Formulation Of Drug Delivery System Research Articles

Enhanced Anti-Inflammatory Activity of Kaempferia galanga Extract by Solid Self-Nanoemulsifying Drug Delivery System and Its Development in Fast Disintegrating Tablet

The increasing global incidence of osteoarthritis (OA) emphasizes the need for effective treatments, particularly for the elderly. Conventional OA treatments pose administration challenges, leading to patient discomfort due to difficulties in administration. Herbal formulations offer an alternative to mitigate these issues. Kaempferia galanga (KG) contains ethyl p-methoxycinnamate, a compound displaying anti-inflammatory properties that hold promise for OA treatment. This study explores the formulation of a solid self-nanoemulsifying drug delivery system (S-SNEDDS) of Kaempferia galanga extract (KGE) and evaluates its anti inflammatory efficacy, subsequently developing it into a fast disintegrating tablet (FDT) dosage form. Initially, a liquid SNEDDS (L-SNEDDS) was prepared with varying surfactant and co surfactant concentrations. The optimal formula of L-SNEDDS (FL2) using tween 80: cremophor RH 40: PEG 400 in a ratio of 1:1:2 demonstrated favorable characteristics, including transmittance of 86.93 ± 1.16%, emulsification time of 28 ± 2.65 s, particle size of 27.79 ± 2.00 nm, PDI of 0.21 ± 0.014, and zeta potential of -12.57 mV. FL2 was solidified using aerosil 200 to produce S-SNEDDS and tested for anti-inflammatory efficacy in vivo using a carrageenan induced rat model. Results showed enhanced anti-inflammatory efficacy of KGE via S-SNEDDS, marked by reduced edema volume. Afterward, FDT S-SNEDDS were prepared using the direct compression method by comparing different types of superdisintegrants. The formulation using the combination of crospovidone and croscarmellose sodium (FT2) demonstrated excellent flow properties, tablet disintegration time of 63 s, wetting time of 34.01 ± 7.87 s, friability of 0.19%, and hardness of 3.53 ± 6.16 kg/cm2. The dissolution test indicated a better dissolution profile for FT2 compared to other formulations. In conclusion, this research presents the potential of FDT S-SNEDDS as a promising drug delivery system for enhancing the therapeutic effects of Kaempferia galanga extract in treating inflammatory conditions such as osteoarthritis.

Advancing Pharmaceutical Science with Artificial Neural Networks: A Review on Optimizing Drug Delivery Systems Formulation.

Drug Delivery Systems (DDS) have been developed to address the challenges associated with traditional drug delivery methods. These DDS aim to improve drug administration, enhance patient compliance, reduce side effects, and optimize target therapy. To achieve these goals, it is crucial to design DDS with optimal performance characteristics. The final properties of a DDS are determined by several factors that go into formulating a pharmaceutical preparation. Thus, optimizing these factors can lead to the ideal DDS formulation. Artificial Neural Networks (ANN) are computational models that mimic the function of biological neurons and neural networks and perform mathematical operations on inputs to generate outputs. ANN is widely used in medical sciences for modeling disease diagnosis and treatment, dose adjustment in combination therapy, medical education, and other fields. In the pharmaceutical sciences, ANN has gained significant attention for designing and optimizing pharmaceutical formulations. This article reviews the use of ANN in the design and optimization of pharmaceutical formulations, specifically DDS. Since DDS is highly diverse, different factors are examined for each type of DDS. These factors are considered independent and dependent parameters for each ANN model, and various examples are provided. By utilizing ANN, it is possible to establish the relationship between the formulation factors and the resulting DDS characteristics, ultimately leading to the development of optimized DDS.

Methodological advances in formulation and assay of herbal resources-based topical drug delivery systems.

