姜黄素介导的抗菌光动力疗法在口腔念珠菌病小鼠模型上的应用
Summary
该方案描述了抗菌光动力疗法(aPDT)在口腔念珠菌病小鼠模型中的应用。使用姜黄素和蓝色LED灯的水溶性混合物进行aPDT。
Abstract
抗菌光动力疗法 (aPDT) 已 在体外进行了广泛的研究,感染的临床前动物模型适用于在临床试验之前评估替代疗法。本研究描述了 aPDT 在口腔念珠菌病小鼠模型中的疗效。40只小鼠通过皮下注射泼尼松龙进行免疫抑制,并使用先前浸泡在 白色念珠菌 细胞悬浮液中的口腔拭子接种它们的舌头。在实验过程中 ,四 环素通过饮用水给药。真菌接种5天后,将小鼠随机分为8组;第九组未经治疗的未感染小鼠作为阴性对照(n = 5)。用蓝色LED灯(89.2 mW /cm 2;~455 nm)和无光(分别为C + + 和 C + L- 组)测试姜黄素混合物的三种浓度(20 μM、40 μM 和 80 μM)。仅光照 (C-L+)、不治疗 (C-L-) 和无感染动物被评估为对照。使用 Welch 方差分析和 Games-Howell 检验 (α = 0.05) 分析数据。口腔念珠菌病在所有受感染的动物中都已确定,并通过舌背上的特征性白斑或假膜在宏观上可视化。组织病理学切片证实,在C-L-组中,酵母和细丝的存在仅限于上皮的角化层,并且在从使用40μM或80μM姜黄素进行aPDT的小鼠获得的图像中,真菌细胞的存在在视觉上减少。与C-L-组相比,由80μM姜黄素介导的aPDT促进了2.47 log10 的菌落计数减少(p = 0.008)。所有其他组的菌落数量均无统计学意义减少,包括光敏剂(C+L-)或光敏(C-L+)组。姜黄素介导的aPDT减少了小鼠舌头的真菌负荷。
Introduction
口腔念珠菌病(OC)是口腔的主要真菌感染;它是由 念珠菌 属的过度生长引起的。OC 的诱发因素包括内分泌功能障碍、使用广谱抗生素、放疗和化疗、营养缺乏、口干症(唾液流量低)、使用假牙、卫生条件差,尤其是免疫抑制1。在 念珠菌 物种中, 白色念珠菌 是最普遍和最致命的一种;它被发现为人体内的共生物种和机会性病原体。 白色念珠菌 有能力将其形态从共生酵母(胚孔)转变为致病丝(菌丝和假菌丝)2。丝状形式,尤其是菌丝,可以通过内吞作用或主动渗透侵入宿主上皮,引起感染3. 白色念珠 菌的其他毒力因子包括粘附、生物膜形成以及脂解和水解酶和毒素的分泌,例如脂肪酶、磷脂酶、蛋白酶和念珠菌溶血素4。
OC治疗包括使用抗真菌药物,特别是局部多烯和唑类(制霉菌素和咪康唑)5。然而,它们仅显示出短期疗效,并且复发频繁。此外,抗真菌药物的过度使用引发了抗真菌药物耐药性发展和传播的问题6。因此,需要替代疗法,例如抗菌光动力疗法 (aPDT),它在氧气存在下将光敏剂 (PS) 和适当波长(与 PS 吸收相同)的光结合在一起。PS与细胞结合或被细胞吸收,当被光激活时,会产生对致敏细胞有毒的活性氧(ROS)7。
在aPDT中,使用的光敏剂(PS)之一是姜黄素(CUR),这是一种从姜黄植物(Curcuma longa L.)的根茎中提取的天然化合物。姜黄素具有多种治疗特性,包括抗炎、抗氧化、抗癌和抗菌能力 8,9。先前的一项研究发现,利用 CUR 的 aPDT 有效地减少了口腔念珠菌病小鼠模型中的白色念珠菌,而不会对宿主的组织造成任何伤害10。CUR是从姜黄中提取的主要姜黄素,但其他多酚,如脱甲氧基姜黄素和双脱甲氧基姜黄素,也存在于这种植物中。姜黄素介导的 aPDT 对导管中生长的金黄色葡萄球菌的生物膜具有抗菌活性11。然而,据我们所知,其对白色念珠菌的抗真菌活性仍不清楚。因此,在这项研究中,我们评估了在 OC 小鼠模型中由姜黄素盐介导的针对白色念珠菌的 aPDT。
Protocol
使用小鼠的研究方案已获得UNESP阿拉拉夸拉牙科学院的动物使用伦理委员会(案例编号05/2008和09/2020)的批准。 白色念珠菌 (ATCC 90028)作为参比菌株。本研究使用体重范围为 20-30 g 的六周龄雌性瑞士小鼠 (n = 45)。这些动物由圣保罗州立大学、UNESP、Botucatu提供。 1. PS的制备和aPDT光源的选择 根据要测试的物质的规格准备PS。注:在这项研究中,?…
Representative Results
OC的小鼠模型显示所有感染小鼠的舌头上有典型的白斑和假膜(图4A)。从C-L-动物中回收 的白色念珠菌 证实了该微生物的组织定植(值范围为1.62 x 104 至4.80 x 105 CFU/mL)。正如预期的那样,来自NCtr组的动物在取样后没有表现出任何组织改变或菌落生长(图4B)。 当在80μM下使用姜黄素进行光敏化时,aPDT降低?…
Discussion
白色念珠菌与免疫功能低下、糖尿病、长期使用抗生素和口腔卫生不良的个体的口腔和食管感染有关 1,3。人类传染病的研究需要进行体外和体内研究,然后才能安全准确地设计临床试验。本研究描述了一种建立OC小鼠模型的方法,可用于评估白色念珠菌口腔感染的发病机制和抗真菌方法的疗效15,16,17,18,19。<su…
Acknowledgements
作者感谢FAPESP(圣保罗研究基金会,过程编号FAPESP #2013/07276-1(CePID CePOF)和2008/00601-6的财政支持。我们还要感谢 Ana Paula Silva 博士提供有关 CUR 基水溶性盐的信息。
Materials
