Green Synthesis of Curcumin-Loaded Bacterial Nanocellulose for Topical Application: Preparation and In vivo Study.

Q2 Pharmacology, Toxicology and Pharmaceutics

Pharmaceutical nanotechnology Pub Date : 2024-12-10 DOI:10.2174/0122117385330452241015071605

Juniar Kalpika Resmi, Safira Prisya Dewi, Heni Rachmawati

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引用次数: 0

Abstract

Background: Bacterial nanocellulose (BNC) is typically produced through fermentation using Hestrin Schramm (HS) médium. However, its high cost limits its use in industry. Moreover, curcumin, as a model substance, is a potential bioactive compound but has low bioavailability. This also limits its use for clinical application. Thus, a delivery system using more affordable production of BNC was develop to improve the lack property of curcumin, focusing on topical route.

Objective: This study aims to determine the best substrate component according to yield value and evaluate the physical properties as well as the permeation capability of BNC as a delivery matrix system for curcumin.

Methods: The optimization of Gluconacetobacter xylinus culture media to produce BNC was conducted using 6 variation substrates consisting of Palmyra sap (PS) and tofu pulp with certain concentrations. Following a nine-day period, the yield of BNC was calculated. The selected BNCs were then impregnated with curcumin-DMSO and curcumin in the form of nanoemulsion (curcumin- NE). Subsequently, the BNCs containing these curcumin forms were characterized. In vitro testing of curcumin reléased from BNC was conducted using Franz difusión cells. In addition, the penetration ability of curcumin across the mice skin was observed using confocal microscopy. In vivo testing was also conducted to ascertain the safety of BNC-loaded curcumin on mice skin.

Results: PS-TP substrate (100:0, S-6) was the most appropriate substrate for BNC production, yielding 118.5±0.09 g/L. CR-DMSO and CR-NE were successfully impregnated into BNC. Confocal data showed that both formulations were able to penétrate the dermis layer. There was no significant difference was observed between the administration of BNC/CR-DMSO and BNC/CR-NE against the control.

Conclusion: BNC successfully produced using palmyra sap shows promising biomembrane for topical delivery of curcumin. No evidence inflammation or neovascularization in BNC/CR-DMSO- and BNC/CR-NE-treated mice confirms the safety use of this biomembrane.

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外用负载姜黄素的细菌纳米纤维素的绿色合成：制备和体内研究。

背景：细菌纳米纤维素（BNC）通常是通过赫斯特林施拉姆（HS）胞质发酵生产的。然而，它的高成本限制了它在工业上的应用。此外，姜黄素作为一种模式物质，是一种潜在的生物活性化合物，但其生物利用度较低。这也限制了其临床应用。因此，本文以局部途径为重点，开发了一种使用成本更低的BNC产品来改善姜黄素缺乏特性的给药系统。目的：根据产率值确定最佳底物组分，并评价BNC作为姜黄素传递基质体系的物理性质和渗透能力。方法：采用棕榈树液（PS）和豆腐浆（一定浓度）组成的6种变异基质，对木醋杆菌生产BNC的培养基进行优化。经过9天的周期，计算BNC的收益率。然后用姜黄素- dmso和姜黄素以纳米乳（姜黄素- NE）的形式浸渍所选的bnc。随后，对含有这些姜黄素形式的bnc进行了表征。用Franz difusión细胞对BNC中姜黄素的释放进行了体外实验。此外，用共聚焦显微镜观察姜黄素对小鼠皮肤的渗透能力。体内实验也证实了bnc负载的姜黄素在小鼠皮肤上的安全性。结果：PS-TP底物（100:0,S-6）为产BNC的最佳底物，产率为118.5±0.09 g/L。CR-DMSO和CR-NE成功浸渍到BNC中。共聚焦数据表明，这两种配方都能够穿透真皮层。BNC/CR-DMSO和BNC/CR-NE对对照组的影响无显著性差异。结论：用棕榈树液成功制备的BNC具有良好的姜黄素外用生物膜应用前景。在BNC/CR-DMSO-和BNC/ cr - ne -处理的小鼠中，没有证据表明炎症或新生血管的形成证实了这种生物膜的安全性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Pharmaceutical nanotechnology Pharmacology, Toxicology and Pharmaceutics-Pharmaceutical Science

CiteScore

4.20

自引率

0.00%

发文量

期刊介绍： Pharmaceutical Nanotechnology publishes original manuscripts, full-length/mini reviews, thematic issues, rapid technical notes and commentaries that provide insights into the synthesis, characterisation and pharmaceutical (or diagnostic) application of materials at the nanoscale. The nanoscale is defined as a size range of below 1 µm. Scientific findings related to micro and macro systems with functionality residing within features defined at the nanoscale are also within the scope of the journal. Manuscripts detailing the synthesis, exhaustive characterisation, biological evaluation, clinical testing and/ or toxicological assessment of nanomaterials are of particular interest to the journal’s readership. Articles should be self contained, centred around a well founded hypothesis and should aim to showcase the pharmaceutical/ diagnostic implications of the nanotechnology approach. Manuscripts should aim, wherever possible, to demonstrate the in vivo impact of any nanotechnological intervention. As reducing a material to the nanoscale is capable of fundamentally altering the material’s properties, the journal’s readership is particularly interested in new characterisation techniques and the advanced properties that originate from this size reduction. Both bottom up and top down approaches to the realisation of nanomaterials lie within the scope of the journal.