Niosomes: novel sustained release nonionic stable vesicular systems--an overview

Niosomes as a targeted drug delivery system in the treatment of breast cancer: preparation, classification and mechanisms of cellular uptake

Breast cancer (BC) remains one of the significant health issues across the globe, being diagnosed in millions of women worldwide annually. Conventional therapeutic options have substantial adverse effects due to their non-specificity and limited drug bioavailability. Niosomes, being novel drug delivery systems formed from non-ionic surfactants, with or without cholesterol and charge-inducing agents, are used as therapeutic options in treating BC. Their formulation by various methods enhances the therapeutic efficacy and bioavailability and minimises side effects. Niosomal formulation of tamoxifen exhibits target drug delivery with enhanced stability, whereas docetaxel and methotrexate show sustained and controlled drug release, respectively. 5-Fluorouracil, doxorubicin, paclitaxel, cyclophosphamide and epirubicin show improved cytotoxic effects against BC when combined with other agents. Furthermore, repurposed niosomal formulations of anti-cancer drugs show improved penetration, reduced tumour volume and significantly enhanced anti-tumour effect. This review article focuses on the composition of niosomes and their application in BC treatment and then examines how niosomes could contribute to BC research.

Exploring the potential of antifungal-loaded proniosomes to consolidate corneal permeation in fungal keratitis: A comprehensive investigation from laboratory characterization to microbiological evaluation

This work aimed to prepare Terconazole loaded proniosomes (TCZ-PNS) utilizing modified coacervation technique for the management of fungal keratitis. Terconazole (TCZ) is a potent antifungal with poor aqueous solubility posing intricacies in its incorporation in ocular formulations. A 23 factorial design was adopted to probe independent formulation variables including A: Lecithin: cholesterol ratio, B: Surfactant: cholesterol ratio and C: Span® 80 contribution (% of total SAA). The formulae, generated by the design, were prepared and scrutinized regarding entrapment efficiency (%EE), particle size (PS), polydispersity index (PDI) and zeta potential (ZP). Numerical desirability algorithms selected an optimum TCZ-PNS which boasted plausible %EE (89.51 % ± 0.94 %), nanoscale vesicles consistent with TEM measurements (247.9 ± 0.42 nm), a sufficiently high ZP (-43.42 ± 0.85 mV), and an in-vitro biphasic release profile that remained stable even after Gamma irradiation and short-term storage. The transcorneal ex-vivo permeation of TCZ-PNS was higher than that of TCZ suspension (≈ 2-fold). The formulation was further evaluated for pH, corneal hydration threshold, and histopathological safety, confirming its suitability for ocular application. Confocal laser microscopy revealed substantial corneal uptake (approximately twice as deep as of TCZ suspension). Additionally, microbiological assessments of the optimal TCZ-PNS compared to TCZ suspension demonstrated an inhibition zone nearly 50 % larger, a significantly lower MIC and MFC (64-fold reduction), and enhanced biofilm inhibition activity across most tested concentrations. These findings suggest that TCZ-PNS could be a propitious treatment choice to deeply deliver antifungal therapy for the eradication of deeply rooted and inaccessible fungal keratitis.

Terconazole loaded edge-activated hybrid elastosome for revamped corneal permeation in ocular mycosis: In-vitro characterization, statistical optimization, microbiological assessment, and in-vivo evaluation

Herein, we investigated the preparation and characterization of Terconazole loaded edge-activated hybrid elastosome (TCN-EHE) adopting thin film hydration technique for the treatment of ocular mycosis. Terconazole (TCN) is a broad spectrum antimycotic agent suffering from sparse aqueous solubility impeding its use in ophthalmic preparations. The scrutinized formulation variables namely X1: Surfactant: Edge activator ratio (SAA: EA), X2: Pluronic® L121 contribution (% of total SAA) and X3: EA concentration (%w/v) were optimized adopting D-optimal design. Ten runs were prepared and characterized regarding their entrapment efficiency, particle size, polydispersity index and zeta potential. An optimized formula was generated, with high desirability, exhibited satisfactory entrapment efficiency, nanoscaled particle size aligning with TEM, plausible zeta potential and bi-phasic release pattern which were not altered after short-term storage. The optimized TCN-EHE displayed 1.94-fold enhanced ex-vivo corneal permeation flux. Safety was ratified through measured corneal hydration level, pH and histopathological evaluation. In-vivo corneal uptake visualized by confocal laser microscopy demonstrated 2.7-fold deeper penetration. Moreover, Superior antifungal activity has been demonstrated displaying 37 % bigger zone of inhibition, 8-fold lower minimum inhibitory and minimum fungal concentration alongside significantly higher biofilm inhibition activity at all tested concentrations for the optimized TCN-EHE compared to TCN suspension. Conclusively, we could prospect that TCN-EHE might be a revamped therapeutic alternative for the delivery of poorly soluble antimycotic agents for the combat of ocular mycosis.

