Fabrication of Phytosome with Enhanced Activity of Sonneratia alba: Formulation Modeling and in vivo Antimalarial Study

The Toxicological Profile of Active Pharmaceutical Ingredients-Containing Nanoparticles: Classification, Mechanistic Pathways, and Health Implications

Nanotechnology is the manipulation of matter on an atomic and molecular scale, producing a lot of new substances with properties that are not necessarily easily expected based on present knowledge. Nanotechnology produces substances with unique properties that can be beneficial or harmful depending on their biocompatibility and distribution. Understanding nanomaterial toxicity is essential to ensure their safe application in biological and environmental applications. This review aims to provide a comprehensive overview of nanoparticle toxicity, focusing on their physicochemical properties, mechanisms of cellular uptake, and potential health risks. Key factors influencing toxicity include particle size, shape, concentration, aspect ratio, crystallinity, surface charge, dissolution, and agglomeration. Nanoparticles can induce oxidative stress and inflammation, contributing to adverse effects when inhaled, ingested, or applied to the skin. However, their toxicity may not be limited to just these pathways, as they can also exhibit other toxic properties, such as activation of the apoptotic pathway and mitochondrial damage. By summarizing the current knowledge on these aspects, this article intends to support the development of nanoparticles in a safer way for future applications.

Phytosomes as a New Frontier and Emerging Nanotechnology Platform for Phytopharmaceuticals: Therapeutic and Clinical Applications

A complete investigation into phytosome-based formulations and innovative nanotechnology is presented in this review. This investigation aims to improve the bioavailability and therapeutic effectiveness of herbal components. Phytosomes can significantly increase solubility, absorption, and stability compared to standard herbal formulations by encapsulating active phytoconstituents into phospholipid complexes. This unique ability of phytosomes to overcome the limits of traditional herbal formulations is a potential game changer in medicine. This study highlights the different uses of phytosomes across various health disorders, such as neurodegenerative illnesses, inflammatory conditions, diabetes, cardiovascular diseases, and wound healing. The review also discusses the potential of phytosomes in treating infectious diseases by improving the delivery of bioactive compounds that have improved anticancer efficacy and antibacterial properties. Despite the emergence of numerous groundbreaking discoveries, substantial barriers remain that hinder their widespread application. Challenges that must be addressed include stability, large-scale manufacture, regulatory hurdles, and limited clinical translation. This review also examines the limitations present in clinical practice, mainly focusing on the variability in bioavailability. The review highlights the crucial need for future research in phytosomes, engaging the researchers and emphasizing the continuous evolution of this promising area of medicine.

Vesicular Carriers for Phytochemical Delivery: A Comprehensive Review of Techniques and Applications

Natural substances, especially those derived from plants, exhibit a diverse range of therapeutic benefits, such as antioxidant, anti-inflammatory, anticancer, and antimicrobial effects. Nevertheless, their use in clinical settings is frequently impeded by inadequate solubility, limited bioavailability, and instability. Nanovesicular carriers, such as liposomes, niosomes, ethosomes, transferosomes, transethosomes, and cubosomes, have emerged as innovative phytochemical delivery systems to address these limitations. This review highlights recent developments in vesicular nanocarriers for phytochemical delivery, emphasizing preparation techniques, composition, therapeutic applications, and the future potential of these systems. Phytosomes, along with their key advantages and various preparation techniques, are extensively described. Various in vitro and in vivo characterization techniques utilized for evaluating these nanovesicular carriers are summarized. Completed clinical trials and patents granted for nanovesicles encapsulating phytochemicals designed for systemic delivery are tabulated. Phytochemical delivery via vesicular carriers faces challenges such as low stability, limited active loading, scalability issues, and high production costs. Additionally, immune clearance and regulatory hurdles hinder clinical application, requiring improved carrier design and formulation techniques.

