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Photodynamic action of protoporphyrin IX derivatives on Trichophyton rubrum* * Study performed at Laboratório de Microbiologia of the Universidade Camilo Castelo Branco (Unicastelo) and Universidade de São Paulo (USP) – São Paulo (SP), Brazil.

Abstract:

BACKGROUND:

Dermatophytes are filamentous keratinophilic fungi. Trichophyton rubrum is a prevalent infectious agent in tineas and other skin diseases. Drug therapy is considered to be limited in the treatment of such infections, mainly due to low accessibility of the drug to the tissue attacked and development of antifungal resistance in these microorganisms. In this context, Photodynamic Therapy is presented as an alternative.

OBJECTIVE:

Evaluate, in vitro, the photodynamic activity of four derivatives of Protoporphyrin IX by irradiation with LED 400 nm in T. rubrum.

METHOD:

Assays were subjected to irradiation by twelve cycles of ten minutes at five minute intervals.

RESULT:

Photodynamic action appeared as effective with total elimination of UFCs from the second irradiation cycle.

CONCLUSION:

Studies show that the photodynamic activity on Trichophyton rubrum relates to a suitable embodiment of the photosensitizer, which can be maximized by functionalization of peripheral groups of the porphyrinic ring.

Keywords:
Photosensitizing agents; Tinea; Trichophyton

INTRODUCTION

Dermatophytes are filamentous keratinophilic fungi, imperfect, taxonomically related, which presents capacity to invade keratinized tissues of men and animals, causing dermatophytosis or tinea, a disease with a contagious nature and high worldwide prevalence.11 Farias MR, Condas LAZ, Ramalho F, Bier D, Muro MD, Pimpão CT. Avaliação do estado de carreador assintomático de fungos dermatofiticos em felinos (Felis catus- Linnaeus, 1793) destinados à doação em centros de controle de zoonoses e sociedades protetoras de animais. Vet Zootec. 2011;18:306-12. These fungi have an enzymatic system essential to metabolize keratin, used as a substrate for obtaining nutrients and energy. Dermatophytes are classified into three kinds: Microsporum, Trichophyton and Epidermophyton, and Trichophyton rubrum (T. rubrum) is the prevalent infectious agent in tineas and other skin diseases, which may be persistent.22 Quinn PJ, Markey BK, Leonard FC, Fitzpatrick ES, Fanning S, Hartigan PJ. Veterinary microbiology and microbial disease. Can Vet J. 2003;44:986.

3 Tortora GJ, Funke BR, Case CL. Microbiologia. 10 ed. Porto Alegre: Artmed; 2012. p.934.

4 Omero C, Dror Y, Freeman A. Trichoderma spp. antagonism to the dermatophyte Trichophyton rubrum: implications in treatment of onychomycosis. Mycopathologia. 2004;158:173-80.
-55 Smijs TG, Bouwstra JA, Talebi M, Pavel S. Investigation of conditions involved in the susceptibility of the dermatophyte Trichophyton rubrum to photodynamic treatment. J Antimicrob Chemother. 2007;60:750-9.

Infections caused by T. rubrum in humans are associated with failure of the host’s immune response, or to the pathogen’s ability to evade the defense system, thus remaining in the superficial skin layers.66 Peres NT, Maranhão FC, Rossi A, Martinez-Rossi NM. Dermatophytes: host-pathogen interaction and antifungal resistance. An Bras Dermatol. 2010;85:657-67. Other factors directly related to T. rubrum are the cell wall components, such as galactomannans, which may present immunosuppressive effects, and the membrane transport proteins, which are important virulence factors that ensure successful colonization in propitious environments. 77 Nir-Paz R, Elinav H, Pierard GE, Walker D, Maly A, Shapiro M, et al. Deep infection by Trichophyton rubrum in an immunocompromised patient. J Clin Microbiol. 2003;41:5298-301.,88 Maranhão FC, Paião FG, Fachin AL, Martinez-Rossi NM. Membrane transporter proteins are involved in Trichophyton rubrum pathogenesis. J Med Microbiol. 2009;58:163-8. In the infection process, the cell wall of the dermatophyte plays an essential role, and is therefore a target to antifungal. 99 Borgers M, Degreef H, Cauwenbergh G. Fungal infections of the skin: infection process and antimycotic therapy. Curr Drug Targets. 2005;6:849-62.