Medicinal plants have been utilized for centuries as a source of healing compounds, which consist of thousands of known bioactive molecules with therapeutic potentials. This article aims to explore and emphasize the significance of medicinal plants and bioactive compounds in the development of topical pharmaceutical formulations. The journey from the extraction of phytochemicals to the development of topical pharmaceutical formulations is described with the aid of scientific evidence selected from PubMed, Google Scholar, ScienceDirect, and Web of Science. Articles published in English during 2018-2023 period were considered and selected randomly. The review discusses the extraction process of medicinal plants, solvent selection, and green synthesis of metal nanoparticles. Subsequently, various biological activities of plant extracts are elaborated especially focusing on antimicrobial, antioxidant, anti-inflammatory, and sun protection activities, along with the corresponding invitro assays commonly employed for the evaluation. The article presents the process of compound isolation through bioactivity-guided fractionation and also the toxicity evaluation of isolated fractions. Finally, the formulation of medicinal plant extracts into topical pharmaceuticals is addressed, emphasizing the stability evaluation procedures necessary for ensuring product quality and efficacy.

Formulation and Evaluation of Pulsatile Drug Delivery System for the Treatment of Arthritic Pain

Formulation and Evaluation of Pulsatile Drug Delivery System for the Treatment of Arthritic Pain

Exploring lipids: A comprehensive review on their utilization in the formulation of liposomes, phytosomes, and ethosomes for advanced drug delivery systems"

This comprehensive review explores the diverse applications of lipids in the formulation of advanced drug delivery systems, specifically focusing on liposomes, phytosomes, and ethosomes. Lipids, crucial components in these formulations, play a pivotal role in enhancing drug solubility, stability, and bioavailability. The review systematically examines the latest advancements in lipid-based delivery systems, shedding light on their unique characteristics and applications. In the realm of liposomes, the study delves into various lipid compositions, highlighting their influence on liposomal structure and function. Additionally, the review explores the integration of phytosomes, which involve the complexation of drugs with plant-derived phospholipids, showcasing their potential to improve therapeutic efficacy. Ethosomes, lipid vesicles containing high concentrations of ethanol, are also extensively discussed, emphasizing their ability to enhance transdermal drug delivery. Critical analyses of recent research findings, including the impact of lipid selection on vesicle stability, drug release kinetics, and pharmacokinetics, are presented. The review further examines the challenges associated with lipid-based formulations, providing insights into potential avenues for future research and development. By synthesizing current knowledge, this review serves as a valuable resource for researchers, clinicians, and pharmaceutical scientists seeking a comprehensive understanding of the role of lipids in optimizing liposomal, phytosomal, and ethosomal drug delivery systems.

The Cytoprotective Effect of C60 Derivatives in the Self-Microemulsifying Drug Delivery System against Triptolide-Induced Cytotoxicity In Vitro.

The aim of this study was to optimize the formulation of a C60-modified self-microemulsifying drug delivery system loaded with triptolide (C60-SMEDDS/TP) and evaluate the cytoprotective effect of the C60-SMEDDS/TP on normal human cells. The C60-SMEDDS/TP exhibited rapid emulsification, an optimal particle size distribution of 50 ± 0.19 nm (PDI 0.211 ± 0.049), and a near-neutral zeta potential of -1.60 mV. The release kinetics of TP from the C60-SMEDDS/TP exhibited a sustained release profile and followed pseudo-first-order release kinetics. Cellular proliferation and apoptosis analysis indicated that the C60-SMEDDS/TP (with a mass ratio of TP: DSPE-PEG-C60 = 1:10) exhibited lower toxicity towards L02 and GES-1 cells. This was demonstrated by a higher IC50 (40.88 nM on L02 cells and 17.22 nM on GES-1 cells) compared to free TP (21.3 nM and 11.1 nM), and a lower apoptosis rate (20.8% on L02 cells and 26.3% on GES-1 cells, respectively) compared to free TP (50.5% and 47.0%) at a concentration of 50 nM. In comparison to the free TP group, L02 cells and GES-1 cells exposed to the C60-SMEDDS/TP exhibited a significant decrease in intracellular ROS and an increase in mitochondrial membrane potential (ΔψM). On the other hand, the C60-SMEDDS/TP demonstrated a similar inhibitory effect on BEL-7402 cells (IC50 = 28.9 nM) and HepG2 cells (IC50 = 107.6 nM), comparable to that of the free TP (27.2 nM and 90.4 nM). The C60-SMEDDS/TP group also exhibited a similar intracellular level of ROS and mitochondrial membrane potential compared to the SMEDDS/TP and free TP groups. Fullerenol-Grafted Distearoyl Phosphatidylethanolamine-Polyethylene Glycol (DSPE-PEG-C60) was synthesized and applied in the self-microemulsifying drug delivery system. The C60-SMEDDS/TP was formulated using Cremophor EL, medium-chain triglycerides (MCT), PEG-400, and DSPE-PEG-C60, and loaded with triptolide (TP). The toxicity and bioactivity of the C60-SMEDDS/TP were assessed using normal human liver cell lines (L02 cells), normal human gastric mucosal epithelial cell lines (GES-1 cells), and liver cancer cell lines (BEL-7402 cells and HepG2 cells). The production of reactive oxygen species (ROS) after the C60-SMEDDS/TP treatment was assessed using 2',7'-dichlorofluorescein diacetate (DCFDA) staining. The alterations in mitochondrial membrane potential (ΔψM) were assessed by measuring JC-1 fluorescence. The cytoprotection provided by the C60-SMEDDS/TP favored normal cells (L02 and GES-1) over tumor cells (BEL-7402 and HepG2 cells) in vitro. This suggests a promising approach for the safe and effective treatment of TP.

