Antifungal Effect of Liposomal α-Bisabolol and When Associated with Fluconazole

Antifungal Effect of Liposomal α-Bisabolol and When Associated with Fluconazole

Fungal pathologies caused by the genus <i>Candida</i> have increased in recent years due to the involvement of immunosuppressed people and the advance of resistance mechanisms acquired by these microorganisms. Liposomes are nanovesicles with lipid bilayers in which they store compounds....

Full description

Bibliographic Details
Main Authors: Camila F. Bezerra, José Geraldo de A. Júnior, Rosilaine de L. Honorato, Antonia Thassya L. dos Santos, Josefa Carolaine P. da Silva, Taís G. da Silva, Thiago S. de Freitas, Thiago Adler T. Vieira, Maria Clara F. Bezerra, Débora Lima Sales, João Pedro V. Rodrigues, José M. Barbosa Filho, Laisla R. Peixoto, Allyson P. Pinheiro, Henrique D. M. Coutinho, Maria Flaviana B. Morais-Braga, Teresinha G. da Silva
Format: Article
Language:English
Published: MDPI AG 2021-04-01
Series:Cosmetics
Subjects:
liposomes
<i>Candida</i>
fluconazole
dimorphism
nanotechnology
Online Access:https://www.mdpi.com/2079-9284/8/2/28
id doaj-b9c2907a8e9b4db892465f6bc7b12d1c
record_format Article
collection DOAJ
language English
format Article
sources DOAJ
author Camila F. Bezerra
José Geraldo de A. Júnior
Rosilaine de L. Honorato
Antonia Thassya L. dos Santos
Josefa Carolaine P. da Silva
Taís G. da Silva
Thiago S. de Freitas
Thiago Adler T. Vieira
Maria Clara F. Bezerra
Débora Lima Sales
João Pedro V. Rodrigues
José M. Barbosa Filho
Laisla R. Peixoto
Allyson P. Pinheiro
Henrique D. M. Coutinho
Maria Flaviana B. Morais-Braga
Teresinha G. da Silva
spellingShingle Camila F. Bezerra
José Geraldo de A. Júnior
Rosilaine de L. Honorato
Antonia Thassya L. dos Santos
Josefa Carolaine P. da Silva
Taís G. da Silva
Thiago S. de Freitas
Thiago Adler T. Vieira
Maria Clara F. Bezerra
Débora Lima Sales
João Pedro V. Rodrigues
José M. Barbosa Filho
Laisla R. Peixoto
Allyson P. Pinheiro
Henrique D. M. Coutinho
Maria Flaviana B. Morais-Braga
Teresinha G. da Silva
Antifungal Effect of Liposomal α-Bisabolol and When Associated with Fluconazole
Cosmetics
liposomes
<i>Candida</i>
fluconazole
dimorphism
nanotechnology
author_facet Camila F. Bezerra
José Geraldo de A. Júnior
Rosilaine de L. Honorato
Antonia Thassya L. dos Santos
Josefa Carolaine P. da Silva
Taís G. da Silva
Thiago S. de Freitas
Thiago Adler T. Vieira
Maria Clara F. Bezerra
Débora Lima Sales
João Pedro V. Rodrigues
José M. Barbosa Filho
Laisla R. Peixoto
Allyson P. Pinheiro
Henrique D. M. Coutinho
Maria Flaviana B. Morais-Braga
Teresinha G. da Silva
author_sort Camila F. Bezerra
title Antifungal Effect of Liposomal α-Bisabolol and When Associated with Fluconazole
title_short Antifungal Effect of Liposomal α-Bisabolol and When Associated with Fluconazole
title_full Antifungal Effect of Liposomal α-Bisabolol and When Associated with Fluconazole
title_fullStr Antifungal Effect of Liposomal α-Bisabolol and When Associated with Fluconazole
title_full_unstemmed Antifungal Effect of Liposomal α-Bisabolol and When Associated with Fluconazole
title_sort antifungal effect of liposomal α-bisabolol and when associated with fluconazole
publisher MDPI AG
series Cosmetics
issn 2079-9284
publishDate 2021-04-01
description Fungal pathologies caused by the genus <i>Candida</i> have increased in recent years due to the involvement of immunosuppressed people and the advance of resistance mechanisms acquired by these microorganisms. Liposomes are nanovesicles with lipid bilayers in which they store compounds. α-Bisabolol is a sesquiterpene with proven biological activities, and in this work it was tested alone in liposomes and in association with Fluconazole in vitro to evaluate the antifungal potential, Fluconazole optimization, and virulence inhibitory effect in vitro. Antifungal assays were performed against standard strains of <i>Candida albicans</i>, <i>Candida tropicalis</i>, and <i>Candida krusei</i> by microdilution to identify the IC<sub>50</sub> values and to obtain the cell viability. The Minimum Fungicidal Concentration (MFC) was performed by subculturing on the solid medium, and at their subinhibitory concentration (Matrix Concentration (MC): 16,384 µg/mL) (MC/16), the compounds, both isolated and liposomal, were associated with fluconazole in order to verify the inhibitory effect of this junction. Tests to ascertain changes in morphology were performed in microculture chambers according to MC concentrations. Liposomes were characterized from the vesicle size, polydispersity index, average Zeta potential, and scanning electron microscopy. The IC<sub>50</sub> value of the liposomal bisabolol associated with fluconazole (FCZ) was 2.5 µg/mL against all strains tested, revealing a potentiating effect. Liposomal bisabolol was able to potentiate the effect of fluconazole against the CA and CT strains by reducing its concentration and completely inhibiting fungal growth. α-Bisabolol in liposomal form inhibited the morphological transition in all strains tested at a concentration of MC/8. The liposomes were homogeneous, with vesicles with diameters of 203.8 nm for the liposomal bisabolol and a surface charge potential of −34.2 mV, conferring stability to the nanosystem. Through scanning microscopy, the spherical shapes of the vesicles were observed.
topic liposomes
<i>Candida</i>
fluconazole
dimorphism
nanotechnology
url https://www.mdpi.com/2079-9284/8/2/28