Tinea treatment, in general, consists of fungicidal or fungistatic drugs of topical or systemic use, which should act specifically against the pathogenic agent, thus avoiding adverse events to the host.66 Peres NT, Maranhão FC, Rossi A, Martinez-Rossi NM. Dermatophytes: host-pathogen interaction and antifungal resistance. An Bras Dermatol. 2010;85:657-67. Topical treatment is satisfactory when lesions are mild. However, in the case of persistent tineas, systemic therapy is employed. In these cases it is necessary to take into consideration the risks of drug interactions and hepatotoxicity, which can be serious.55 Smijs TG, Bouwstra JA, Talebi M, Pavel S. Investigation of conditions involved in the susceptibility of the dermatophyte Trichophyton rubrum to photodynamic treatment. J Antimicrob Chemother. 2007;60:750-9. These treatment options frequently result in failure, since the commonly used antifungal agents have limited cellular targets. Moreover, emergence of resistant strains occurs, concomitant with high costs treatments for long periods, with possible adverse events, as well as drug application difficulty and disease relapses after discontinuation of antifungal therapy.66 Peres NT, Maranhão FC, Rossi A, Martinez-Rossi NM. Dermatophytes: host-pathogen interaction and antifungal resistance. An Bras Dermatol. 2010;85:657-67.,1010 Girois SB, Chapuis F, Decullier E, Revol BG. Adverse effects of antifungal therapies in invasive fungal infections: review and meta-analysis. Eur J Clin Microbiol Infect Dis. 2006;25:138-49.

Difficulties in the treatment of tinea by conventional methods have led to the search for safer, more efficient, easily achievable and cost-effective antifungal therapy. While some drugs produce effects only to metabolically active and/or just fungiostatic parasites, photodynamic therapy (PDT) consistis in the destruction of living tissue by visible light in the presence of a photosensitizer (PS) and molecular oxygen. PDT causes demise both in metabolically active cells, such as yeast and hyphae, as well as in resistant forms, such as conidia.1111 Rodrigues GB, Ferreira LK, Wainwright M, Braga GU. Susceptibilities of the dermatophytes Trichophyton mentagrophytes and T. rubrum microconidia to photodynamic antimicrobial chemotherapy with novel phenothiazinium photosensitizers and red light. J Photochem Photobiol B. 2012;116:89-94.

After the discovery of penicillin, antibiotics have been occupying a central role in combating microorganisms. 1212 Raab O. Action of fluorescent materials on infusorial substances. Z Biol. 1900;39:524-46.,1313 Pereira AL, Pita JR. Alexander Fleming (1881-1955): da descoberta da penicilina (1928) ao prêmio Nobel (1945). Rev FLUP. 2005;6:129-51. Since then, studies with PDT were directed to other therapies, such as cancer. This was due to the fact that antibiotics have been presented as the ultimate solution to combat microorganisms. After the discovery of development of microorganisms resistance to antibiotics, PDT rises again as an alternative. This therapy has been studied in the fight against Trichophyton rubrum and other dermatophytes. 1414 Vural E, Winfield HL, Shingleton AW, Horn TD, Shafirstein G. The effects of laser irradiation on Trichophyton rubrum growth. Lasers Med Sci. 2008;23:349-53.,1515 Becker C, Bershow A. Lasers and photodynamic therapy in the treatment of onychomycosis: a review of the literature. Dermatol Online J. 2013;19:19611. It was also shown that PDT activity is related to the type of PS, the intensity of the incident radiation and the pH of the medium.55 Smijs TG, Bouwstra JA, Talebi M, Pavel S. Investigation of conditions involved in the susceptibility of the dermatophyte Trichophyton rubrum to photodynamic treatment. J Antimicrob Chemother. 2007;60:750-9. PDT, when applied under appropriate conditions, can provide photo oxidation of hyphae and conidia and total elimination of these patogens. 55 Smijs TG, Bouwstra JA, Talebi M, Pavel S. Investigation of conditions involved in the susceptibility of the dermatophyte Trichophyton rubrum to photodynamic treatment. J Antimicrob Chemother. 2007;60:750-9. However, the therapy development demands studies that provide greater selectivity and hence greater activity in combating pathogenic microorganisms.