Development of FK506-loaded maleimide-functionalized cationic niosomes for prolonged retention and therapeutic efficacy in dry eye disease

Tacrolimus (FK506) is widely used in ocular diseases such as corneal transplantation-host disease, uveitis, conjunctivitis, and dry eye disease (DED). However, its low aqueous solubility and poor ocular retention pose challenges for its application in the eye diseases. This study developed a novel FK506-loaded maleimide-functionalized cationic niosomes (FK506 M-CNS), aiming to prolong the retention time of FK506 in the eye and enhance its therapeutic efficacy. FK506 M-CNS had a particle size of 87.69 ± 1.05 nm and zeta potential of 22.06 ± 1.01 mV. Results of histological evaluation through H&E staining and in vitro cytotoxicity of human corneal epithelial cells consistently revealed the excellent biocompatibility of FK506 M-CNS. FK506 M-CNS exhibited superior ocular retention compared to the market product Talymus®. FK506 M-CNS significantly alleviated the symptoms of DED and promoted the recovery of corneal epithelia. FK506 M-CNS group had the lowest expression levels of inflammatory factors associated with DED. These superiorities might be due to the electrostatic interaction between cationic niosomes and negatively charged mucin in the eye, and the covalent binding of maleimide with the thiol group in the mucin. The maleimide group improved the ocular retention and efficacy of FK506, but did not increase the toxicity. Results indicated that FK506 M-CNS had great potential as a nanopharmaceutical in the treatment of ocular diseases, and M-CNS could be a promising drug carrier for ophthalmic drug delivery systems.

Repurposing verapamil hydrochloride with niosomal gel technology: Enhanced efficacy and skin penetration in hypertrophic scars

Hypertrophic scars arising from abnormal wound healing after burns, trauma, or surgery present challenges for their effective treatment. Verapamil hydrochloride (VHCl), a calcium channel blocker primarily used in cardiovascular diseases, has been proposed as a niosomal gel for topical hypertrophic scar treatment. VHCL stimulates procollagenase synthesis, induces actin filament depolymerization, and reduces fibrous tissue production, thus making it a promising candidate for scar therapy. Prior to formulation, FT-IR spectroscopy was performed to assess drug and excipient compatibility. VHCl niosomes were prepared using the thin-film hydration technique with Span-40 and cholesterol in a 7:3 molar ratio. The characterization included entrapment efficiency (%EE), vesicle size, and surface morphology. Optimized niosomes were incorporated into a gel, and in in-vitro drug release and stability studies were conducted. An in-vivo study was conducted using a rabbit model to assess formulation efficacy. Optimized VHCl niosomal formulations with high entrapment efficiency (%EE) of 71.62 % and a small vesicle size of 180 nm were used for characterization, in-vitro and in-vivo evaluations. The vesicles displayed a monodisperse distribution, spherical and irregular morphology under TEM, and good stability for 60 days at room and refrigerated temperatures. The lyophilized formulation incorporated into the silicone gel exhibited optimal pH, thixotropic rheological behavior, and sustained VHCl release for up to 48 h. In-vivo studies on a rabbit ear model revealed enhanced efficacy, reducing hypertrophic scar diameter from 7 mm to 1.9 mm after 28 days. The combination of VHCl-loaded niosomal gels demonstrated improved permeation and synergistic effects, enhancing the safety and efficacy of long-term VHCl treatment.

Transfersomes: a next-generation drug delivery system for topical ocular drug delivery

INTRODUCTION

The eye is a complex organ with several anatomical and physiological barriers that make ocular drug delivery an ongoing challenge. Transfersomes (TFS) are deformable vesicles that have been extensively applied to enhance transdermal drug delivery. However, their application in ocular drug delivery remains largely unexplored.

AREAS COVERED

This review highlights the challenges typically associated with ocular drug delivery and emphasizes the inherent properties of TFS that enable them to overcome these challenges. The influence of excipients and critical process parameters on TFS characteristics have been discussed in detail with an emphasis on the fabrication and characterization techniques typically employed for TFS development and optimization. Furthermore, recent studies evaluating the application of TFS in ocular drug delivery have been discussed in depth.

EXPERT OPINION

The unique stress-responsive and deformable nature of TFS makes them promising carriers for ocular drug delivery. However, further research in this direction is needed to understand their penetration mechanism and elucidate their potential for sustained and targeted drug delivery to ocular tissues. Moreover, further research is needed to optimize the stability and scalability of TFS to encourage their translation to the market.

Current advancements in nanoparticles for vaccines and drug delivery for the treatment of tuberculosis

Since the early centuries until the present, tuberculosis has been a global illness with no cure. However, the sickness remains dormant in the afflicted individuals in certain circumstances. Due to the thick lipid mycobacterial wall and the challenging medication delivery into the bacterial cell, treatment is complex at this point. Over the past utics., there has been a growth in the function of nanomaterials in tuberculosis (TB) management, especially in the domains of early diagnosis, vaccine, and therapy. It has been demonstrated that nanomaterials are effective in quickly and accurately identifying tuberculosis germs. Additionally, novel nanocarriers have shown great promise for improved medication delivery and immunization, possibly increasing drug concentrations in target organs while lowering the frequency of treatments. Furthermore, the engineering of antigen carriers is a promising area of tuberculosis research that may lead to the successful creation of a novel class of potent TB vaccines. This article addresses tuberculosis infection diagnosis, pathophysiology, immunology, and advanced nanoparticles to deliver TB vaccines and anti-TB drugs. The challenges and prospects for the future in creating secure and functional nanoparticles for tuberculosis treatment and diagnosis for the good health and well-being of the patient are also discussed.