Design and Development of Film Forming Gel of Tavaborole by using Factorial Design

Film forming gel (FFG) could be a novel approach in film forming drug delivery system which has pulled in the intrigued of pharmaceutical researcher in improvement and characterization of skin drug delivery system. FFG were developed by varying concentration of the polymers and plasticizer. The formulations were prepared using 32 full factorial design. FFG were evaluated for important parameters like drying time, drug release, antifungal activity, skin irritation and stability studies. The FFG was characterized for pH, viscosity, drug content, effective dosage volume and mechanical properties of the film formed after application; bioadhesion and water vapour permeability were also tested. All the formulations showed results within acceptable range for various tests. The optimized formulation showed drug release of 98.76% and antifungal activity in terms of efficacy as 95.83%. It is stated that the created formulation will shorten therapy duration, increase patient acceptance, and represent a breakthrough in the treatment of skin infections.

Design and Development of a Self-nanoemulsifying Drug Delivery System for Co-delivery of Curcumin and Naringin for Improved Wound Healing Activity in an Animal Model.

The present study endeavored to design and develop a self-nanoemulsifying drug delivery system to improve the solubility and dermatological absorption of curcumin and naringin. Curcumin and naringin-loaded self-nanoemulsifying drug delivery system formulations were developed using aqueous phase titration. Phase diagrams were used to pinpoint the self-nanoemulsifying drug delivery system zones. Tween 80 and Labrasol (surfactants), Transcutol (cosurfactant), and cinnamon oil were chosen from a large pool of surfactants, cosurfactants, and oils based on their solubility and greatest nano-emulsion region. Fourier transform infrared spectroscopy, zeta sizer, and atomic force microscopy were used to characterize the optimized formulations and test for dilution and thermodynamic stability. The optimized curcumin-naringin-self-nanoemulsifying drug delivery system demonstrated the following characteristics: polydispersity index (0.412 ± 0.03), % transmittance (97%), particle size (212.5 ± 05 nm), zeta potential (- 25.7 ± 1.80 mV) and having a smooth and spherical droplet shape, as shown by atomic force microscopy. The ability of their combined formulation to cure wounds was tested in comparison to pure curcumin suspension, empty self-nanoemulsifying drug delivery system, and standard fusidic acid. Upon topical administration, the optimized curcumin-naringin-self-nanoemulsifying drug delivery system demonstrated significant wound healing activity in comparison with a pure curcumin suspension, empty self-nanoemulsifying drug delivery system, and standard fusidic acid. Based upon this result, we assume that skin penetration was increased by using the optimized curcumin-naringin-self-nanoemulsifying drug delivery system with enhanced solubility.

Enhancing Oral Bioavailability of Domperidone Maleate: Formulation, In vitro Permeability Evaluation In-caco-2 Cell Monolayers and In situ Rat Intestinal Permeability Studies.