In this study we assessed the activity of PS derived from protoporphyrin IX, aiming at incorporating strategies to fight Trichophyton rubrum.

METHODS

Biological material:Trichophyton rubrum ATCC (American Type Culture Collection) 28188 strain was used, which was grown for seven days on Sabouraud Dextrose Agar (SDA, OXOID®), using incubation at 28°C.

Photosensitizers: Tested PS (Pp IX dimethyl ester, PpNpNA and PpNpNI) was obtained by derivatization of protoporphyrin IX, through procedure analogue to the one described in the literature. Structural characterization was performed by mass spectrometry and nuclear magnetic resonance of hydrogen, by one-dimensional and two-dimensional techniques at 300 MHz and 500 MHz. As reference, Hp IX was tested, obtained from Sigma-Aldrich. For the tests, PS were dissolved in dimethylsulfoxide (DMSO) at a concentration of 1 mg/mL-1, and subsequently diluted in NaCl solution (0.5%) for the test concentration [20µM].

In vitro test:T. rubrum ATCC 28188 was cultured for 7 days, amid tryptone soya broth (TSB OX-OID®), centrifuged (4000 rpm) for 5 minutes and the supernatant was discarded. The material was resuspended in sterile NaCl (0.5%) and subjected to further centrifugation. This procedure was repeated 5 times, in order to eliminate the components of the culture medium. At the end of the cycle, the material was resuspended in 1 ml of sterile NaCl (0.5%) and stirred vigorously for 1 minute. Then, 9 ml of NaCl was added and the resulting solution was subjected to stirring for 1 minute and adjusted to a McFarland standard tube 0.5, which corresponds to approximately 1.5 x 108 CFU mL-1; this solution was diluted 100 times for the tests, resulting in concentration of 1.5 x 106 CFU ml -1.

Antifungal activity: Experimental design was completely randomized, comprising 6 treatments: 1) control without application of light and PS; 2) application of light; 3) PS (Hp IX, Pp IX Dimethyl Ester, PpNpNA, PpNpNI,) and irradiated LED ≈ 400 nm. The experiment was conducted in vitro in from November to December 2013 and January 2014. For the tests, 1,1 mL of the fungal suspension and 0,05 mL of the PS solution were added to a centrifuge tube with 2 mL capacity, where it was incubated for 15 minutes at room temperature and protected from light. After incubation, samples were subjected to 12 cycles of 10 minutes of irradiation with LED at 400 nm and 21 mW power. Cycles were interspersed with a period of 5 minutes. At each cycle, 0,05 mL was removed and transferred to a petri dish containing Sabourad Dextrose Agar. The medium was uniformly distributed with the aid of sterile glass beads, and the plates were incubated at 28°C for 7 days. After this time, colony count was performed for the assessment of photodynamic activity against T. rubrum. The whole procedure was performed in triplicate.

Incorporation Studies: The study was carried out by incorporation of fluorescence microscopy. To obtain images, T. rubrum was grown in TSB medium at room temperature as described above.

Preparation of the sample: In a 2 ml capacity centrifuge tube, 1 ml of suspension at a concentration of 1.5 x 106 CFU mL-1 and 100 µL of PS solution were added, at the concentration of 20µM, which was prepared in saline NaCl 0.5%. The sample was homogenized and incubated for 15 minutes. For the preparation of the blades, an aliquot was removed from the sample, placed on slides and coated with cover slips. Images were obtained in a fluorescence microscope, Zeiss Axiovert 200, with objective lens of 40 X. The excitement was held in blue (470 ± 20 nm) and green (546 ± 12nm), and the emission was recorded for the higher λ 515 nm and 590 nm, respectively. Images were recorded on a Canon Power Shot G10 camera.

