Abstract
Invasive candidiasis (IC) remains as a major cause of morbidity and mortality in critically ill patients. Amphotericin B (AmB) is one of the most effective antifungal agents commonly used to treat this infection. However, it induces severe side effects such as nephrotoxicity, cardiac alterations, nausea, fever, and liver damage. The utilization of drug delivery systems has been explored to overcome these limitations. Several AmB lipid formulations have been developed and are currently available in the market. Although they have the ability to reduce the main side effects of free AmB, their high cost, necessity of repeated intravenous injections for successful treatment, and incidence of pulmonary toxicity have limited their use. In the last decades, alginate has gained significant interest in drug delivery applications as a cost-effective strategy to improve the safety and therapeutic effect of toxic drugs. In this work, the clinically relevant drug AmB was encapsulated into alginate microparticles using the emulsification/external gelation method. We hypothesize that this synthesis strategy may positively impact the antifungal efficacy of AmB-loaded MCPs toward Candida albicans cells while reducing the toxicity in human lung cells. To prove this hypothesis, the ability of the microplatform to disrupt the cellular membrane potential was tested and its antifungal effectiveness toward Candida albicans cells was evaluated using the cell counting and plate count methods. Moreover, the toxicity of the microplatform in human lung cells was evaluated using CellTiter 96® AQueous cell viability assay and qualitative diffusion analysis of acridine orange. Our results demonstrated that the platform developed in this work was able to induce antifungal toxicity against Candida albicans yeast cells at the same level of free AmB with minimal toxicity to lung cells, which is one of the main side effects induced by commercial drug delivery systems containing AmB. Overall, our data provides convincing evidence about the effectiveness of the alginate-based microplatform toward Candida albicans cells. In addition, this vehicle may not require several infusions for a successful treatment while reducing the pulmonary toxic effect induced by commercial lipid formulations.
Highlights
Invasive candidiasis (IC) is a serious infection caused by a yeast called Candida, with candidaemia being its most common clinical presentation [1,2,3,4,5]
Blank microparticles (MCPs) showed a diameter of 1.6 ± 0.3 μm according to scanning electron microscopy (SEM) and optical microscope. is indicates that the incorporation of amphotericin B (AmB) did not induce an increase in the diameter of the microplatform
Our work demonstrated that AmB-loaded MCPs were effective in disrupting the cellular membrane potential and reducing the cell viability of Candida albicans cells at the same level as free AmB with minimal lung cell toxicity and cell membrane injury
Summary
Invasive candidiasis (IC) is a serious infection caused by a yeast called Candida, with candidaemia being its most common clinical presentation [1,2,3,4,5]. It was reported that the drug released from the gel discs was approximately 15–20% in 2 days [42] Based on these results, alginate-based vehicles may confront similar clinical limitations as the commercial lipid formulations, requiring repeated intravenous injections for successful treatment and inducing pulmonary toxicity. It has been reported that the production methods of alginate nano- or microparticles have a significant impact on tuning the (bio)pharmaceutical performance [44] We hypothesize that this synthesis strategy may positively impact the antifungal efficacy of AmB-loaded MCPs toward Candida albicans cells while reducing the toxicity in human lung cells. Our results demonstrated that AmB-loaded MCPs were able to disrupt the cellular membrane potential of Candida albicans yeast cells and the in vitro antifungal effectivity was the same as that induced by the free drug. This data provides convincing evidence of the effectiveness of the platform developed in this work toward Candida albicans cells, which in turn may reduce the side effect of current vehicles associated with pulmonary toxicity
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