The domperidone maleate, a lipophilic agent classified as a Biopharmaceutical Classification System Class II substance with weak water solubility. Self- Emulsifying Drug Delivery System is a novel approach to improve water solubility and, ultimately bioavailability of drugs. This study aimed to develop and characterize new domperidone-loaded self-emulsifying drug delivery systems as an alternative formulation and to evaluate the permeability of domperidone-loaded self-emulsifying drug delivery systems by using Caco-2 cells and via single-pass intestinal perfusion method. Three self-emulsifying drug delivery systems were prepared and characterized in terms of pH, viscosity, droplet size, zeta potential, polydispersity index, conductivity, etc. Each formulation underwent 10, 100, 200, and 500 times dilution in intestinal buffer pH 6.8 and stomach buffer pH 1.2, respectively. Female Sprague Dawley rats were employed for in situ single-pass intestinal perfusion investigations. Results of the study revealed that the ideal self-emulsifying drug delivery systems formulation showed narrow droplet size, ideal zeta potential, and no conductivity. Additionally, as compared to the control groups, the optimum formulation had better apparent permeability (12.74 ± 0.02×10-4) from Caco-2 cell monolayer permeability experiments. The study also revealed greater Peff values (2.122 ± 0.892×10-4 cm/s) for the optimal formulation from in situ intestinal perfusion analyses in comparison to control groups (Domperidone; 0.802 ± 0.418×10-4 cm/s). To conclude, prepared formulations can be a promising way of oral administration of Biopharmaceutical Classification System Class II drugs.

Artificial intelligence-aided rational design and prediction model for progesterone-loaded self-microemulsifying drug delivery system formulations

Artificial intelligence-aided rational design and prediction model for progesterone-loaded self-microemulsifying drug delivery system formulations

PREPARATION OF LIPID-BASED FORMULATIONS USING LOCAL BEESWAX SOURCED FROM HONEYCOMBS

Solid lipids used in formulation of novel drug delivery systems in most developing countries are sourced from abroad and are quite expensive. Wax from honeycombs is readily available, and is even disposed as waste, but can be utilized as a solid lipid for the formulation of different lipid-based drug delivery systems. This study aims to formulate and compare the features of the solid lipid nanoparticle (SLNs) and nanostructured lipid carrier (NLCs) delivery systems of quinine hydrochloride made with local beeswax (that is beeswax from locally sources honeycomb waste) and other solid lipids sourced from abroad. Local beeswax was first purified by hot bath method. Solidified reverse micellar solutions (SRMS) were prepared by fusion method using Phospholipon®90H and either local beeswax, Softisan®154, foreign beeswax, or stearic acid, separately. SLNs and NLCs of quinine made with SRMS of each of these solid lipids were formulated using hot homogenization method. These SLNs and NLCs were characterized. The average particle size of SLNs and NLCs made with local beeswax was 93.60 ± 4.44 nm and 112.80 ± 3.89 nm, respectively, and was not significantly (p > 0.05) different from the sizes of formulations made from other solid lipids (SLNs: 96.64 to 118.9 ± 4.13 nm and NLCs: 99.68 ± 6.75 to 117.30 ± 4.60 nm). The particles were monodispersed having PDI ranging from 0.281±0.054 to 0.308±0.055. Encapsulation efficiency and loading capacity were generally poor, especially among the SLN formulations. However, SLNs made with local beeswax and stearic acid were able to encapsulate quinine, whereas foreign beeswax and Softisan®154 had zero encapsulation. This study reveals that the features of the SLNs and NLCs made with local beeswax where highly comparable with those formulated with the imported solid lipids. Therefore, local beeswax can serve as a suitable affordable and available alternative to other imported solid lipids for formulating different lipid drug delivery systems.

Antibiotic-Loaded Nano-Sized Delivery Systems: An Insight into Gentamicin and Vancomycin.

The fight against infectious disease has remained an ever-evolving challenge in the landscape of healthcare. The ability of pathogens to develop resistance against conventional drug treatments has decreased the effectiveness of therapeutic interventions, and antibiotic resistance is recognized as one of the main challenges of our time. The goal of this systematic review paper is to provide insight into the research papers published on innovative nanosized drug delivery systems (DDSs) based on gentamycin and vancomycin and to discuss the opportunity of their repurposing through nano DDS formulations. These two antibiotics are selected because (i) gentamicin is the first-line drug used to treat suspected or confirmed infections caused by Gram-negative bacterial infections and (ii) vancomycin is used to treat serious Gram-positive bacterial infections. Moreover, both antibiotics have severe adverse effects, and one of the purposes of their formulation as nanosized DDSs is to overcome them. The review paper includes an introduction focusing on the challenges of infectious diseases and traditional therapeutic treatments, a brief description of the chemical and pharmacological properties of gentamicin and vancomycin, case studies from the literature on innovative nanosized DDSs as carriers of the two antibiotic drugs, and a discussion of the results found in the literature.