Enhanced Transdermal Delivery of Piroxicam via Nanocarriers, Formulation, Optimization, Characterization, Animal Studies and Randomized Double-Blind Clinical Trial

Piroxicam is a non-steroidal anti-inflammatory drug which is used topically as an adjunctive treatment of knee osteoarthritis and as an option to control joint pain in patients suffering rheumatoid arthritis. In this study, an emulgel containing optimized nano-niosomal piroxicam was formulated and characterized in terms of mean size, polydispersity index, zeta potential, drug entrapment efficiency and capacity, release and transdermal permeation. Also, animal studies including pain level assessment, synovial prostaglandin E2 levels, knee joint swelling degree and histopathologic investigations were conducted. A randomized double-blind clinical trial was also performed to compare the analgesic effect of nano-niosomal piroxicam emulgel with piroxicam gel. The results showed optimized niosome formulation with 142 ± 7nm mean size and 0.23 ± 0.08 PDI, entrapped 99.48 ± 0.79% of added piroxicam with a sustained release pattern. Permeation studies indicated a 3.31-fold transdermal permeation of niosomal piroxicam emulgel compared with the piroxicam gel. The niosomal formulation significantly reduced knee joint swelling and prostaglandin E2 levels. The clinical trial indicated that the painkilling efficiency of the niosomal piroxicam emulgel was 37.30-fold and 3.16-fold greater compared to the placebo and the positive control groups, respectively. In conclusion, the niosomal piroxicam emulgel which may enable the drug to permeate through the skin and accumulate in synovial tissue more efficiently, showed a promising performance in lowering pain and inflammation based on the animal studies and the human clinical trial.

Niosomes as Vesicular Nanocarriers in Cosmetics: Characterisation, Development and Efficacy

In an era of significant developments in cosmetic chemistry and growing demand for efficacious skincare products, the efficient delivery of active molecules has been a challenge in formulations of cosmetics. In order to improve the performance of active compounds, the use of different nanotechnology-based systems have been explored in cosmetic chemistry. Niosomes, self-assembled vesicular nanocarriers, have been used in the cosmetic industry since the 1970s. The aim of this review is to provide a comprehensive overview of recent advancements in the encapsulation of active cosmetic compounds using niosomes as potential carriers for their sustained and targeted delivery. The review discusses the physicochemical, pharmacokinetic and pharmacodynamic properties of niosomes, including preparation methods, advantages and limitations. Various applications of niosomes in the cosmetic industry are presented together with the permeation and efficacy data from conducted in vitro and in vivo studies. Future perspectives of these nanocarriers for cosmetic applications are highlighted.

DNA vaccines as promising immuno-therapeutics against cancer: a new insight

Cancer is one of the leading causes of mortality around the world and most of our conventional treatments are not efficient enough to combat this deadly disease. Harnessing the power of the immune system to target cancer cells is one of the most appealing methods for cancer therapy. Nucleotide-based cancer vaccines, especially deoxyribonucleic acid (DNA) cancer vaccines are viable novel cancer treatments that have recently garnered significant attention. DNA cancer vaccines are made of plasmid molecules that encode tumor-associated or tumor-specific antigens (TAAs or TSAs), and possibly some other immunomodulatory adjuvants such as pro-inflammatory interleukins. Following the internalization of plasmids into cells, their genes are expressed and the tumor antigens are loaded on major histocompatibility molecules to be presented to T-cells. After the T-cells have been activated, they will look for tumor antigens and destroy the tumor cells upon encountering them. As with any other treatment, there are pros and cons associated with using these vaccines. They are relatively safe, usually well-tolerated, stable, easily mass-produced, cost-effective, and easily stored and transported. They can induce a systemic immune response effective on both the primary tumor and metastases. The main disadvantage of DNA vaccines is their poor immunogenicity. Several approaches including structural modification, combination therapy with conventional and novel cancer treatments (such as chemotherapy, radiotherapy, and immune checkpoint blockade (ICB)), and the incorporation of adjuvants into the plasmid structure have been studied to enhance the vaccine's immunogenicity and improve the clinical outcome of cancer patients. In this review, we will discuss some of the most promising optimization strategies and examine some of the important trials regarding these vaccines.

