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. 2015 Jun 16;26(4):278–e61. doi: 10.1111/vde.12220

A pilot study of the efficacy of wipes containing chlorhexidine 0.3%, climbazole 0.5% and Tris-EDTA to reduce Malassezia pachydermatis populations on canine skin

Paola Cavana *, Andrea Peano , Jean-Yanique Petit , Paolo Tizzani , Sébastien Perrot , Emmanuel Bensignor §, Jacques Guillot *
PMCID: PMC4660877  PMID: 26083147

Abstract

Background

Wipes containing chlorhexidine and azole derivates have been recommended for veterinary use. No study has been published about their activity against Malassezia pachydermatis.

Hypothesis/Objectives

To evaluate the in vivo and in vitro activity of wipes soaked in a chlorhexidine, climbazole and Tris-EDTA solution against Malassezia pachydermatis.

Animals

Five research colony shar-pei dogs.

Methods

Wipes were applied once daily onto the left axilla, left groin and perianal area (protocol A), and twice daily on the right axilla, right groin and umbilical region (protocol B) for 3 days. In vivo activity was evaluated by quantifying Malassezia colonies through contact plates on the selected body areas before and after wipe application. The activity of the solution in which the wipes were soaked was assessed in vitro by contact tests following the European Standard UNI EN 1275 guidelines.

Results

Samples collected after wipe application showed a significant and rapid reduction of Malassezia yeast CFU. No significant difference in the Malassezia reduction was found between protocols A and B. In vitro assay showed 100% activity against Malassezia yeasts after a 15 min contact time with the wipe solution.

Conclusions and clinical importance

Wipes containing chlorhexidine, climbazole and Tris-EDTA substantially reduced the M. pachydermatis population on the skin of dogs. The results, although this was an uncontrolled study performed on a small number of dogs, suggest that these wipes may be useful for topical therapy of Malassezia dermatitis involving the lips, paws, perianal area and skin folds.

Résumé

Contexte

Des lingettes contenant de la chlorhexidine et des dérivésazolés ont été recommandés en médicine vétérinaire. Aucune étude n'a été publiée sur leur activité contre Malassezia pachydermatis.

Hypothèses/Objectifs

Evaluer l'activité in vivo et in vitro de lingettes imprégnées d'une solution de chlorhexidine, climbazole et Tris-EDTA contre Malassezia pachydermatis.

Sujets

Cinq colonies de shar-pei de recherche.

Méthodes

Les lingettes ont été appliquées une fois par jour au niveau du pli axillaire gauche, le pli inguinal droit et de la zone périanale(protocole A) et deux fois par joursur le pli axillaire droit, le inguinal droit et l'ombilic (protocole B) pendant 3 jours. L'activité in vivo a été évaluée par quantification des colonies de Malassezia par disques de contact sur les zones corporelles choisies avant et après application des lingettes. L'activité de la solution d'imprégnation des lingettes a été testée in vitro par tests de contact suivant les recommandations de l'European Standard UNI EN 1275.

Résultats

Les échantillons prélevés après application ont montré une diminution importante et rapide des CFU des levures Malassezia. Aucune différence significative dans la diminution des Malassezia n'a été mise en évidence entre les protocoles A et B. Des tests in vitro ont montré 100% d'activité contre les Malassezia après un temps de contact de 15 minutes avec la solution des lingettes.

Conclusions et importance Clinique

Les lingettes contenant la chlorhexidine, le climbazole et le Tris-EDTA réduisent substantiellement la population de M. pachydermatis sur la peau des chiens. Les résultats, bien qu'il s'agisse d'une étude non contrôlée réalisée sur un faible nombre de chiens, suggère que ces lingettes peuvent être utiles en traitement local de la dermatite à Malassezia des lèvres, des pattes, du périnée et des plis cutanés.

Resumen

Introducción

las gasas que contienen clorhexidina y derivados de azol son recomendadas para uso veterinario. No se ha publicado ningún estudio acerca su actividad contra Malassezia paquidermatis.

