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Comparative analysis of biofilm formation by Candida albicans and Candida krusei in different types of contact lenses

Análise comparativa da formação de biofilmes, por Candida albicans e Candida krusei, em diferentes tipos de lentes de contato

ABSTRACT

Objective:

To evaluate the Candida krusei and Candida albicans biofilm formation abilities on 5 different types of contact lenses and compare their metabolic activities and biomass.

Methods:

After biofilm formation by both the test species, their metabolic activity was assessed by the 2,3-bis (2-methoxy-4-nitro-5-sulfophenyl)-2H-tetrazolium-5-carboxanilide reduction assay with menadione, while the biomass was determined by staining with 0.4% crystal violet dye for further statistical analysis.

Results:

Both the Candida species could form biofilms on different types of contact lenses, with greater metabolic activities and lower biomass formation in rigid gas permeable lenses.

Conclusion:

Biofilm formation with greater metabolic activity and greater biomass were expected on soft contact lenses considering their surface hydrophobicity. However, the results demonstrated a greater metabolic activity on rigid contact lenses. This result has a great significance with regards to the increasing risk of microbial keratitis, although further studies are warranted to better elucidate the formation of biofilms on different types of contact lens materials in the future.

Keywords:
Biofilm; Contact lense; Contact lense, hydrophilic; Candida albicans; Candida krusei

RESUMO

Objetivo:

Avaliar a capacidade de formação de bio­filmes de Candida krusei e Candida albicans em cinco tipos de lentes de contato, comparando atividade metabólica e biomassa dos mesmos.

Métodos:

Após a formação de biofilme de ambas as espécies, a atividade metabólica foi avaliada por ensaio de redução 2,3-bis (2-methoxy-4-nitro-5-sulfophenyl)-2H-te­tra­zolium-5-carboxanilide com Menadiona, e a biomassa foi avaliada por coloração com Cristal Violeta 0,4% para posterior análise estatística.

Resultados:

Ambas as espécies de Candida foram capazes de formar biofilmes nos diferentes tipos de lentes de contato, havendo em lentes rígidas gás permeável maior atividade metabólica e menor biomassa formada.

Conclusão:

Esperava-se a obtenção de biofilmes de maior atividade metabólica e maior biomassa em lentes de contato gelatinosas com base no fundamento da Hidrofobicidade Superficial. Porém, o resultado apontou para maior atividade metabólica em lentes de contato rígidas. Apesar de observados resultados significativos, trata-se de um assunto de grande importância frente ao aumento do número de ceratites microbianas, mostrando-se necessários outros estudos para melhor elucidar a formação de biofilmes em diferentes tipos de materiais de lentes de contato.

Descritores:
Biofilme; Lente de contato; Lente de contato hidrofílica; Candida albicans; Candida krusei

INTRODUCTION

The popularization of the use of contact lenses runs parallel with reports of increased risk of microbial keratitis. Although fungal keratitis represents only 1.5% of all cases of keratitis in contact lenses users(11 Moriyama AS, Hofling-Lima AL. Contact lens-associated microbial keratitis. Arq Bras Oftalmol. 2008;71(6 Suppl):32-6.), the presence of fungi and the consequent formation of biofilms in contact lenses is a growing threat to the public health(22 Imamura Y, Chandra J, Mukherjee PK, Lattif AA, Szczotka-Flynn LB, Pearlman E, et al. Fusarium and Candida albicans biofilms on soft contact lenses: model development, influence of lens type, and susceptibility to lens care solutions. Antimicrob Agents Chemother. 2008;52(1):171-82.).

Most Candida spp. are biofilm producers on a large or small scale, which is an important factor associated with their virulence and resistance to antifungals, which in turn favor the occurrence of serious or recurrent infections(33 Cardoso B. Produção de biofilme e perfil de suscetibilidade a antifúngicos de isolados de Candida spp. em episódios de candidemia no Hospital das Clínicas da FMRP-USP [tese]. Ribeirão Preto: Universidade de São Paulo; 2017.). Owing to the physical barrier of a polymeric matrix in relation to fungal biofilms, less susceptibility is associated with the penetration of antimicrobials of multipurpose solutions for the maintenance of contact lenses(44 Ramage G, VandeWalle K, Bachmann SP, Wickes BL, López-Ribot JL. In vitro pharmacodynamic properties of three antifungal agents against preformed Candida albicans biofilms determined by time-kill studies. Antimicrob Agents Chemother. 2002;46(11):3634-6.).