| C. albicans | ATCC (Rockville, Md, USA) | 90028 | Used to prepare the Candida inoculum |
| Centrifuge | Eppendorf Centrifuge 5804/5804R,B. Braun, Melsungen, Hesse, Germany | 022628146 (NA) | Used to prepare the Candida inoculum |
| Chlorpromazine chloride 2 mg/mL | Compounding pharmacy, Araraquara, SP, Brazil | - | Used to sedate animals during candida inoculation |
| Curcumin-based water-soluble salt | PDTPharma, Cravinhos, Brazil | - | Consisting of 53.4% of natural curcumin, and 46.6% of other curcuminoids (demethoxycurcumin and bis-demethoxycurcumin). Prepared in water and N-MethylD-Glucamine (final average molecular weight of 730.32 g.mol−1) |
| Digital colony counter | CP 600 Plus, Phoenix Ind Com Equipamentos Científicos Ltda, Araraquara, SP, Brazil | - | Used to count colonies on agar plates |
| Extruded mouse chow | Benelab food, Industry Qualy Animal Nutrition and Commerce Ltda., Lindóia, São Paulo State, Brazil. | - | Used for the feeding of the mice |
| Ketamine Hydrochloride 10% | Ketamina Agener, União Química Farmacêutica Nacional S/A, Embu-Guaçu, SP, Brazil | - | Used to anesthetize animals before treatments and for euthanasia |
| Light-emitting diode handpiece (prototype) | Instituto de Física de São Carlos, University of São Paulo, São Carlos, SP, Brazil | - | Fabricated with LXHL-PR09, Luxeon III Emitter, Lumileds Lighting, San Jose, California, USA |
| Methylprednisolone acetate 40 mg | DEPO-MEDROL, Pfizer, New York | - | Used as an immunosuppressant |
| Microtome | Leica Microsystems, Bannockburn, IL, USA | SM2500 | Used to cut the serial sections of the tongues |
| Propylene boxes (cages housing) H13 x L20 x D30 cm | Bonther Equipaments, Ribeirão Preto, SP, Brazil | - | Used to keep the animals throughout the experimental period |
| Sabouraud Dextrose Agar with Chloramphenicol | HiMedia, Mumbai, India | MM1067-500G | Culture medium for yeast growth (agar) |
| Spectrophotometer | Spectrophotometer Kasvi K37-VIS , São José dos Pinhais, PR, Brazil | K37-VIS | Used to standardize the inoculum concentration |
| Tetracycline hydrochloride | Compounding pharmacy, Araraquara, SP, Brazil | - | Antibiotic given to induce oral dysbiosis |
| Wood shavings | J.R. Wood Shavings, Comerce of Sawdust Ltda., Conchal, São Paulo State, Brazil | - | Used for floor covering inside the housing boxes |