Hipótesis/Objetivos

evaluar la actividad in vivo e in vitro de las gasas con clorhexidina, climbazol y soluciónb Tris-EDTA frente a Malassezia pachydermatis

Animales

cinco colonias de investigación de perros Sharpei.

Métodos

las gasas se aplicaron una vez al día en la axila izquierda, zona inguinal izquierda, y zona perianal (protocolo A), y dos veces al día en la axila derecha, zona inguinal derecha, y región umbilical (protocolo B) durante tres días. La actividad in vivo se evaluó mediante cuantificación de las colonias de Malassezia en placas de contacto de zonas seleccionadas del cuerpo antes y después de la aplicación de las gasas. La actividad de la solución en las que las gasas se empaparon se evaluó in vitro mediante pruebas de contacto siguiendo los estándares europeos UNI EN 1275.

Resultados

las muestras recogidas tras la aplicación de las gasas mostraron una reacción rápida y significativa de las colonias de Malassezia. No hubo significativas en la reducción de Malassezia en los dos protocolos. El ensayo in vitro demostró una actividad del 100% frente a Malassezia tras 15 minutos de contacto con la solución de las gasas.

Conclusiones e importancia clínica

las gasas que contienen clorhexidina, climbazol y Tris-EDTA reducen sustancialmente la población de Malassezia paquidermatis en la piel de perros. Aunque este era un estudio no controlado y desarrollado en un pequeño número de perros, los resultados sugieren que estas gasas pueden ser útiles para la terapia tópica de dermatitis producida por Malassezia en zonas de los labios, almohadillas plantares, y zonas perianales y pliegues de la piel.

Zusammenfassung

Hintergrund

Feuchttücher, die Chlorhexidinund Azolderivate beinhalten, werden für den veterinärmedizinischen Gebrauch empfohlen. Es gibt keine Studie über ihre Wirkung im Einsatz gegen Malasseziapachydermatis.

Hypothese/Ziele

Eine Evaluierung der in vivo und der in vitro Aktivität dieser Feuchttücher in einer Chlorhexidin, Climbazol und Tris-EDTA Lösung gegen Malasseziapachydermatis.

Tiere

Fünf Shar-Peis aus einer Versuchstierkolonie.

Methoden

Die Feuchttücher wurden einmal täglich in der linken Achsel, in der linken Inguinalgegend und perianal (Protokol A) angewendet, und zweimal täglich in der rechten Achsel, in der rechten Inguinalgegend und umbilikal (Protokol B); beide Protokolle wurden 3 Tage lang durchgeführt. Die in vivo Aktivität wurde durch die Quantifizierung von Malassezienkolonien durch Kontaktplatten an den ausgewählten Körperstellen vor und nach Verwendung der Feuchttücher beurteilt. Die Aktivität der Lösung, in der die Feuchttücher getaucht waren, wurde in vitro mittels Kontakttest, den European Standard UNI EN 1275 Richtlinienfolgend, beurteilt.

Ergebnisse

Die Proben, die nach Anwendung der Feuchttücher genommen wurden, zeigten eine signifikante und rasche Abnahme der Malassezienhefen CFU. Zwischen den Protokollen A und B wurden keine signifikanten Unterschiede bei der Reduktion der Malassezien gefunden. Der in vitro Test zeigte nach einer 15 minütigen Kontaktzeit mit der Feuchtlösung eine 100%ige Wirkung gegen Malassezien.

Schlussfolgerungen und klinische Bedeutung

Feuchttücher, die Chlorhexidin, Climbazol und Tris-EDTA enthalten, reduzierten die M. pachydermatisPopulation auf der Haut der Hunde signifikant. Obwohl es sich um eine unkontrollierte Studie handelte, die an einer kleinen Zahl von Hunden durchgeführt wurde, weisen die Ergebnisse darauf hin, dass diese Feuchttücher für eine topische Behandlung der Malasseziendermatitis der Lippen, der Pfoten, der Perianalgegend und der Hautfaltennützlich sein könnten.

