPAR, M.; MILIC, J.; GRAEFE, S.; FAHR, A. Stability evaluation of temoporfin-loaded liposomal gels for topical application. J. Liposome Res., v.20, n.1, p.38-48, 2010.).

CONCLUSIONS

It was possible to conclude that SD increases the stability of dithranol, and that an SD of stearic acid with argan oil (SD SA) achieves this purpose better than an SD of glyceryl behenate (SD C). However, the dermatological base also influences the stability, and the anhydrous formulations (hydrophobic ointment) showed the best results compared to the formulations containing water in their composition. In the future it will be important to optimize the dermatological base for SD incorporation, for example, with the addition of an antioxidant to obtain a completely stable system, suitable for skin application of dithranol.

REFERENCES

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