| Xylazine 2% | Calmiun, União Química Farmacêutica Nacional S/A, Embu-Guaçu, SP, Brazil | - | Used in combination with ketamine for anesthesia |
| Yeast Nitrogen Broth | Difco, InterLab, Detroit, MI, USA | DF0919-07-3 | Culture medium for yeast growth (broth) |
| Yeast Peptone Dextrose Broth | NutriSelect Basic, Sigma Aldrich | Y1375 | Culture medium for maintaining the strains at -80°C and grow |
References
- Vila, T., Sultan, A. S., Montelongo-Jauregui, D., Jabra-Rizk, M. A. Oral candidiasis: a disease of opportunity. Journal of fungi (Basel, Switzerland). 6 (1), 15 (2020).
- Sudbery, P. E. Growth of Candida albicans hyphae. Nature Reviews Microbiology. 9 (10), 737-748 (2011).
- Moyes, D. L., Richardson, J. P., Naglik, J. R. Candida albicans-epithelial interactions and pathogenicity mechanisms: scratching the surface. Virulence. 6 (4), 338-346 (2015).
- Lopes, J. P., Lionakis, M. S. Pathogenesis and virulence of Candida albicans. Virulence. 13 (1), 89-121 (2022).
- Quindós, G., et al. Therapeutic tools for oral candidiasis: Current and new antifungal drugs. Medicina oral, patologia oral y cirugia buccal. 24 (2), e172-e180 (2019).
- Nishimoto, A. T., Sharma, C., Rogers, P. D. Molecular and genetic basis of azole antifungal resistance in the opportunistic pathogenic fungus Candida albicans. Journal of Antimicrobial Chemotherapy. 75 (2), 257-270 (2020).
- Gholami, L., Shahabi, S., Jazaeri, M., Hadilou, M., Fekrazad, R. Clinical applications of antimicrobial photodynamic therapy in dentistry. Frontiers in Microbiology. 13, 1020995 (2013).
- Trigo-Gutierrez, J. K., Vega-Chacón, Y., Soares, A. B., Mima, E. G. O. Antimicrobial activity of curcumin in nanoformulations: a comprehensive review. International Journal of Molecular Sciences. 22 (13), 7130 (2021).
- Santezi, C., Reina, B. D., Dovigo, L. N. Curcumin-mediated Photodynamic Therapy for the treatment of oral infections-A review. Photodiagnosis and Photodynamic Therapy. 21, 409-415 (2018).
- Dovigo, L. N., et al. Curcumin-mediated photodynamic inactivation of Candida albicans in a murine model of oral candidiasis. Medical Mycology. 51 (3), 243-251 (2013).
- Zangirolami, A. C., Carbinatto, F., Filho, J. D. V., Bagnato, V. S., Blanco, K. C. Impact of light-activated curcumin and curcuminoids films for catheters decontamination. Colloids and SurfacesB: Biointerfaces. 213, 112386 (2022).