The inappropriate handling of contact lenses by their users generates friction between the lenses and the cornea, causing reactions that ease the entry of infectious agents onto the lenses, although the mentioned organisms do not penetrate the whole cornea(55 De Oliveira PR, Resende SM, De Oiveira FC, De Oliveira AC. Ceratite fúngica. Arq Bras Oftalmol. 2001;64(1):75-9.).

According to the literature, the risk of complications from the use of soft contact lens subtypes is greater than that from the use of rigid ones(66 Franks WA, Adams GG, Dart JK, Minassian D. Relative risks of different types of contact lenses. BMJ. 1988 Aug 20-27;297(6647):524-5.).

Concerning rigid gas permeable contact lenses, past data demonstrate a 21-times greater risk of microbial keratitis for programmed-replacement disposal lenses and a 4-times greater risk among daily-use contact lenses. In contrast, the analyses of only rigid contact lenses have shown only a slightly higher risk with polymethylmethacrylate contact lenses when compared to rigid gas permeable ones(77 Dart JK, Stapleton F, Minassian D, Dart JK. Contact lenses and other risk factors in microbial keratitis. Lancet. 1991;338(8768):650-3.).

Through this study, we aimed to broaden the considerably scarce knowledge database on the possibility of different types of contact lenses materials allowing the formation of biofilms formation by C. albicans and C. krusei toward the development of preventive and/or reductive measures against eye infections among contact lenses users.

METHODS

The present study was conducted at the Microbiology and Immunology Laboratories from the Federal University of Alfenas (UNIFAL-MG). Two strains of Candida spp. were used, namely, C. albicans SC5314 and C. krusei ATCC® 6258.

To assess and compare the capacity of biofilm formation in different types of contact lenses by the selected strains of Candida spp., 5 types of contact lenses were used in this study. Among the soft contact lenses, biofilms were formed in programmed-replacement disposal, single-use (daily disposable), and therapeutic contact lenses. Among rigid gas permeable contact lenses, the biofilms were formed in polycarbonate lenses and in Hexafocon A copolymer (XO®, Bausch and Lomb).

Biofilms were developed as suggested in the literature(88 Ramage G, Vande Walle K, Wickes BL, López-Ribot JL. Standardized method for in vitro antifungal susceptibility testing of Candida albicans biofilms. Antimicrob Agents Chemother. 2001;45(9):2475-9.) with some modifications(99 Melo AS, Bizerra FC, Freymüller E, Arthington-Skaggs BA, Colombo AL. Biofilm production and evaluation of antifungal susceptibility amongst clinical Candida spp. isolates, including strains of the Candida parapsilosis complex. Med Mycol. 2011;49(3):253-62.). Briefly, pre-sterilized commercial flat-bottom polystyrene 24-wells microplates with a 2-mL total well volume that could perfectly shelter the contact lenses were used in this study. Candida spp. was first cultured on Sabouraud's Dextrose Agar medium and then in RPMI-1640 broth, using the 24-h incubation time at 37°C. The cell concentration was adjusted to 1-5 × 107 cells/mL in RPMI-1640 broth by measuring the optical density (OD), which was nearly 0.4 at 530 nm. On the contact lenses, the culture suspensions were added and maintained for 2 h at 37°C on a shaker at 75 rpm to ensure cell adhesion. The plate/lens sets were washed with PBS solution, non-inoculated RPMI was added, and the microplates were incubated again for 24 h at 37°C on 75-rpm rotation shaker for biofilm formation/development. The tests were performed thrice on different types of contact lenses.