Non-Viral Delivery Systems to Transport Nucleic Acids for Inherited Retinal Disorders

Inherited retinal disorders (IRDs) represent a group of challenging genetic conditions that often lead to severe visual impairment or blindness. The complexity of these disorders, arising from their diverse genetic causes and the unique structural and functional aspects of retinal cells, has made developing effective treatments particularly challenging. Recent advancements in gene therapy, especially non-viral nucleic acid delivery systems like liposomes, solid lipid nanoparticles, dendrimers, and polymersomes, offer promising solutions. These systems provide advantages over viral vectors, including reduced immunogenicity and enhanced targeting capabilities. This review delves into introduction of common IRDs such as Leber congenital amaurosis, retinitis pigmentosa, Usher syndrome, macular dystrophies, and choroideremia and critically assesses current treatments including neuroprotective agents, cellular therapy, and gene therapy along with their limitations. The focus is on the emerging role of non-viral delivery systems, which promise to address the current limitations of specificity, untoward effects, and immunogenicity in existing gene therapies. Additionally, this review covers recent clinical trial developments in gene therapy for retinal disorders.

Menthol-based Novel Ultra-Deformable Vesicle: Formulation, Optimization and Evaluation of an Antifungal Drug

The current study aims to establish a novel ultra-deformable vesicular system to enhance the drug penetration across the skin by preparing the ketoconazole-loaded menthosomes. It was achieved through regular thin-film evaporation & hydration techniques. To examine the effect of formulation parameters on menthosome characteristics, a 23 full factorial design was used using Design-Expert® software. The optimized batch exhibited a vesicle size (107.6 nm), a polydispersity index (PDI) (0.248), entrapment efficiency (% EE) (76.9%), and a zeta potential (-33.7 mV). Results from ex vivo skin permeation studies and in vitro drug release demonstrated enhanced improved skin permeation and drug release compared to other formulations. An in vitro antifungal and in vivo pharmacodynamic study, elucidated the enhanced effectiveness of the optimized formulation against Candida albicans. In summary, menthosomes could serve as a potent vehicle to enhance drug penetration via the skin to improve its antifungal activity.

Better blood pressure control with the nanoformulation of antihypertensive drugs

INTRODUCTION

Hypertension is very common and a major risk factor for cardiovascular disease, heart failure, chronic kidney disease, strokes, and death. However, at present only 14% of patients of developing countries have their blood pressure (BP) well controlled. The causes for the failure to control the BP are multiple and one of them could be the formulation of antihypertensive drugs.

AREAS COVERED

The recent development of nanotechnology by incorporating the drugs into nanoparticles is a new promising field of nanomedicine and preliminary studies have shown this nanoformulation to be more effective in the treatment of hypertension than the existing drug formulations. Another recent development is the nanoformulation of genes used for the treatment of hypertension and cardiovascular diseases. For current information, a Medline search was conducted between 2017 and 2024 and 36 pertinent papers were selected.

EXPERT OPINION

The nanoformulations of drugs help achieve better drug concentrations, improve drug stability, low solubility, short half life, oral bioavailability, narrow therapeutic index, and poor pharmacokinetic and pharmacodynamic profiles, and decrease the adverse effects of antihypertensive drugs. Also, the nanoformulation of genes for the treatment of hypertension has been shown in preliminary studies to be effective, but more research is needed.

Contemporary strategies in glioblastoma therapy: Recent developments and innovations

Glioblastoma multiforme (GBM) represents one of the most prevailing and aggressive primary brain tumors among adults. Despite advances in therapeutic approaches, the complex microenvironment of GBM poses significant challenges in its optimal therapy, which are attributed to immune evasion, tumor repopulation by stem cells, and limited drug penetration across the blood-brain barrier (BBB). Nanotechnology has emerged as a promising avenue for GBM treatment, offering biosafety, sustained drug release, enhanced solubility, and improved BBB penetrability. In this review, a comprehensive overview of recent advancements in nanocarrier-based drug delivery systems for GBM therapy is emphasized. The conventional and novel treatment modalities for GBM and the potential of nanocarriers to overcome existing limitations are comprehensively covered. Furthermore, the updates in the clinical landscape of GBM therapeutics are presented in addition to the current status of drugs and patents in the same context. Through a critical evaluation of existing literature, the therapeutic prospect and limitations of nanocarrier-based drug delivery strategies are highlighted offering insights into future research directions and clinical translation.

Vesicular Carriers for Improved Oral Anticoagulation Competence of Rivaroxaban: In Vitro and In Vivo Investigation

Rivaroxaban is an anticoagulant for avoidance and therapy of thromboembolic disorders. Unfortunately, oral bioavailability of rivaroxaban is compromised with dose increments. Accordingly, the aim was to test nano-vesicular lipid systems for improved oral anticoagulation activity of rivaroxaban. Rivaroxaban loaded niosomes, bilosomes and spanlastic formulations were prepared. The prepared systems were assessed in terms of particle size, zeta potential, transition electron microscopic features (TEM), entrapment efficiency, in-vitro drug release, and in-vivo anticoagulation performance in rats. The prepared vesicular systems exposed spherical negatively charged vesicles with mean particle size values between 136.6 nm to 387.9 nm depending on the composition. Rivaroxaban was efficiently entrapped in the vesicular systems with entrapment efficiency values ranging from 92.4% to 94.0%. Rivaroxaban underwent sustained release from the fabricated vesicular systems. The in vivo performance of the tested preparation revealed significant enhancement of the anticoagulation parameters. This was manifested from the prolonged clotting time, and prothrombin time. Moreover, the cut tails of the examined rats receiving the formulated nano-systems exposed a lengthy tail bleeding time compared to those receiving the un-processed rivaroxaban aqueous dispersion. In Conclusion, niosomes, bilosomes and spanlastic nano-dispersions have a potential to overwhelm the oral anticoagulation efficiency of rivaroxaban with spanlastic ranked as best.