Microbeads produced by prilling/vibration technique: A new way to use polyvinyl alcohol in pediatric and veterinary formulations

Poly(vinyl alcohol) (PVA) is a widely used synthetic polymer and due to its hydrophilicity, biocompatibility, and biodegradability, it is considered a suitable polymer for the formulation of drug delivery systems. In this study, PVA was used in a prilling/vibration technology as a pharmaceutical grade excipient to produce microbeads for oral administration that improve class II drugs' solubility and dissolution rate according to the Biopharmaceutical Classification System (BCS). Specifically, Ibuprofen (IBU) is a weakly acidic drug with low solubility at pH 1.2 and Ketoconazole (KETO), a weakly basic drug characterized by low solubility at pH 6.8. These drugs were selected because of their requirements for specific dosing conditions in children or animals, which often differ from commercially available conventional drugs. The microbeads produced were fully characterized in terms of drug loading, encapsulation efficiency, size, morphology, and drug release experiments were also conducted in a gastric fluid for IBU-loaded microbeads and simulated intestinal fluid for KETO-loaded microbeads. Finally, PVA microbeads were compared with an amorphous solid dispersion (ASDs) of the respective APIs, showing the same increase in solubility and dissolution rate. Therefore, the use of the prilling/vibration technology to produce PVA-based microbeads containing BCS class II drugs improves solubility and dissolution profile, which represent fundamental requirements for good bioavailability. Furthermore, the manufactured microbeads provide a high degree of dosing flexibility, making them suitable for administration in pediatric or veterinary patients with swallowing difficulties and requiring customized dosing.

Drug Release Study of Polyvinyl Alcohol-Gelatin-Montmorillonite Bionanocomposite Hydrogel Drug Delivery Systems Loaded with Clindamycin

One of the challenges facing medical science is the proper formulation of drug delivery systems for the correct transfer of active pharmaceutical ingredients to the body. Polymer and nanocomposite hydrogels have been considered ideal options in the preparation of drug delivery systems due to their proper properties, such as hydrophilicity and biocompatibility. In this, our research, described in this manuscript, the drug release from polyvinyl alcohol (PVA)-gelatin-montmorillonite (MMT) bionanocomposite hydrogel drug delivery systems loaded with clindamycin was studied. The structural and physical properties of prepared nanocomposite hydrogels were investigated using X-ray diffractometry (XRD), field emission scanning electron microscopy (FESEM), Fourier-transform infrared spectroscopy (FTIR), Brunauer-Emmette-Teller (BET) analysis, gel fraction and swelling tests. The results showed that by adding MMT clay to PVA-gelatin hydrogels, the amount of gel fraction increased, and due to the decrease in the size of the pores, the amount of swelling decreased. The results of the drug release tests showed that the release rate of clindamycin was inversely related to the percentage of MMT added to the nanocomposite hydrogel. The results also showed that the shape of the drug delivery system and its dimensions affected the release rate of clindamycin. The dominant mechanism of drug release in all samples was found to be Fickian transport. Considering the favorable in-vitro drug release performance of our PVA-gelatin-MMT nanocomposite hydrogels in the release of clindamycin, it was concluded that they are suitable options for preparing practical drug delivery systems with controlled drug release ability.