The metabolic activities of biofilms were assessed by the 2,3-bis (2-methoxy-4-nitro-5-sulfophenyl)-2H-te­trazolium-5-carboxanilide (XTT) reduction assay as described elsewhere(88 Ramage G, Vande Walle K, Wickes BL, López-Ribot JL. Standardized method for in vitro antifungal susceptibility testing of Candida albicans biofilms. Antimicrob Agents Chemother. 2001;45(9):2475-9.) with some modifications(99 Melo AS, Bizerra FC, Freymüller E, Arthington-Skaggs BA, Colombo AL. Biofilm production and evaluation of antifungal susceptibility amongst clinical Candida spp. isolates, including strains of the Candida parapsilosis complex. Med Mycol. 2011;49(3):253-62.). The reagent solution was prepared at the ratio of 5:1 by mixing a 1 mg/mL XTT solution in PBS and 0.4 mM menadione solution in acetone (XTT:Menadione) and added to the microplate wells on which the biofilm formation on contact lenses was performed. After incubating the flat-bottom microplates for 90 min in the dark, OD readings were taken at 490 nm by using an automated microplate reader. These readings referred to the metabolic activity of the biofilms evaluated since the change in the color is proportional to the number of living cells; thus, greater the absorbance, greater is the number of metabolically active cells, considering that XTT quantifies the ability of the dehydrogenase enzyme present in the mitochondria to convert the water-soluble tetra­zolium salt (XTT) (yellow color) into formazan compounds (orange color)(88 Ramage G, Vande Walle K, Wickes BL, López-Ribot JL. Standardized method for in vitro antifungal susceptibility testing of Candida albicans biofilms. Antimicrob Agents Chemother. 2001;45(9):2475-9.).

For total biomass evaluation, the wells were washed with PBS, to which 0.4% crystal violet dye was added after drying the wells/lenses. After contacting for 15 min, the dye was removed from each well containing the lenses, which were then washed 4-times with distilled water. Subsequently, absolute ethanol was added to the wells for solubilizing the dye that had adhered to the biofilm, followed by OD measurement of this solution at 595 nm. Higher OD values indicate biofilms with greater biomass production(1010 Naves P, del Prado G, Huelves L, Gracia M, Ruiz V, Blanco J, et al. Correlation between virulence factors and in vitro biofilm formation by Escherichia coli strains. Microb Pathog. 2008;45(2):86-91.).

The biofilm formation and assessment tests were conducted thrice, and the results were compared. Statistically significant differences (p<0.05) were then recorded and the corresponding graphs were created using the Graph Pad Prism 5.0.

RESULTS

Both the tested Candida spp. could form biofilms in the evaluated contact lenses. We noted that the biofilms were formed and standardized in their growth with some aspects of cell development and adhesion.

Biofilm production by C. albicans SC5314 and C. krusei ATCC® 6258 in different types of lenses was estimated by quantification of the metabolic activities by using the XTT reduction assay and analysis of fungal biomass by staining with crystal violet dye (Table 1).

Table 1
Metabolic activity and fungal biomass of Candida krusei and Candida albicans strains. The values are expressed as an average of the optical density (OD) reading ± standard deviation

Greater metabolic activity was determined for biofilms formed by both the Candida spp. on the XO® contact lenses, followed by the formation in polycarbonate lenses. Biofilms with less metabolic activity were recorded for single-use lenses (Figure 1).

Figure 1
Metabolic activity of biofilms from C. albicans SC5314 and C. krusei ATCC® 6258 on different types of contact lenses.

As shown in figure 1, comparison of the biofilms formed by the Candida spp. Indicated that the biofilms formed by C. krusei had greater metabolic activities on the programmed-replacement disposal, therapeutic, polycar­bonate, and single-use lenses. However, C. albicans showed greater metabolic activity only in rigid XO® lens.

Concerning the biomass analysis (Figure 2), rigid lenses (i.e., polycarbonate and XO®) had biofilms with less fungal biomass, although their Candida spp. biofilms demonstrated greater metabolic activities (Figure 1).

Figure 2
Biomass production in biofilms by C. albicans SC5314 and C. krusei ATCC® 6258 in different types of contact lenses.

We also noted a large production of biomass by C. krusei biofilms in the programmed-replacement disposal lenses, which was approximately twice as much as that of C. albicans biofilms in the same type of lens (Figure 2).

In general, biofilms produced on XO® and polycarbonate lenses demonstrated greater metabolic activity, but lesser representative biomass.