Enhanced assembly stability for amine-based cationic glycolipid

Glycolipids incorporating positive charges, mediated by an imidazolium cation, have shown potential for effective formulation of vesicular drug carriers, reflecting repulsive electrostatic forces, promoting the formation of nanosized assemblies and preventing unwanted Oswald ripening (Goh et al. (2019), ACS Omega 4, 17,039). Our continuous development of an assembly-based drug delivery system prompted us to investigate a pH-sensitive analogue, leading to the synthesis of a 6-amino-Guerbet glycoside. However, in contrast to the imidazolium counterpart, the amine-mediated charge increased the intermolecular cohesions, furnishing bigger assemblies instead, which further increased upon introduction of acid. Moreover, assemblies exhibited a significantly reduced positive charge density. It is concluded that strong proton-initiated hydrogen bonding between amino groups provide cohesive head group interactions overcompensating possible repulsive charge interactions. While this behavior invalidates the application of the amino-glucoside as dispersing agent for the formulation of small vesicles, it potentially paves a route towards enhanced vesicle stability.

The treatment of psoriasis via herbal formulation and nano-polyherbal formulation: A new approach

Psoriasis is a chronic condition that can strike at any age. This sickness is associated with inflammatory problems that impact all humans in the world. Psoriasis is more common in Scandinavians than in Asian and African populations due to a combination of factors such as age, gender, geographic location, ethnicity, genetic and environmental factors. Immune stimulation, genetic contribution, antimicrobial peptides, and other significant triggers such as medicines, immunizations, infections, trauma, stress, obesity, alcohol intake, smoking, air pollution, sun exposure, and particular disorders cause psoriasis. Numerous clinical research investigations are now underway, and therapeutic alternatives are available. However, these therapies only improve symptoms and do not accomplish a complete cure; they also have dangerous and undesirable side effects. Natural products have gained popularity recently due to their great effectiveness, safety, and low toxicity. Natural formulations of various nanocarriers like liposomes, lipospheres, nanogels, emulgel, nanostructured lipid carriers, nanosponge, nanofibers, niosomes, nanomiemgel, nanoemulsions, nanospheres, cubosomes, microneedles, nanomicelles, ethosomes, nanocrystals, and foams, have significantly contributed and encouraged advancement in psoriasis disease treatment. These phytochemical-loaded new nanoformulations address several issues associated with natural products in conventional dosage forms, such as instability, poor solubility, and limited bioavailability. This article reviews some of the intriguing phytochemicals, as well as their possible molecular target locations and mechanisms of action, which may assist in the development of more specific and selective antipsoriatic medicines. Exploring and understanding phytochemicals' functions will allow for more site-specific psoriasis treatment techniques. This review concluded the psoriasis disease with phytoconstituent loaded herbal or polyherbal nanocarriers and their mechanistic approach.

Review on novel targeted enzyme drug delivery systems: enzymosomes

The goal of this review is to present enzymosomes as an innovative means for site-specific drug delivery. Enzymosomes make use of an enzyme's special characteristics, such as its capacity to accelerate the reaction rate and bind to a particular substrate at a regulated rate. Enzymosomes are created when an enzyme forms a covalent linkage with a liposome or lipid vesicle surface. To construct enzymosomes with specialized activities, enzymes are linked using acylation, direct conjugation, physical adsorption, and encapsulation techniques. By reducing the negative side effects of earlier treatment techniques and exhibiting efficient medication release, these cutting-edge drug delivery systems improve long-term sickness treatments. They could be a good substitute for antiplatelet medication, gout treatment, and other traditional medicines. Recently developed supramolecular vesicular delivery systems called enzymosomes have the potential to improve drug targeting, physicochemical characteristics, and ultimately bioavailability in the pharmaceutical industry. Enzymosomes have advantages over narrow-therapeutic index pharmaceuticals as focusing on their site of action enhances both their pharmacodynamic and pharmacokinetic profiles. Additionally, it reduces changes in normal enzymatic activity, which enhances the half-life of an enzyme and accomplishes enzyme activity on specific locations.

Bile salt-enriched vs. non-enriched nanoparticles: comparison of their physicochemical characteristics and release pattern

Bile salts were first used in the preparation of nanoparticles due to their stabilizing effects. As time went by, they attracted much attention and were increasingly employed in fabricating nanoparticles. It is well accepted that the physicochemical properties of nanoparticles are influential factors in their permeation, distribution, elimination and degree of effectiveness as well as toxicity. The review of articles shows that the use of bile salts in the structure of nanocarriers may cause significant changes in their physicochemical properties. Hence, having information about the effect of bile salts on the properties of nanoparticles could be valuable in the design of optimal carriers. Herein, we review studies in which bile salts were used in preparing liposomes, niosomes and other nanocarriers. Furthermore, the effects of bile salts on entrapment efficiency, particle size, polydispersity index, zeta potential, release profile and stability of nanoparticles are pointed out. Finally, we debate how to take advantage of bile salts potential for preparing desirable nanocarriers.