Formulation Development of Natural Polymeric Nanoparticles, In Vitro Antiaging Evaluation, and Metabolite Profiling of Toona sinensis Leaf Extracts

Background/Objectives: Natural polymer nanoparticles have potential as delivery systems, can enhance pharmacological activity, and can improve stability in the cosmetic field. In this research, we implemented a development approach for chitosan-alginate and chitosan-pectin nanoparticles. This study aimed to investigate effect of formulation, process variables, in vitro antiaging evaluation, and metabolite profiling of Toona sinensis leaf extracts. Methods: Polymeric nanoparticles have been prepared using the ionic gelation method (Temperature = 40 °C, time = 1 h and speed = 1000 rpm), in vitro antiaging evaluation using the Neutrophil Elastase Inhibitor Screening Kit method, and analysis of metabolite profiling with UHPLC-HRMS. Results: Research results found that the SLE and EAFSL nanoparticles that have good and stable characteristics before and after storage in a climatic chamber after 3 months are FIIA-NPSLE (0.75% chitosan and 1.25% Alginate), FIP-NPSLE (1% chitosan and 0.5% Pectin), FIIA-NPEAFSL (0.75% chitosan and 1.25% Alginate), and FIIIP-NPEAFSL (0.125% chitosan and 0.375% Alginate). Chitosan-alginate polymers, such as FIIA-NPEAFSL, have higher inhibition of the elastase enzyme than FIIA-NPSLE, with a % inhibition (IC50) of FIIA-NPEAFSL being 87.30%, while the IC50 of FIIA-NPSLE is 39.40%. Meanwhile, using chitosan-pectin polymers, such as FIP-NPSLE, results in lower inhibition of the elastase enzyme compared to the chitosan-alginate polymer, with an IC50 of 27.28% while IC50 FIIIP-NPEAFSL is 39.53%. SLE and EAFSL nanoparticles with chitosan-alginate and chitosan-pectin polymers resulted in a significant PDI during storage from 1.3 to 1.9, and zeta potential values were very low, ranging from -11 mV to -27 mV. Metabolite profiling using UHPLC-HRMS on T. sinensis leaf extracts revealed that the main compounds contained were glycitein, quercetin, quercetin-3β-D-glucoside, kaempferol, and ellagic acid, which has potential as an antiaging agent. Conclusions: It can be concluded that using chitosan, alginate, and pectin in the process of encapsulating extracts into nanoparticles with the same process variables affect evaluation of antiaging activity in elastase enzymes. Further research will develop these nanoparticles into nanohydrogels with antiaging activity.

Nanoparticle-Encapsulated Plant Polyphenols and Flavonoids as an Enhanced Delivery System for Anti-Acne Therapy

This study conducted a literature review by searching for articles related to the treatment of skin infections/wrinkles using nano-delivery systems containing natural compounds. The search was conducted in various databases for articles published in the last 10 years, with strict inclusion and exclusion criteria. Of the 490 articles found, 40 were considered relevant. Acne vulgaris is a common dermatological disorder characterised by inflammation of the sebaceous glands, often resulting in the development of pimples, cysts, and scarring. Conventional treatments, including antibiotics and topical retinoids, frequently demonstrate limitations such as side effects, resistance, and insufficient skin absorption. Recent advancements in nanotechnology have enabled the creation of innovative drug-delivery systems that enhance the effectiveness and reduce the adverse effects of anti-acne medications. Polyphenols and flavonoids, natural bioactive compounds with notable anti-inflammatory, antioxidant, and antibacterial properties, are recognised for their therapeutic effectiveness in acne treatment. However, their practical application is hindered by insufficient solubility, stability, and bioavailability. The incorporation of these compounds into nanoparticle-based delivery systems has shown promise in resolving these challenges. Various nanoparticle platforms, including lipid-based nanoparticles, polymeric nanoparticles, and solid lipid nanoparticles, are evaluated for their ability to improve the stability, controlled release, and targeted delivery of polyphenols and flavonoids to the skin. The advent of polyphenol and flavonoid-loaded nanoparticles marks a new acne therapy era.