Formulation, Optimization and Evaluation of Dabigartan Etexilate Encapsulated Solid Supersaturated Self-Nanoemulsifying Drug Delivery System

Objective: The present study proposed Dabigatran Etexilate loaded solid supersaturat-ed self-nanoemulsifying drug delivery system (solid S-SNEDDS) for enhancement of payload, drug solubility, dissolution rate as well as minimization of drug precipitation. Methods: The study involved formulation optimization using the Box-Behnken design. The op-timal SNEDDS consisting of Caprylic acid (32.9% w/w), Cremophor EL (50.2% w/w) and Transcutol HP (18.8% w/w) as Oil, Surfactant and Co-surfactant, respectively were formulated and evaluated for particle size, PDI, Zeta potential and saturation solubility. The SNEDDS was further incorporated with PPIs for the preparation of supersaturated SNEDDS (S-SNEDDS) to in-crease the drug payload in the formulation. S-SNEDDS was converted to solid S-SNEDDS by ad-sorption onto the porous carrier i.e., Aerosil®200. The in-vitro drug release study was also con-ducted for solid S-SNEDDS. Results: SNEDDS had size, PDI, and Zeta potential of 82 nm, 0.347, -10.50 mV, respectively. SNEDDS enhanced the saturation solubility of the drug by 93.65-fold. Among PPIs, HPMC K4M showed the most effective response for the formulation of S-SNEDDS. The S-SNEDDS had a more substantial drug payload, which further increased the solubility by 150 times of pure drugs and 16 times of SNEDDS. Solid S-SNEDDS exhibited free-flowing properties. Reconstituted sol-id S-SNEDDS had acceptable size, PDI, and Zeta potential of 131.3 nm, 0.457, and -11.3 mV, respectively. In-vitro drug release study revealed higher drug dissolution and minimized drug pre-cipitation by SNEDDS compared to marketed products and pure drugs. Conclusion: Proposed nano-formulation was found to efficiently improve the aqueous solubility of the drug and avoid the drug precipitation, thereby avoiding drug loss and improving drug bioa-vailability.

Formulation of self-nanoemulsifying drug delivery system (SNEDDS) of combined 70% ethanolic of Begonia medicinalis herbs and Moringa oleifera leaves

Background: Benalu batu (Begonia medicinalis) and kelor leaves (Moringa oleifera) are empirically used as alternative therapies by people in Central Sulawesi to maintain their health. Our previous research showed that the combination of these two plant extracts possessed an immunomodulatory activity. Self-Nanoemulsifying Drug Delivery System (SNEDDS) formulation was performed to improve the extract's bioavailability, solubility and stability. Objective: This study aims to formulate and characterise SNEDDS preparations of combined ethanolic extract of B. medicinalis herbs and M. oleifera leaves and further test its stability. Method: SNEDDS formulation was started by screening for proper oil, surfactant, and co-surfactant. The formula was then optimised using a ternary phase diagram and characterisation. The stability test was performed using centrifugation, heating-cooling, and freeze-thaw cycles. Results: The optimal SNEDDS formula consists of isopropyl myristate (10%), tween 80 (50%) and propylene glycol (40%). The characterisation values obtained were: Transmittance value 83.785 ± 0.275%, particle size 18.666 ± 0.208 nm, polydispersity index 0.664 ± 0.0085, and zeta potential -39.20 ± 0.2 mV. The formula was stable during three stability evaluation tests. Conclusion: The optimal formula met the SNEDDS characteristics requirements and showed good stability.

Formulation, In-vitro and In-vivo Evaluation of Chronology-based Mucoadhesive Drug Delivery System of an Antihypertensive Drug

Current research aimed to prepare and estimate chronology-based mucoadhesive PDDS of antihypertensive drug losartan potassium through formulation of fast-dissolving core tablet and incorporation of core tablet to polymer coating to formulate bioadhesive PDDS through direct compression system. The coating was done by using polymers ethyl cellulose and carbopol 934. Pre-compression and post-compression parameters, drug release, lag time and mucoadhesive examination was assessed for the formulation. The expected lag time for hypertension is 8 hours; hence, this lag time was achieved by using a bioadhesive pulsatile system. The optimized formulation showed 8 hours lag time with appropriate mucoadhesion for an equivalent period. Moreover, in-vitro as well as in-vivo mucoadhesion investigations reflected the positive outcomes. Consequently, the BPDDS was the finest preventative substitute for drugs with the highest absorption in the stomach and for drugs used to treat diseases related to circadian rhythm

Technical Considerations, Applications, and Benefits of Organogels in Topical Drug Delivery Systems.