A comprehensive review on alpha-lipoic acid delivery by nanoparticles

Alpha-lipoic acid (ALA) has garnered significant attention for its potential therapeutic benefits across a wide spectrum of health conditions. Despite its remarkable antioxidant properties, ALA is hindered by challenges such as low bioavailability, short half-life, and unpleasant odor. To overcome these limitations and enhance ALA's therapeutic efficacy, various nanoparticulate drug delivery systems have been explored. This comprehensive review evaluates the application of different nanoparticulate carriers, including lipid-based nanoparticles (solid lipid nanoparticles, niosomes, liposomes, nanostructured lipid carriers (NLCs), and micelles), nanoemulsions, polymeric nanoparticles (nanocapsules, PEGylated nanoparticles, and polycaprolactone nanoparticles), films, nanofibers, and gold nanoparticles, for ALA delivery. Each nanoparticulate system offers unique advantages, such as improved stability, sustained release, enhanced bioavailability, and targeted delivery. For example, ALA-loaded SLNs demonstrated benefits for skin care products and skin rejuvenation. ALA encapsulated in niosomes showed potential for treating cerebral ischemia, a condition largely linked to stroke. ALA-loaded cationic nanoemulsions showed promise for ophthalmic applications, reducing vascular injuries, and corneal disorders. Coating liposomes with chitosan further enhanced stability and performance, promoting drug absorption through the skin. This review provides a comprehensive overview of the advancements in nanoparticulate delivery systems for ALA, highlighting their potential to overcome the limitations of ALA administration and significantly enhance its therapeutic effectiveness. These innovative approaches hold promise for the development of improved ALA-based treatments across a broad spectrum of health conditions.

Niosome as a promising tool for increasing the effectiveness of anti-inflammatory compounds

Niosomes are drug delivery systems with widespread applications in pharmaceutical research and the cosmetic industry. Niosomes are vesicles of one or more bilayers made of non-ionic surfactants, cholesterol, and charge inducers. Because of their bilayer characteristics, similar to liposomes, niosomes can be loaded with lipophilic and hydrophilic cargos. Therefore, they are more stable and cheaper in preparation than liposomes. They can be classified into four categories according to their sizes and structures, namely small unilamellar vesicles (SUVs), large unilamellar vesicles (LUVs,), multilamellar vesicles (MLVs), and multivesicular vesicles (MVVs). There are many methods for niosome preparation, such as thin-film hydration, solvent injection, and heating method. The current study focuses on the preparation methods and pharmacological effects of niosomes loaded with natural and chemical anti-inflammatory compounds in kinds of literature during the past decade. We found that most research was carried out to load anti-inflammatory agents like non-steroidal anti-inflammatory drugs (NSAIDs) into niosome vesicles. The studies revealed that niosomes could improve anti-inflammatory agents' physicochemical properties, including solubility, cellular uptake, stability, encapsulation, drug release and liberation, efficiency, and oral bioavailability or topical absorption. See also the graphical abstract(Fig. 1).

Nanotechnology-based Nose-to-brain Delivery in Epilepsy: A NovelApproach to Diagnosis and Treatment

Epilepsy is a serious neurological disease, and scientists have a significant challenge in developing a noninvasive treatment for the treatment of epilepsy. The goal is to provide novel ideas for improving existing and future anti-epileptic medications. The injection of nano treatment via the nose to the brain is being considered as a possible seizure control method. Various nasal medicine nanoformulations have the potential to cure epilepsy. Investigations with a variety of nose-to-brain dosing methods for epilepsy treatment have yielded promising results. After examining global literature on nanotechnology and studies, the authors propose nasal administration with nanoformulations as a means to successfully treat epilepsy. The goal of this review is to look at the innovative application of nanomedicine for epilepsy treatment via nose-to-brain transfer, with a focus on the use of nanoparticles for load medicines. When nanotechnology is combined with the nose to brain approach, treatment efficacy can be improved through site specific delivery. Furthermore, this technique of administration decreases adverse effects and patient noncompliance encountered with more traditional procedures.