Statistical analysis: Data were tabulated and submitted to analysis of variance (ANOVA) and means were compared using Bonferroni test with 5% significance level.

RESULTS

Collection of photosensitizers: PS were obtained by derivatization of protoporphyrin IX via acid chloride and nucleophilic substitution with a corresponding amine or by Fisher esterification. Structural characterization, as well as the incomes, were similar to that described by Uchôa et al. 1616 Uchoa AF, Oliveira CS, Baptista MS. Relationship between structure and photoactivity of porphyrins derived from protoporphyrin IX. J Porphyrins Phthalocyanines. 2010;14:832-45. Compounds structures are shown in figure 1.

Figure 1
Chemical structure of photosensitizers derived from protoporphyrin IX

Photodynamic activity in Trichophyton rubrum: Photodynamic action of Protoporphyrin IX derivatives on Trichophyton rubrum ATCC 28188 radiated at 400 nm is presented in table 1.

Table 1
Photodynamic activity of protoporphyrin IX derivates on Trichophyton rubrum ATCC 28188; values expressed by the arithmetic mean of colony forming units

Table 1 shows that the control (CT) presented a mean growth between 3206 and 3370 CFU. When the sample was irradiated (L+), a significant decrease was observed, and this decrease evolved over time for the first 6 cycles. In the tests with irradiation in the presence of a PS, a marked reduction from the first irradiation cycle was observed.

For a better visualization, results were transformed to percentage of reduction and are shown in figure 2, thereby providing a better asssess between the antifungal potential of each photosensitizer.

Figure 2
Percentage of reduction of T. rubrum (A) irradiated with blue LED (B) by photodynamic action

Figure 2A shows the percentage of reduction in CFUs of T. rubrum by irradiation at 400 nm. In this assay, a 35% reduction of CFU of T. rubrum was observed for the first irradiation cycle. This decrease was intensified for the first 6 cycles, presenting a plateau from the sixth cycle, in which there was a 50% reduction (IC50). For hiher times, significant differences between the sixth and the following cycles were not observed.

Incorporation of PS in T. rubrum was observed by fluorescence microscopy, in which fluorescence was observed in red (≈ 660 nm), referring to emission of Pp IX derivatives. This emission was observed in hyphae and conidia, being perfectly differentiated from natural fluorescence of the species, which emits 450 nm when irradiated in ultraviolet.1717 Gupta AK, Zaman M, Singh J. Diagnosis of Trichophyton rubrum from onychomycotic nail samples using polymerase chain reaction and calcofluor white microscopy. J Am Podiatr Med Assoc. 2008;98:224-8. Figure 3 shows the fluorescence by emission of endogenous fluorophores and Pp IX derivatives incorporated in T. rubrum hyphae.

Figure 3
Image (A, C) showing Trichophyton rubrum ATCC 28188 fluorescence, and (B, D) image of fluorescence of the photosensitizers derivative from protoporphyrin IX incorporated in Trichophyton rubrum ATCC 28188. Vizualized in fluorescence microscope Zeiss Axiovert 200, using 100X objective lens

DISCUSSION

Microorganisms reduction by irradiation is widely known. 1818 Yoshimura M, Namura S, Akamatsu H, Horio T. Antimicrobial effects of phototherapy and photochemotherapy in vivo and in vitro. Br J Dermatol. 1996;135:528-32. The species may be eliminated by ultraviolet irradiation, classic disinfection method, since irradiation in these levels of energy leads to destruction of biomolecules by rupture of chemical bonds.1919 Boyce RP, Howard-Flanders P. Genetic control of DNA breakdown and repair in E. Coli K-12 treated with mitomycin C or ultraviolet light. Z Vererbungsl. 1964;95:345-50. However, energy emitted at 400 nm is not considered sufficient to provide this degradation process in biomolecules. Accordingly, the destruction of biological material by irradiation at 400 nm is attributed to photosensitization process by the presence of endogenous PS. For the tests, in which T. rubrum was irradiated in the presence of PS, we observed a reduction ratio higher than 96% of CFU for all tested PS.