- Santezi, C., Tanomaru, J. M., Bagnato, V. S., Júnior, O. B., Dovigo, L. N. Potential of curcumin-mediated photodynamic inactivation to reduce oral colonization. Photodiagnosis Photodynamic Therapy. 15, 46-52 (2016).
- Takakura, N., et al. A novel murine model of oral candidiasis with local symptoms characteristic of oral thrush. Microbiology and immunology. 47 (5), 321-326 (2003).
- Mima, E. G., et al. Susceptibility of Candida albicans to photodynamic therapy in a murine model of oral candidosis. OralSurgery, Oral Medicine, Oral Pathology, Oral Radiology and Endodontology. 109, 392-401 (2010).
- Solis, N. V., Filler, S. G. Mouse model of oropharyngeal candidiasis. Nature Protocol. 7 (4), 637-642 (2012).
- Marôco, J. . Análise Estatística com o SPSS Statistics 25. , (2018).
- Naglik, J. R., Fidel, P. L., Odds, F. C. Animal models of mucosal Candida infection. FEMS Microbiology Letters. 283 (2), 129-139 (2008).
- Samaranayake, Y. H., Samaranayake, L. P. Experimental oral candidiasis in animal models. Clinical Microbiology Reviews. 14, 398-429 (2001).
- Chamilos, G., Lionakis, M. S., Lewis, R. E., Kontoyiannis, D. P. Role of mini-host models in the study of medically important fungi. The Lancet Infectious Diseases. 7, 42-55 (2007).
- Carmello, J. C., et al. Treatment of oral candidiasis using Photodithazine- mediated photodynamic therapy in vivo. PLoS One. 11 (6), e0156947 (2016).
- Sakima, V. T., et al. Antimicrobial photodynamic therapy mediated by curcumin-loaded polymeric nanoparticles in a murine model of oral candidiasis. Molecules. 23 (8), 2075 (2018).
- Abe, S., et al. A glucocorticoid antagonist, mifepristone affects anti-Candida activity of murine neutrophils in the presence of prednisolone in vitro and experimental candidiasis of prednisolone-treated mice in vivo. FEMS Immunology and Medical Microbiology. 13 (4), 311-316 (1996).
- Jones, J. H., Russell, C., Young, C., Owen, D. Tetracycline and the colonization and infection of the mouths of germ-free and conventionalized rats with Candida albicans. Journal Antimicrobial Chemotherapy. 2 (3), 247-253 (1976).
- Russell, C., Jones, J. H. Effects of oral inoculation of Candida albicans in tetracycline-treated rats. Journal of Medical Microbiology. 6 (3), 275-279 (1973).
- Teichert, M. C., Jones, J. W., Usacheva, M. N., Biel, M. A. Treatment of oral candidiasis with methylene blue- mediated photodynamic therapy in an immunodeficient murine model. OralSurgery, Medicine, Pathology, Radiology and Endodontology. 93, 155-160 (2002).
- Totti, M. G. A., Santos, E. B., Almeida, O. P., Koga-Ito, C. Y., Jorge, A. O. C. Oral candidosis by Candida albicans in normal and xerostomic mice. Brazilian Oral Research. 18, 202-207 (2004).
- Hidalgo, K. J. R., et al. Antimicrobial photodynamic therapy in combination with nystatin in the treatment of experimental oral candidiasis induced by Candida albicans resistant to fluconazole. Pharmaceuticals (Basel). 12 (3), E140 (2019).
Citer Cet Article
Mima, E. G. d. O., Pavarina, A. C., Jordão, C. C., Vieira, S. M., Dovigo, L. N. Curcuminoid-Mediated Antimicrobial Photodynamic Therapy on a Murine Model of Oral Candidiasis. J. Vis. Exp. (200), e65903, doi:10.3791/65903 (2023).