Recent Updates on Nanocarriers for Drug Delivery in Posterior Segment Diseases with Emphasis on Diabetic Retinopathy

In recent years, various conventional formulations have been used for the treatment and/or management of ocular medical conditions. Diabetic retinopathy, a microvascular disease of the retina, remains the leading cause of visual disability in patients with diabetes. Currently, for treating diabetic retinopathy, only intraocular, intravitreal, periocular injections, and laser photocoagulation are widely used. Frequent administration of these drugs by injections may lead to serious complications, including retinal detachment and endophthalmitis. Although conventional ophthalmic formulations like eye drops, ointments, and suspensions are available globally, these formulations fail to achieve optimum drug therapeutic profile due to immediate nasolacrimal drainage, rapid tearing, and systemic tearing toxicity of the drugs. To achieve better therapeutic outcomes with prolonged release of the therapeutic agents, nano-drug delivery materials have been investigated. These nanocarriers include nanoparticles, solid lipid nanoparticles (SLN), nanostructured lipid carriers (NLC), dendrimers, nanofibers, in-situ gel, vesicular carriers, niosomes, and mucoadhesive systems, among others. The nanocarriers carry the potential benefits of site-specific delivery and controlled and sustained drug release profile. In the present article, various nanomaterials explored for treating diabetic retinopathy are reviewed.

A Comprehensive Review on Niosomes as a Tool for Advanced Drug Delivery

Over the past few decades, advancements in nanocarrier-based therapeutic delivery have been significant, and niosomes research has recently received much interest. The self-assembled nonionic surfactant vesicles lead to the production of niosomes. The most recent nanocarriers, niosomes, are self-assembled vesicles made of nonionic surfactants with or without the proper quantities of cholesterol or other amphiphilic molecules. Because of their durability, low cost of components, largescale production, simple maintenance, and high entrapment efficiency, niosomes are being used more frequently. Additionally, they enhance pharmacokinetics, reduce toxicity, enhance the solubility of poorly water-soluble compounds, & increase bioavailability. One of the most crucial features of niosomes is their controlled release and targeted diffusion, which is utilized for treating cancer, infectious diseases, and other problems. In this review article, we have covered all the fundamental information about niosomes, including preparation techniques, niosomes types, factors influencing their formation, niosomes evaluation, applications, and administration routes, along with recent developments.

Nanotechnological Advancements for the Theranostic Intervention in Anaplastic Thyroid Cancer: Current Perspectives and Future Direction

Anaplastic thyroid cancer is the rarest, most aggressive, and undifferentiated class of thyroid cancer, accounting for nearly forty percent of all thyroid cancer-related deaths. It is caused by alterations in many cellular pathways like MAPK, PI3K/AKT/mTOR, ALK, Wnt activation, and TP53 inactivation. Although many treatment strategies, such as radiation therapy and chemotherapy, have been proposed to treat anaplastic thyroid carcinoma, they are usually accompanied by concerns such as resistance, which may lead to the lethality of the patient. The emerging nanotechnology-based approaches cater the purposes such as targeted drug delivery and modulation in drug release patterns based on internal or external stimuli, leading to an increase in drug concentration at the site of the action that gives the required therapeutic action as well as modulation in diagnostic intervention with the help of dye property materials. Nanotechnological platforms like liposomes, micelles, dendrimers, exosomes, and various nanoparticles are available and are of high research interest for therapeutic intervention in anaplastic thyroid cancer. The pro gression of the disease can also be traced by using magnetic probes or radio-labeled probes and quantum dots that serve as a diagnostic intervention in anaplastic thyroid cancer.

A Comprehensive Review on Niosomes as a Strategy in Targeted Drug Delivery: Pharmaceutical, and Herbal Cosmetic Applications

Niosomes are newly developed, self-assembling sac-like transporters that deliver medication at a specific site in a focused manner, increasing availability in the body and prolonging healing effects. Niosome discovery has increased drugs' therapeutic effectiveness while also reducing adverse effects. This article aims to concentrate on the increase in the worldwide utilization of niosomal formulation. This overview presents a thorough perspective of niosomal investigation up until now, encompassing categories and production techniques, their significance in pharmaceutical transportation, and cosmetic use. The thorough literature review revealed that extensive attention has been given to developing nanocarriers for drug delivery as they hold immense endeavor to attain targeted delivery to the affected area simultaneously shielding the adjacent healthy tissue. Many reviews and research papers have been published that demonstrate the interest of scientists in niosomes. Phytoconstituents, which possess antioxidant, antibiotic, anti-inflammatory, wound healing, anti-acne, and skin whitening properties, are also encapsulated into niosome. Their flexibility allows for the incorporation of various therapeutic agents, including small molecules, proteins, and peptides making them adaptable for different types of drugs. Niosomes can be modified with ligands, enhancing their targeting capabilities. A flexible drug delivery mechanism provided by non-ionic vesicles, which are self-assembling vesicular nano-carriers created from hydrating non-ionic surfactant, cholesterol, or amphiphilic compounds along comprehensive applications such as transdermal and brain-targeted delivery.