DISCUSSION

Candida spp. constitute the normal microbiota of approximately 50% of individuals and generally reside in the human body as a commensal organism(1111 Moragues MD, Omaetxebarria MJ, Elguezabal N, Sevilla MJ, Conti S, Polonelli L, et al. A monoclonal antibody directed against a Candida albicans cell wall mannoprotein exerts three anti-C. albicans activities. Infect Immun. 2003;71(9):5273-9.). Several factors are associated with their virulence that guarantee their ability to colonize and cause infections, such as adherence to host cells, promotion of phenotypic changes, convergence of yeasts into pseudohyphae, formation of biofilms, production of toxic substances (such as hemolysins), resistance to hydrogen peroxide, and the production and secretion of hydrolytic enzymes(1212 Naglik JR, Challacombe SJ, Hube B. Candida albicans secreted aspartyl proteinases in virulence and pathogenesis. Microbiol Mol Biol Rev. 2003;67(3):400-28.,1313 Lyon JP, dos Santos FV, de Moraes PC, Moreira LM. Inhibition of virulence factors of Candida spp. by different surfactants. Mycopathologia. 2011;171(2):93-101.).

In this study, no statistically significant difference was noted in relation to the biofilm production capacity by C. albicans and C. krusei strains (p>0.05). This result contributes to the validity of the concept that contact lens can serve as a suitable surface for Candida spp. adhesion and growth. A past study reported that, besides that the material structure eases the adhesion and multiplication of microorganisms, corneal hypoxia resulting from the prolonged use of contact lenses tends to compromise the integrity of the epithelium, thereby acting as a gateway for microorganisms related to the causation of eye infections(1414 Bôas VT, Almeida Júnior GC, Almeida MT, Gonçalves MS, Coelho LF. Microbiological analysis of contact lens cases: impact of the hospital environment. Arq Bras Oftalmol. 2018;81(5):371-5.).

We assumed that the lenses were not contaminated by any microorganisms, considering that the lenses arrived in sealed and sterilized packaging, which means that the results were related to the growth of sessile cells of C. albicans and C. krusei strains.

According to the results shown in figure 1, the formation of biofilms with greater metabolic activity and greater biomass was noted for rigid contact lenses (i.e., XO®), while the polycarbonate lenses showed greater absorbance for both the species.

We had expected that biofilms on soft contact lenses would have greater metabolic activity and greater biomass. This expectation was also related to the past reports that 2 out of every 3 infections related to the use of contact lenses were associated with soft lenses and 1 to the use of rigid ones(11 Moriyama AS, Hofling-Lima AL. Contact lens-associated microbial keratitis. Arq Bras Oftalmol. 2008;71(6 Suppl):32-6.).

The basis for greater contamination in soft, silicone and hydrogel contact lenses, when compared to rigid lenses, can be attributed to the relative ease of removal of biofilms in rigid lenses, in addition to the fact that hydrophobic materials such as silicone with hydrogel monomers are more prone to biofilm adhesion(1515 Da Silva AR. Biofilmes e Lentes de Contato [tese]. Porto: Universidade Fernando Pessoa; 2012.). This event is called superficial hydrophobicity, in which the free surface energy (FSE) contributes to the greater susceptibility to adhesion of microorganisms. This fact is also directly related to the reaction against water, which is known for its high particle adhesion capacity. Thus, greater the hydrophobicity, lower is the FSE related to the presence of water and greater is the ability of the microorganism to adhere(1616 Rodriguez EJ. Hidrofobicidade superficial e colonização de Candida albicans sobre resina acrílica termopolimerizável para confecção de bases de próteses totais após desinfecção química [tese]. Bauru: Universidade de São Paulo; 2009.). In other words, hydrophobic materials, such as those mainly present in the soft contact lenses tend to enable microbial adhesion and the formation of biofilms, which is associated with higher rates of infections.

The comparison with the average values established from triplicated analyses indicated nearly similar values of metabolic activity for biofilms formed in programmed-replacement disposal, therapeutic, and single-use lenses types.