In the assays using hematoporphyrin XI (HP IX), a classic PS, a 99% reduction of CFU from the first irradiation cycle was observed. This activity had a positive performance for the first 3 cycles, remaining stable for the following clycles, thus indicating that the compound reached the plateau without achieving the complete elimination of CFUs of T. rubrum. This limitation may be attributed to a possible saturation of the membrane. 2020 Santus R, Kohen C, Kohen E, Reyftmann JP, Morliere P, Dubertret L, et al. Permeation of lysosomal membranes in the course of photosensitization with methylene blue and hematoporphyrin: study by cellular microspectrofluorometry. Photochem Photobiol. 1983;38:71-7. Protoporphyrin dimethyl ester (Pp dimethyl ester IX) was the PS with lower reduction rate for the first cycle. However, a progressive evolution was observed over time, achieving, asymptotically, total reduction. It was observed that, after the third cycle, occurred a reduction greater than that presented for Hp IX. This superiority was attributed to the incorporation in the membrane, followed by enzymatic hydrolysis of the ester groups. 2121 Eigen M. Proton Transfer, Acid-base Catalysis, and Enzymatic Hydrolysis. PART I: Elementary processes. Angewandte Chemi. 1964;3:1-19. This process provides improved internalization of the photosensitizer, whereas, in ester form, it presents greater interaction with lipophilic systems. Thus, after PS reaches the membrane, it will undergo hydrolysis, being conducted to the interior of the cells, resulting in better integration and consequently higher activity over time.2222 Bermúdez Moretti M, Correa García S, Perotti C, Batlle A, Casas A. Delta-Aminolevulinic acid transport in murine mammary adenocarcinoma cells is mediated by beta transporters. Br J Cancer. 2002;87:471-4.

PpNpNA and PpNpNI compounds presented greater activity (Figure 2). PpNpNA showed complete elimination of T. rubrum CFUs from the third irradiation cycle, while for PpNpNI, total elimination occurred from the second cycle. The superior activity of these compounds was attributed to the amphiphilic character and to the asymmetry.1616 Uchoa AF, Oliveira CS, Baptista MS. Relationship between structure and photoactivity of porphyrins derived from protoporphyrin IX. J Porphyrins Phthalocyanines. 2010;14:832-45. These characteristics enable the compounds to cross the membrane and internalize in the microorganisms, as observed in HeLas cells. In addition to the amphiphilicity and asymmetry, PpNpNA presents two groups of tertiary amine with pKa ≈ 10 on a same face of the molecule. Thus, it is expected that these compounds are partially protonated and attracted by biomolecules that have negative charges, by electrostatic forces. 1616 Uchoa AF, Oliveira CS, Baptista MS. Relationship between structure and photoactivity of porphyrins derived from protoporphyrin IX. J Porphyrins Phthalocyanines. 2010;14:832-45. But PpNpNI is a permanent di-cationitac, permanently susceptible to electrostatic attraction with anionic structures at any level of pH.

When comparing PS structures, it is observed that protoporphyrin IX was changed only in their peripheral groups, not undergoing changes in the chromophore and, consequently, not undergoing changes in their photophysical properties. Accordingly, changes enabled the incorporation of PS, keeping the photooxidative potential of derivatives and, consequently, T. rubrum activity. In figure 3, we can observe, by the chhromophore fluorescence, that the compounds were perfectly incorporated, resulting in photooxidative damage when irradiated at 400 nm, region where these compounds present the band with the highest absorption intensity, the Soret band.