Organogels represent semi-solid systems where an organic liquid phase is entrapped within a three-dimensional network formed by self-assembled, crosslinked, or entangled gelator fibers. These versatile materials find applications in a wide range of fields, including chemistry, pharmaceuticals, cosmetics, biotechnology, and food technology. Notably, in pharmacology, they serve as valuable platforms for drug and vaccine delivery, facilitating the transport of active ingredients through various routes such as transdermal, oral, and parenteral. However, their previous utility as drug delivery systems was hindered by the toxicity associated with the organic solvents used. The pharmacokinetics of medications delivered via organogels are primarily influenced by the distinctive properties of these materials, specifically their "high permeability and poor aqueous solubility," which can impact the bioavailability of the drugs. Organogels can be employed topically or for the controlled release of medications through cutaneous administration and percutaneous absorption, expanding their scope of application beyond conventional drug delivery methods. Organogels hold significant promise as drug delivery vehicles due to their biocompatibility, non-irritating properties, and thermoremanent characteristics. They enable the formulation of diverse drug delivery systems by incorporating both hydrophilic and hydrophobic bioactive compounds within the gel matrix. This comprehensive review offers an overview of organogels, encompassing their nature, synthesis, characterization, and properties. Special attention is directed towards cutting-edge technologies employed in designing organogels as potential controlled delivery systems, with a focus on their emerging therapeutic applications.

Formulation Development of Solid Self-Nanoemulsifying Drug Delivery Systems of Quetiapine Fumarate via Hot-Melt Extrusion Technology: Optimization Using Central Composite Design.

Quetiapine fumarate (QTF) was approved for the treatment of schizophrenia and acute manic episodes. QTF can also be used as an adjunctive treatment for major depressive disorders. QTF oral bioavailability is limited due to its poor aqueous solubility and pre-systemic metabolism. The objective of the current investigation was the formulation development and manufacturing of solid self-nanoemulsifying drug delivery system (S-SNEDDS) formulation through a single-step continuous hot-melt extrusion (HME) process to address these drawbacks. In this study, Capmul® MCM, Gelucire® 48/16, and propylene glycol were selected as oil, surfactant, and co-surfactant, respectively, for the preparation of S-SNEDDS. Soluplus® and Klucel™ EF (1:1) were selected as the solid carrier. Response surface methodology in the form of central composite design (CCD) was utilized in the current experimental design to develop the S-SNEDDS formulations via a continuous HME technology. The developed formulations were evaluated for self-emulsifying properties, particle size distribution, thermal behavior, crystallinity, morphology, physicochemical incompatibility, accelerated stability, and in vitro drug release studies. The globule size and emulsification time of the optimized SNEDDS formulation was 92.27 ± 3.4 nm and 3.4 ± 3.38 min. The differential scanning calorimetry (DSC) and powder X-ray diffraction (PXRD) studies revealed the amorphous nature of the drug within the formulation. There were no drug-excipient incompatibilities observed following the Fourier transform infrared (FTIR) spectroscopy. The optimized formulation showed an extended-release profile for 24 h. The optimized formulation was stable for three months (last time-point tested) at 40 °C/75% RH. Therefore, the developed S-SNEDDS formulation could be an effective oral delivery platform for QTF and could lead to better therapeutic outcomes.

Overview on Natural Polymers: A Promising Pharmaceutical excipient in Mucoadhesive Drug Delivery System

This review aims to compile the current literature with a perspective on the role of natural polymers or polysaccharides in mucoadhesive drug delivery systems. Natural polymers are basically polysaccharides, biocompatible, non-toxic, stable, and economical. Polymers play an important role as excipients in designing the dosage form and influence drug release without any side effects. Natural polymers are of growing interest in the utilization of mucosal drug delivery as a novel technique due to their ability to interact with the mucosal layer of the body, improve the effectiveness of the drug, and prolong the residence time of the dosage form at the site of absorption. The bioadhesive polymers can exert control over the rate and extent of drug release and are selected in the formulation of mucoadhesive drug delivery systems. This review article discusses several aspects of mucoadhesive drug delivery, including the mechanism of mucoadhesion, mucus layer, and mucoadhesive polymers, with special reference to natural-based polysaccharides, as well as their applications and roles in different formulations developed by using polysaccharides in various dosage forms.