As shown in figure 1, C. krusei formed biofilms with greater metabolic activity in the evaluated lenses, with the exception of XO® lenses; this result is consistent with that in the literature(1717 Pathak AK, Sharma S, Shrivastva P. Multi-species biofilm of Candida albicans and non-Candida albicans Candida species on acrylic substrate. J Appl Oral Sci. 2012;20(1):70-5.). In a past study(1717 Pathak AK, Sharma S, Shrivastva P. Multi-species biofilm of Candida albicans and non-Candida albicans Candida species on acrylic substrate. J Appl Oral Sci. 2012;20(1):70-5.), 24 Candida spp. were isolated (including strains of C. albicans, C. glabrata, C. krusei, and C. tropicalis). All species showed biofilm formation on acrylic surfaces with moderate to high intensity. In this study, C. krusei did not present with the highest values for the formation of biofilms in comparison with other species of the genus, and smaller results were presented by C. albicans as well; these reports conform to the present results.

Another past study indicated that more hydrophobic species, such as C. tropicalis, C. glabrata, and C. krusei, have greater ability to adhere to polymeric surfaces, such as contact lenses, while the opposite occurs with less hydrophobic species, such as C. albicans, C stellatoidea, and C. parapsilosis(1616 Rodriguez EJ. Hidrofobicidade superficial e colonização de Candida albicans sobre resina acrílica termopolimerizável para confecção de bases de próteses totais após desinfecção química [tese]. Bauru: Universidade de São Paulo; 2009.).

Moreover, it can be seen from figure 2 that biofilms with greater metabolic activity do not necessarily have greater biomass. The same fact was reported in a past comparative study between C. glabrata and C. krusei, in which C. glabrata biofilms demonstrated greater metabolic activity, as assessed by the XTT reduction assay method, than C. krusei biofilms, while also producing less biomass(1818 Rossoni RD, Barros PP, Freire F, Santos JD, Jorge AO, Junqueira JC. Study of Microbial Interaction Formed by "Candida krusei" and "Candida glabrata": "In Vitro" and "In Vivo" Studies. Braz Dent J. 2017;28(6):669-74.). As observed in previous studies, the decrease in the XTT reduction method can be directly associated with the amount of cells present in the biofilm(1818 Rossoni RD, Barros PP, Freire F, Santos JD, Jorge AO, Junqueira JC. Study of Microbial Interaction Formed by "Candida krusei" and "Candida glabrata": "In Vitro" and "In Vivo" Studies. Braz Dent J. 2017;28(6):669-74.), while the greater metabolic activity possibly indicates greater virulence and greater resistance to antifungal agents(1919 Ferreira AV, Prado CG, Carvalho RR, Dias KS, Dias AL. Candida albicans and non-C. albicans Candida species: comparison of biofilm production and metabolic activity in biofilms, and putative virulence properties of isolates from hospital environments and infections. Mycopathologia. 2013;175(3-4):265-72.).

Rigid contact lenses, which are relatively more hydrophilic, are less suitable for microbial adhesion(1616 Rodriguez EJ. Hidrofobicidade superficial e colonização de Candida albicans sobre resina acrílica termopolimerizável para confecção de bases de próteses totais após desinfecção química [tese]. Bauru: Universidade de São Paulo; 2009.). Among the possible causes of greater metabolic activity in these lenses with less biomass, we must consider that a greater catabolic activity, under the stress of the unfavorable environment, lead to a greater transition from organic carbon to carbon dioxide and hence greater use of oxygen from the environment. The generation of carbon dioxide results causes only a smaller amount of cells to be produced, which consequently reduces the overall biomass(2020 Liu Y, Tay JH. Metabolic response of biofilm to shear stress in fixed-film culture. J Appl Microbiol. 2001;90(3):337-42.). In addition, the color intensity produced in the biomass assessment test is directly related to the structure/size of the biofilm formed, which is less on surfaces that are less suitable for proliferation and formation, since, for maintaining gases and nutrients at adequate levels, large biomass condensation must be avoided(2121 Bester E, Kroukamp O, Wolfaardt GM, Boonzaaier L, Liss SN. Metabolic differentiation in biofilms as indicated by carbon dioxide production rates. Appl Environ Microbiol. 2010;76(4):1189-97.).