Inline graphic

Inline graphic

Introduction

Malassezia pachydermatis is a lipophilic yeast that is part of the normal cutaneous microflora of many warm-blooded vertebrates. Alterations in the skin surface microclimate or host defence promote Malassezia proliferation.1,2 Given that M. pachydermatis is located on the stratum corneum, topical therapy may be sufficient to resolve clinical signs of infection.2 Wipes soaked in a solution with antiseptic and antifungal agents have been recommended for veterinary use. To the best of the authors' knowledge no study has been published about their efficacy.

The aim of this study was to assess the in vivo and in vitro activity of commercial cotton wipes (CLX® Wipes, ICF; Cremona, Italy) against M. pachydermatis from naturally infected dogs. The wipes are soaked in a solution containing chlorhexidine digluconate 0.3%, climbazole 0.5%, zinc gluconate 1%, ethylene diamine tetra acetic acid-tromethamine (Tris-EDTA) with benzoyl alcohol, propylene glycol, ethoxylated isotridecanol and glycerin as excipients.

Material and Methods

Dogs

Five shar-pei dogs living in the kennel facility research, two males and three females, aged between 4 and 6 years were used. They showed an average ≥4 Malassezia yeasts in 10 microscopic fields, at ×1000 magnification, using the tape strip technique on left and right axilla, left and right groin, umbilical region and the perianal area. The study was performed according to institutional animal welfare regulations. The Ecole Nationale Veterinaire d'Alfort Ethics Committee was consulted and the methods used in the present study were considered to cause neither discomfort nor pain to the dogs.

In vivo wipes activity

The wipes were applied once daily (09.00 h) on the left axilla, left groin and perianal area (protocol A), and twice daily (09.00 and 21.00 h) on the right axilla, right groin and umbilical region (protocol B) for three consecutive days. One wipe (21 cm × 29 cm) was scrubbed on each area for 30 s. The population size of M. pachydermatis was estimated using contact plates containing modified Dixon's medium.3 They were pressed on each site for 10 s before the first morning application and subsequently after 30 min, 3 h and 12 h. The same selected areas were sampled once daily for the following 3 days and 7 days after the last wipe application. Plates were incubated at 30°C for 3 days. Malassezia yeasts were identified by microscopic examination, using lactophenol cotton blue stain. Malassezia colonies were counted up to a maximum of 900 and results were reported as Malassezia colony forming units (CFU) values; if there were >900 CFU/plate, the presence of 1,000 UFC was considered.3

In vitro assay

The activity of the wipe solution (WS) in which the wipes are soaked and its dilutions 1/10, 1/100 and 1/1000 in sterile distilled water, against M. pachydermatis was evaluated, following the guidelines of the European regulation UNI EN 1275.4 A reference strain (M. pachydermatis CBS1879) and five isolates of yeast from the left axilla of dogs used in the in vivo study were tested. These isolates were cultured on Sabouraud's dextrose agar (Biolife; Milan, Italy) for 3 days at 30°C. After two subcultures the yeast colonies were diluted in distilled water with Tween 80 0.1% (Sigma-Aldrich; Milan, Italy). These test suspensions (TS) were standardized to 1.5–5.0 × 107 CFU/mL by a spectrophotometer at 630 nm (Ultrospec2000, Pharmacia Biotech; Milan, Italy). Two mL of the TS were added, respectively, to 8 mL of the WS and to 8 mL of sterile physiological solution used as a growth control. After fixed contact times (1, 5, 15 and 30 min), 1 mL of the TS/WS mixture was added to a neutralizing solution (lecithin 3 g/L; Tween 80.3%, Sigma-Aldrich) to suppress the fungicidal activity.4 Then 100 μL of the resulting suspension and 100 μL of the TS/WS mixture, without being neutralized, were placed onto Sabouraud's dextrose agar plates. After incubation at 30°C for 3 days the number of CFU per single plate was evaluated. According to the UNI EN 1275 guidelines, the WS and its dilutions were considered fungicidal if at least a four decimal log (i.e. 99.99%) reduction of the Malassezia yeast after 15 min contact time was observed.4 Two tests for each Malassezia strain were performed.