Fluorescence at 660 nm proves the incorporation and internalization of PS in T. rubrum and shows that the elimination of the species occurred due to photoinduced process triggered near the chromophore, since these processes are initiated by protons or electrons tranference, radical reactions or electrophilic attack of singlet oxygen to membranes.2323 Weber G, Charitat T, Baptista MS, Uchoa AF, Pavani C, Junqueira HC, et al. Lipid oxidation induces structural changes in biomimetic membrane. Soft Matter. 2014;10:4241-7. Accordingly, it is necessary that the physicochemical properties of the photosensitizer and, consequently, its biodistribution, favors the incorporation in the parasite rather than in the host.2424 Kessel D, Woodburn k. Biodistribution of photosensitizing agentes. Int J Biochem. 1993;25:1377-83.,2525 Song D, Lindoso JA, Oyafuso LK, Kanashiro EH, Cardoso JL, Uchoa AF, et al. Photodynamic therapy using methylene blue to treat cutaneous leishmaniasis. Photomed Laser Surg. 2011;29:711-5.

Among the tested compounds, PpNpNA and PpNpNI were those that provided a greater incorporation and thus a higher activity in T. rubrum by affinity with biomolecules that have negative charges, such as glucosamine, glycoproteins and polysaccharides. 2626 Giavasis I. Bioactive fungal polysaccharides as potential functional ingredients in food and nutraceuticals. Curr Opin Biotechnol. 2014;26:162-73.

CONCLUSION

The studies presented show that the photodynamic activity on Trichophyton rubrum relates to an adequate incorporation of PS, which can be made possible by changes in the peripheral functional groups of the chromophore. This strategy eliminates the need for a incorporation vehicle. Esterification of Pp IX enables the incorporation by lipophilicity and prolongs the activity, due to the controlled hydrolysis process of ester groups. Moreover, amphiphilic and cationic strategy adopted in PS PpNpNI and PpNpNA enables greater incorporation in shorter time, maximizing the treatment by reducing the period of exposure to irradiation and lower therapeutic doses, and the di-quaternary ammonium (PpNpNI) compound presents more effective by being cationic at all pH levels.

  • Financial support: Fapesp, project Fotossensibilização nas ciências da vida, process number 12/50680-5 and REDOXOME - Center for Research on Redox Processes in Biomedicine. Process number 2013/07937-8.
  • *
    Study performed at Laboratório de Microbiologia of the Universidade Camilo Castelo Branco (Unicastelo) and Universidade de São Paulo (USP) – São Paulo (SP), Brazil.