Generally, biofilm cells are more tolerant to antifungal treatments than planktonic cells and they can persist in the host even with a large influx of inflammatory cells and adaptive immune cells(2222 Hall-Stoodley L, Stoodley P, Kathju S, Høiby N, Moser C, Costerton JW, et al. Towards diagnostic guidelines for biofilm-associated infections. FEMS Immunol Med Microbiol. 2012;65(2):127-45.,2323 Silva S, Negri M, Henriques M, Oliveira R, Williams DW, Azeredo J. Adherence and biofilm formation of non-Candida albicans Candida species. Trends Microbiol. 2011;19(5):241-7.). In the literature, biofilm producing Candida spp. have been associated with greater mortality rates when compared to biofilm non-producing strains(2323 Silva S, Negri M, Henriques M, Oliveira R, Williams DW, Azeredo J. Adherence and biofilm formation of non-Candida albicans Candida species. Trends Microbiol. 2011;19(5):241-7.).

It is significant that C. krusei biofilms have the highest intensity of metabolic activities considering the presence of non-albicans strains of Candida spp., which are usually associated with changes in the antifungal susceptibility over a period of time; this pattern has been observed to change across the world with the expansion of the use of antifungal agents(2424 Ko JH, Jung DS, Lee JY, Kim HA, Ryu SY, Jung SI, et al. Changing epidemiology of non-albicans candidemia in Korea. J Infect Chemother. 2019;25(5):388-91.).

Behavioral changes in a biofilm formed by the same species in relation to different topographies and substrates in terms of formation and maturation(2525 Suzuki LC. Desenvolvimento de biofilme formado por Candida albicans in vitro para estudo do efeito fotodinâmico [tese]. São Paulo: Universidade de São Paulo; 2009.) have been rectified by the present study. However, although our results are significant, further studies are necessary to better explain the differences between these strains. Thus, it is expected to prevent biofilm formation on contact lenses surfaces, either by manipulating their hydrophobicity/hy­drophilic relationship, by assessing the antibiofilm potential of compounds present in multipurpose solutions, and/or, mainly, by reinforcing patients to become aware of the need for correct contact lens handling.

  • Funding: This study received no specific financial support.
  • Approved by the following research ethics committee: Universidade Federal de Alfenas (CAAE 68040317.8.0000.5142).