Data analysis

The percentage of CFU reduction between day one, T0, and different fixed times (FT) after wipe application was calculated as follows: % reduction of Malassezia count = [(Count at T0 – Count at FT)/Count at T0] ×100. The normality of the data was assessed by the Shapiro-Wilk test. The post hoc test after ANOVA with repeated measures was employed to evaluate the CFU reduction in protocols A and B. Wilcoxon rank-sum test with continuity correction was used to compare the CFU reduction in both protocols. All of the analyses were performed with R Core Team software (2014) (http://www.R-project.org/). A P-value < 0.05 was considered significant.

Results

In vivo wipes activity

The percentage of CFU reduction after wipe application is shown in Table 1. In both protocols, 30 min after the first wipe application, Malassezia CFU reduction was statistically significant compared with the initial value (Figure1). Malassezia CFU values from all samples collected at different times during the wipe application days and from the samples collected within 3 days and 7 days after the last wipe application remained significantly lower than initial CFU values (Figure1). No significant difference in the Malassezia reduction was found between protocols A and B (Wilcoxon rank-sum test: W = 3309.5, P = 0.71). No adverse effects were noted except mild and transient erythema and pruritus at the sites of wipe application in one dog.

Table 1.

In vivo activity of the wipes: percentage of Malassezia CFU reduction: 30 min and 3 h after the application on the 3 days of wipe application (first, second & third day); 12, 24, 36, 48 and 60 h after the first wipe application; 1, 2, 3 and 7 days after the last wipe application. A = protocol A (once a day wipe application); B = protocol B (twice a day wipe application); WA = wipe application

After morning WA
After the first WA
After the last WA
A B A B A B
First day 12 h 71% 78% 1 day 96% 99%
 30 min 66% 74% 24 h 83% 96% 2 days 97% 99%
 3 h 70% 76% 36 h 98% 98% 3 days 98% 99%
Second day 48 h 98% 99% 7 days 94% 97%
 30 min 88% 87% 60 h 99% 99%
 3 h 93% 78%
Third day
 30 min 82% 79%
 3 h 79% 42%

Figure 1.

Figure 1

Malassezia CFU (median values) before and after wipes application at different sampling times. Protocol A: once a day wipe application. Protocol B: twice a day wipe application. D = days; h = hours; arrows = wipe applications. Stars indicate significant decreases of CFU compared with sampling immediately previous (*P < 0.05; **P < 0.01; ***P < 0.001). CFU at all time points are significantly lower than CFU count at T0. Protocol A: all samples P < 0.001, except the sample collected after 3 h on D1, P < 0.05. Protocol B: all samples P < 0.001, except the samples collected after 30 min and 3 h on D1, P < 0.01 (post hoc test after ANOVA with repeated measures).

In vitro assay

The undiluted WS reduced viable Malassezia cells with a linear trend (Table 2). After one minute contact time the yeast reduction was between 25% and 53%, while after five minute contact time the percentage of decrease was >95%. After 15 min contact time the WS activity was complete with 100% reduction of all yeast strains. All dilutions of the WS showed poor efficacy in reducing Malassezia strains when the fungicidal activity was suppressed by the neutralizing solution at fixed contact times. Conversely, the 1/10 and 1/100 WS dilutions showed >99% reduction of all yeast isolates with prolonged contact time, i.e. when the fungicidal activity was not suppressed by the neutralizing solution.

Table 2.