REFERENCES

  • 1
    Farias MR, Condas LAZ, Ramalho F, Bier D, Muro MD, Pimpão CT. Avaliação do estado de carreador assintomático de fungos dermatofiticos em felinos (Felis catus- Linnaeus, 1793) destinados à doação em centros de controle de zoonoses e sociedades protetoras de animais. Vet Zootec. 2011;18:306-12.
  • 2
    Quinn PJ, Markey BK, Leonard FC, Fitzpatrick ES, Fanning S, Hartigan PJ. Veterinary microbiology and microbial disease. Can Vet J. 2003;44:986.
  • 3
    Tortora GJ, Funke BR, Case CL. Microbiologia. 10 ed. Porto Alegre: Artmed; 2012. p.934.
  • 4
    Omero C, Dror Y, Freeman A. Trichoderma spp. antagonism to the dermatophyte Trichophyton rubrum: implications in treatment of onychomycosis. Mycopathologia. 2004;158:173-80.
  • 5
    Smijs TG, Bouwstra JA, Talebi M, Pavel S. Investigation of conditions involved in the susceptibility of the dermatophyte Trichophyton rubrum to photodynamic treatment. J Antimicrob Chemother. 2007;60:750-9.
  • 6
    Peres NT, Maranhão FC, Rossi A, Martinez-Rossi NM. Dermatophytes: host-pathogen interaction and antifungal resistance. An Bras Dermatol. 2010;85:657-67.
  • 7
    Nir-Paz R, Elinav H, Pierard GE, Walker D, Maly A, Shapiro M, et al. Deep infection by Trichophyton rubrum in an immunocompromised patient. J Clin Microbiol. 2003;41:5298-301.
  • 8
    Maranhão FC, Paião FG, Fachin AL, Martinez-Rossi NM. Membrane transporter proteins are involved in Trichophyton rubrum pathogenesis. J Med Microbiol. 2009;58:163-8.
  • 9
    Borgers M, Degreef H, Cauwenbergh G. Fungal infections of the skin: infection process and antimycotic therapy. Curr Drug Targets. 2005;6:849-62.
  • 10
    Girois SB, Chapuis F, Decullier E, Revol BG. Adverse effects of antifungal therapies in invasive fungal infections: review and meta-analysis. Eur J Clin Microbiol Infect Dis. 2006;25:138-49.
  • 11
    Rodrigues GB, Ferreira LK, Wainwright M, Braga GU. Susceptibilities of the dermatophytes Trichophyton mentagrophytes and T. rubrum microconidia to photodynamic antimicrobial chemotherapy with novel phenothiazinium photosensitizers and red light. J Photochem Photobiol B. 2012;116:89-94.
  • 12
    Raab O. Action of fluorescent materials on infusorial substances. Z Biol. 1900;39:524-46.
  • 13
    Pereira AL, Pita JR. Alexander Fleming (1881-1955): da descoberta da penicilina (1928) ao prêmio Nobel (1945). Rev FLUP. 2005;6:129-51.
  • 14
    Vural E, Winfield HL, Shingleton AW, Horn TD, Shafirstein G. The effects of laser irradiation on Trichophyton rubrum growth. Lasers Med Sci. 2008;23:349-53.
  • 15
    Becker C, Bershow A. Lasers and photodynamic therapy in the treatment of onychomycosis: a review of the literature. Dermatol Online J. 2013;19:19611.
  • 16
    Uchoa AF, Oliveira CS, Baptista MS. Relationship between structure and photoactivity of porphyrins derived from protoporphyrin IX. J Porphyrins Phthalocyanines. 2010;14:832-45.
  • 17
    Gupta AK, Zaman M, Singh J. Diagnosis of Trichophyton rubrum from onychomycotic nail samples using polymerase chain reaction and calcofluor white microscopy. J Am Podiatr Med Assoc. 2008;98:224-8.
  • 18
    Yoshimura M, Namura S, Akamatsu H, Horio T. Antimicrobial effects of phototherapy and photochemotherapy in vivo and in vitro. Br J Dermatol. 1996;135:528-32.
  • 19
    Boyce RP, Howard-Flanders P. Genetic control of DNA breakdown and repair in E. Coli K-12 treated with mitomycin C or ultraviolet light. Z Vererbungsl. 1964;95:345-50.
  • 20
    Santus R, Kohen C, Kohen E, Reyftmann JP, Morliere P, Dubertret L, et al. Permeation of lysosomal membranes in the course of photosensitization with methylene blue and hematoporphyrin: study by cellular microspectrofluorometry. Photochem Photobiol. 1983;38:71-7.
  • 21
    Eigen M. Proton Transfer, Acid-base Catalysis, and Enzymatic Hydrolysis. PART I: Elementary processes. Angewandte Chemi. 1964;3:1-19.
  • 22
    Bermúdez Moretti M, Correa García S, Perotti C, Batlle A, Casas A. Delta-Aminolevulinic acid transport in murine mammary adenocarcinoma cells is mediated by beta transporters. Br J Cancer. 2002;87:471-4.
  • 23
    Weber G, Charitat T, Baptista MS, Uchoa AF, Pavani C, Junqueira HC, et al. Lipid oxidation induces structural changes in biomimetic membrane. Soft Matter. 2014;10:4241-7.
  • 24
    Kessel D, Woodburn k. Biodistribution of photosensitizing agentes. Int J Biochem. 1993;25:1377-83.
  • 25
    Song D, Lindoso JA, Oyafuso LK, Kanashiro EH, Cardoso JL, Uchoa AF, et al. Photodynamic therapy using methylene blue to treat cutaneous leishmaniasis. Photomed Laser Surg. 2011;29:711-5.
  • 26
    Giavasis I. Bioactive fungal polysaccharides as potential functional ingredients in food and nutraceuticals. Curr Opin Biotechnol. 2014;26:162-73.

Publication Dates

  • Publication in this collection
    Mar-Apr 2016

History

  • Received
    22 Apr 2014
  • Accepted
    26 Apr 2015
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