REFERENCES

  • 1
    Moriyama AS, Hofling-Lima AL. Contact lens-associated microbial keratitis. Arq Bras Oftalmol. 2008;71(6 Suppl):32-6.
  • 2
    Imamura Y, Chandra J, Mukherjee PK, Lattif AA, Szczotka-Flynn LB, Pearlman E, et al. Fusarium and Candida albicans biofilms on soft contact lenses: model development, influence of lens type, and susceptibility to lens care solutions. Antimicrob Agents Chemother. 2008;52(1):171-82.
  • 3
    Cardoso B. Produção de biofilme e perfil de suscetibilidade a antifúngicos de isolados de Candida spp. em episódios de candidemia no Hospital das Clínicas da FMRP-USP [tese]. Ribeirão Preto: Universidade de São Paulo; 2017.
  • 4
    Ramage G, VandeWalle K, Bachmann SP, Wickes BL, López-Ribot JL. In vitro pharmacodynamic properties of three antifungal agents against preformed Candida albicans biofilms determined by time-kill studies. Antimicrob Agents Chemother. 2002;46(11):3634-6.
  • 5
    De Oliveira PR, Resende SM, De Oiveira FC, De Oliveira AC. Ceratite fúngica. Arq Bras Oftalmol. 2001;64(1):75-9.
  • 6
    Franks WA, Adams GG, Dart JK, Minassian D. Relative risks of different types of contact lenses. BMJ. 1988 Aug 20-27;297(6647):524-5.
  • 7
    Dart JK, Stapleton F, Minassian D, Dart JK. Contact lenses and other risk factors in microbial keratitis. Lancet. 1991;338(8768):650-3.
  • 8
    Ramage G, Vande Walle K, Wickes BL, López-Ribot JL. Standardized method for in vitro antifungal susceptibility testing of Candida albicans biofilms. Antimicrob Agents Chemother. 2001;45(9):2475-9.
  • 9
    Melo AS, Bizerra FC, Freymüller E, Arthington-Skaggs BA, Colombo AL. Biofilm production and evaluation of antifungal susceptibility amongst clinical Candida spp. isolates, including strains of the Candida parapsilosis complex. Med Mycol. 2011;49(3):253-62.
  • 10
    Naves P, del Prado G, Huelves L, Gracia M, Ruiz V, Blanco J, et al. Correlation between virulence factors and in vitro biofilm formation by Escherichia coli strains. Microb Pathog. 2008;45(2):86-91.
  • 11
    Moragues MD, Omaetxebarria MJ, Elguezabal N, Sevilla MJ, Conti S, Polonelli L, et al. A monoclonal antibody directed against a Candida albicans cell wall mannoprotein exerts three anti-C. albicans activities. Infect Immun. 2003;71(9):5273-9.
  • 12
    Naglik JR, Challacombe SJ, Hube B. Candida albicans secreted aspartyl proteinases in virulence and pathogenesis. Microbiol Mol Biol Rev. 2003;67(3):400-28.
  • 13
    Lyon JP, dos Santos FV, de Moraes PC, Moreira LM. Inhibition of virulence factors of Candida spp. by different surfactants. Mycopathologia. 2011;171(2):93-101.
  • 14
    Bôas VT, Almeida Júnior GC, Almeida MT, Gonçalves MS, Coelho LF. Microbiological analysis of contact lens cases: impact of the hospital environment. Arq Bras Oftalmol. 2018;81(5):371-5.
  • 15
    Da Silva AR. Biofilmes e Lentes de Contato [tese]. Porto: Universidade Fernando Pessoa; 2012.
  • 16
    Rodriguez EJ. Hidrofobicidade superficial e colonização de Candida albicans sobre resina acrílica termopolimerizável para confecção de bases de próteses totais após desinfecção química [tese]. Bauru: Universidade de São Paulo; 2009.
  • 17
    Pathak AK, Sharma S, Shrivastva P. Multi-species biofilm of Candida albicans and non-Candida albicans Candida species on acrylic substrate. J Appl Oral Sci. 2012;20(1):70-5.
  • 18
    Rossoni RD, Barros PP, Freire F, Santos JD, Jorge AO, Junqueira JC. Study of Microbial Interaction Formed by "Candida krusei" and "Candida glabrata": "In Vitro" and "In Vivo" Studies. Braz Dent J. 2017;28(6):669-74.
  • 19
    Ferreira AV, Prado CG, Carvalho RR, Dias KS, Dias AL. Candida albicans and non-C. albicans Candida species: comparison of biofilm production and metabolic activity in biofilms, and putative virulence properties of isolates from hospital environments and infections. Mycopathologia. 2013;175(3-4):265-72.
  • 20
    Liu Y, Tay JH. Metabolic response of biofilm to shear stress in fixed-film culture. J Appl Microbiol. 2001;90(3):337-42.
  • 21
    Bester E, Kroukamp O, Wolfaardt GM, Boonzaaier L, Liss SN. Metabolic differentiation in biofilms as indicated by carbon dioxide production rates. Appl Environ Microbiol. 2010;76(4):1189-97.
  • 22
    Hall-Stoodley L, Stoodley P, Kathju S, Høiby N, Moser C, Costerton JW, et al. Towards diagnostic guidelines for biofilm-associated infections. FEMS Immunol Med Microbiol. 2012;65(2):127-45.
  • 23
    Silva S, Negri M, Henriques M, Oliveira R, Williams DW, Azeredo J. Adherence and biofilm formation of non-Candida albicans Candida species. Trends Microbiol. 2011;19(5):241-7.
  • 24
    Ko JH, Jung DS, Lee JY, Kim HA, Ryu SY, Jung SI, et al. Changing epidemiology of non-albicans candidemia in Korea. J Infect Chemother. 2019;25(5):388-91.
  • 25
    Suzuki LC. Desenvolvimento de biofilme formado por Candida albicans in vitro para estudo do efeito fotodinâmico [tese]. São Paulo: Universidade de São Paulo; 2009.

Publication Dates

  • Publication in this collection
    10 Sept 2021
  • Date of issue
    May-Jun 2022

History

  • Received
    10 June 2020
  • Accepted
    12 Oct 2020
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