In vitro activity of the wipe solution and its dilutions against Malassezia pachydermatis (1–5: strains from the dogs used for in vivo assay; reference strain: CBS1879). Numbers indicate the percentage of CFU reduction (mean of two tests for each strain)

Strain Wipe solution Contact times
1 min 5 min 15 min 30 min Prolonged
1 Undiluted 37.8 99.0 100 100 100
1/10 15.9 28.6 29.0 30.2 100
1/100 8.6 9.0 20.7 28.3 99.9
1/1000 1.2 3.4 9.4 10.1 11.2
2 Undiluted 53.3 96.8 100 100 100
1/10 12.4 31.9 28.7 31.3 100
1/100 7.5 10.9 19.0 27.1 99.9
1/1000 2.4 4.5 7.3 5.3 10.4
3 Undiluted 42.8 97.6 100 100 100
1/10 10.3 29.2 30.2 37.9 100
1/100 7.5 10.9 19.0 27.1 99.9
1/1000 1.3 4.0 4.3 4.9 9.0
4 Undiluted 35.6 95.7 100 100 100
1/10 12.3 25.6 30.0 31.9 100
1/100 7.5 10.9 19.0 27.1 99.9
1/1000 2.3 4.9 3.4 5.8 8.9
5 Undiluted 40.8 93.4 100 100 100
1/10 8.9 23.3 35.0 32.4 100
1/100 7.5 10.9 19.0 27.1 99.9
1/1000 1.2 3.4 4.6 5.8 10.1
Reference strain Undiluted 24.8 96.8 100 100 100
1/10 7.1 20.2 25.4 27.3 100
1/100 6.4 8.3 21.2 35.6 99.8
1/1000 2.3 4.6 3.3 4.3 9.3

Discussion

The present study demonstrated that once or twice daily applications of wipes soaked in antiseptic and antifungal agents are effective in reducing M. pachydermatis populations on canine skin. The in vivo activity of wipes was supported by in vitro tests. Wipes were quick and effective in reducing Malassezia yeasts on the skin of all naturally infected dogs. In both protocols, 30 min after wipe application there was already >60% Malassezia reduction. Both protocols resulted in a 99% reduction of Malassezia CFU: as soon as the third day under protocol A and as soon as the second day after application under protocol B, respectively. Malassezia CFU decrease was observed during the 12 h following each wipe application and significantly reduced Malassezia populations were found within 3 and 7 days after the last wipe application. Residual antifungal activity may be suspected to explain this finding because residual antimicrobial activity of hair shafts after application of chlorhexidine shampoos and conditioner was previously demonstrated.5 Our in vitro data support this hypothesis because the WS, even after 1/10 and 1/100 dilutions, prevented the growth of Malassezia yeast when these were kept in prolonged contact with the active solution.

In the present study, fungal culture was chosen to assess the cutaneous Malassezia yeast population because it has higher sensitivity than cytological examination.6 Contact plates have been used to quantify Malassezia on skin areas.3,6 In vitro WS activity has been evaluated by contact tests, previously used to assess the efficacy of solutions against bacteria and yeasts.4 This approach takes into account the main factors which influence the efficacy of antimicrobial topical products, namely the product formulation effects and the duration of contact.7

Only six M. pachydermatis isolates were tested in vitro. This in vitro assay was performed to simulate the in vivo behaviour of Malassezia in contact with wipes on the cutaneous sites. There was no intention to perform an epidemiological study on Malassezia susceptibility to WS.

The wipes' activity is likely to be due to chlorhexidine, climbazole and Tris-EDTA. In vitro and in vivo 2%–4.5% chlorhexidine showed efficacy against Malassezia yeasts.1,2 In vivo, 3% chlorhexidine and 0.5% climbazole shampoo and, in vitro, a combination of Tris-EDTA and 0.15% chlorhexidine demonstrated anti-Malassezia activity.8,9 Climbazole was effective in vitro against M. pachydermatis showing a 0.06 μg/mL minimal inhibitory concentration.10

In conclusion, once or twice daily applications of wipes soaked in a chlorhexidine, climbazole and Tris-EDTA solution are effective in reducing the numbers of M. pachydermatis yeast on canine skin. These wipes may be useful for treating lips, interdigital spaces, the perianal area and skin folds frequently affected by Malassezia overgrowth.1,2 It must be stated that this was an uncontrolled study performed on a small number of dogs. A controlled study using placebo wipes on a large number of dogs should follow this pilot study.

Acknowledgments

The authors thank Thomas Lilin for allowing the access to research shar-pei dogs.

References

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