work_keys_str_mv AT camilafbezerra antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT josegeraldodeajunior antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT rosilainedelhonorato antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT antoniathassyaldossantos antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT josefacarolainepdasilva antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT taisgdasilva antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT thiagosdefreitas antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT thiagoadlertvieira antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT mariaclarafbezerra antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT deboralimasales antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT joaopedrovrodrigues antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT josembarbosafilho antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT laislarpeixoto antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT allysonppinheiro antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT henriquedmcoutinho antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT mariaflavianabmoraisbraga antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
AT teresinhagdasilva antifungaleffectofliposomalabisabololandwhenassociatedwithfluconazole
_version_ 1721544657998970880
spelling doaj-b9c2907a8e9b4db892465f6bc7b12d1c2021-04-02T23:02:24ZengMDPI AGCosmetics2079-92842021-04-018282810.3390/cosmetics8020028Antifungal Effect of Liposomal α-Bisabolol and When Associated with FluconazoleCamila F. Bezerra0José Geraldo de A. Júnior1Rosilaine de L. Honorato2Antonia Thassya L. dos Santos3Josefa Carolaine P. da Silva4Taís G. da Silva5Thiago S. de Freitas6Thiago Adler T. Vieira7Maria Clara F. Bezerra8Débora Lima Sales9João Pedro V. Rodrigues10José M. Barbosa Filho11Laisla R. Peixoto12Allyson P. Pinheiro13Henrique D. M. Coutinho14Maria Flaviana B. Morais-Braga15Teresinha G. da Silva16Department of Pharmaceutical Sciences, Federal University of Pernambuco-UFPE, Recife 50732-970, BrazilDepartment of Pharmacy, Federal University of Ceará-UFC, Fortaleza 60455-900, BrazilDepartment of Biological Sciences, Regional University of Cariri-URCA, Crato 63105-010, BrazilDepartment of Biological Sciences, Regional University of Cariri-URCA, Crato 63105-010, BrazilDepartment of Biological Sciences, Regional University of Cariri-URCA, Crato 63105-010, BrazilDepartment of Biological Sciences, Regional University of Cariri-URCA, Crato 63105-010, BrazilDepartment of Biological Chemistry, Regional University of Cariri-URCA, Crato 63105-010, BrazilDepartment of Pharmaceutical Sciences, Federal University of Pernambuco-UFPE, Recife 50732-970, BrazilFaculty of Medicine of Juazeiro do Norte-Estácio FMJ, Juazeiro do Norte 63047-045, BrazilDepartment of Biological Chemistry, Regional University of Cariri-URCA, Crato 63105-010, BrazilDepartment of Pharmacy, Federal University of Ceará-UFC, Fortaleza 60455-900, BrazilDepartment of Pharmacy, Federal University of Paraíba-UFPB, João Pessoa 58051-900, BrazilDepartment of Pharmacy, Federal University of Paraíba-UFPB, João Pessoa 58051-900, BrazilDepartment of Biological Sciences, Regional University of Cariri-URCA, Crato 63105-010, BrazilDepartment of Biological Chemistry, Regional University of Cariri-URCA, Crato 63105-010, BrazilDepartment of Biological Sciences, Regional University of Cariri-URCA, Crato 63105-010, BrazilDepartment of Antibiotics, Federal University of Pernambuco-UFPE, Recife 50732-970, BrazilFungal pathologies caused by the genus <i>Candida</i> have increased in recent years due to the involvement of immunosuppressed people and the advance of resistance mechanisms acquired by these microorganisms. Liposomes are nanovesicles with lipid bilayers in which they store compounds. α-Bisabolol is a sesquiterpene with proven biological activities, and in this work it was tested alone in liposomes and in association with Fluconazole in vitro to evaluate the antifungal potential, Fluconazole optimization, and virulence inhibitory effect in vitro. Antifungal assays were performed against standard strains of <i>Candida albicans</i>, <i>Candida tropicalis</i>, and <i>Candida krusei</i> by microdilution to identify the IC<sub>50</sub> values and to obtain the cell viability. The Minimum Fungicidal Concentration (MFC) was performed by subculturing on the solid medium, and at their subinhibitory concentration (Matrix Concentration (MC): 16,384 µg/mL) (MC/16), the compounds, both isolated and liposomal, were associated with fluconazole in order to verify the inhibitory effect of this junction. Tests to ascertain changes in morphology were performed in microculture chambers according to MC concentrations. Liposomes were characterized from the vesicle size, polydispersity index, average Zeta potential, and scanning electron microscopy. The IC<sub>50</sub> value of the liposomal bisabolol associated with fluconazole (FCZ) was 2.5 µg/mL against all strains tested, revealing a potentiating effect. Liposomal bisabolol was able to potentiate the effect of fluconazole against the CA and CT strains by reducing its concentration and completely inhibiting fungal growth. α-Bisabolol in liposomal form inhibited the morphological transition in all strains tested at a concentration of MC/8. The liposomes were homogeneous, with vesicles with diameters of 203.8 nm for the liposomal bisabolol and a surface charge potential of −34.2 mV, conferring stability to the nanosystem. Through scanning microscopy, the spherical shapes of the vesicles were observed.https://www.mdpi.com/2079-9284/8/2/28liposomes<i>Candida</i>fluconazoledimorphismnanotechnology

Similar Items