Applications of Nanotechnology-mediated Herbal Nanosystems for Ophthalmic Drug

In recent years, herbal nanomedicines have gained tremendous popularity for novel drug discovery. Nanotechnology has provided several advances in the healthcare sector, emerging several novel nanocarriers that potentiate the bioavailability and therapeutic efficacy of the herbal drug. The recent advances in nanotechnology with accelerated strategies of ophthalmic nanosystems have paved a new path for overcoming the limitations associated with ocular drug delivery systems, such as low bioavailability, poor absorption, stability, and precorneal drug loss. Ophthalmic drug delivery is challenging due to anatomical and physiological barriers. Due to the presence of these barriers, the herbal drug entry into the eyes can be affected when administered by following multiple routes, i.e., topical, injectables, or systemic. However, the advancement of nanotechnology with intelligent systems enables the herbal active constituent to successfully entrap within the system, which is usually difficult to reach employing conventional herbal formulations. Herbal-loaded nanocarrier drug delivery systems demonstrated enhanced herbal drug permeation and prolonged herbal drug delivery. In this current manuscript, an extensive search is conducted for original research papers using databases Viz., PubMed, Google Scholar, Science Direct, Web of Science, etc. Further painstaking efforts are made to compile and update the novel herbal nanocarriers such as liposomes, polymeric nanoparticles, solid lipid nanoparticles, nanostructure lipid carriers, micelles, niosomes, nanoemulsions, dendrimers, etc., which are mostly used for ophthalmic drug delivery system. This article presents a comprehensive survey of diverse applications used for the preventative measures and treatment therapy of varied eye disorders. Further, this article highlights the recent findings that the innovators are exclusively working on ophthalmic nanosystems for herbal drug delivery systems. The nanocarriers are promising drug delivery systems that enable an effective and supreme therapeutic potential circumventing the limitations associated with conventional ocular drug delivery systems. The nanotechnology-based approach is useful to encapsulate the herbal bioactive and prevent them from degradation and therefore providing them for controlled and sustained release with enhanced herbal drug permeation. Extensive research is still being carried out in the field of herbal nanotechnology to design an ophthalmic nanosystem with improved biopharmaceutical properties.

Stability of polymeric cationic niosomes and their plasmid DNA-based complexes as gene delivery carriers

This study aims to explore the stability of lipo-polymeric niosomes/niosome-based pCMS-EGFP complexes under different storage temperatures (25 °C, 4 °C, and -20 °C). To date, the question of nucleic acid-complex stability is one of the most vital issues in gene delivery applications. The need for stable vaccines during the COVID-19 pandemic has merely highlighted it. In the case of niosomes as gene carriers, the scientific literature still lacks comprehensive stability studies. In this study, the physicochemical features of niosomes/nioplexes in terms of size, surface charge, and polydispersity index (PDI), along with transfection efficiency, and cytotoxicity in NT2 cells were evaluated for 8 weeks. Compared to day 0, the physicochemical features of the niosomes stored at 25 °C and -20 °C changed dramatically in terms of size, zeta potential, and PDI, while remaining in reasonable values when stored at 4 °C. However, niosomes and nioplexes stored at 4 °C and -20 °C showed nearly stable transfection efficiency values, yet an obvious decrease at 25 °C. This article provides a proof of concept into the stability of polymeric cationic niosomes and their nioplexes as promising gene delivery vehicles. Moreover, it highlights the practical possibility of storing nioplexes at 4 °C for up to 2 months, as an alternative to niosomes, for gene delivery purposes.

A green-based approach for noninvasive skin rejuvenation: Potential application of hyaluronic acid

Gradually, loss of skin elasticity and elastic properties occurs after 30 years of age and will be associated with several changes, including creating wrinkles, skin laxity (sagging skin), and skin blemishes. In general, people all over the world are looking for ways to keep their facial skin young over time. There are several strategies to skin rejuvenate, including invasive and non-invasive methods. However, invasive methods have less popularity than non-invasive methods due to their need for specialist physicians (medical expertise), localized neuropathic pains for patients, the prevalence and incidence of skin infections, and high-cost clinical services. In the meantime, skin hydration is one of the simplest non-invasive methods for skin rejuvenation, and HA, with anti-aging and skin collagen-stimulating properties, has been introduced as a natural skin moisturizing agent. Therefore, since this composition maintains facial skin moisture and radiance, and improves its elasticity, it has always been considered by experts and specialist physicians. On the other hand, due to its lipophilic properties, hydrophilic macromolecules containing HA cannot pass through the stratum corneum. However, they have temporary and superficial softening effects on the skin. Hence, some nanocarriers have been suggested to overcome this problem and develop the properties and positive influences of HA on skin rejuvenation. Therefore, the present study aimed to introduce some new non-invasive approaches in facial skin rejuvenation, including applying liposomes, niosomes, ethosomes, and ionic liquids, to transport HA into the inner and deeper layers of the skin, including Dermis. In this review article, we examine non-invasive methods using nanoparticles to deliver HA to the epidermis and dermis of the skin for skin rejuvenation.

Eco-friendly preparation, characterization, evaluation of anti-melanogenesis/antioxidant effect and in vitro/in vivo safety profile of kojic acid loaded niosome as skin lightener preparation

In the current study, an ultrasonic approach (as green method) was utilized to prepared kojic acid niosome (kojisome) which aimed to increase the dermal delivery and improving anti-melanogenesis properties. The study's findings demonstrated that increasing cholesterol enhanced the mean particle size from 68.333 ± 5.686 nm to 325.000 ± 15.099 nm and entrapment efficiency 0% to 39.341 ± 4.126% of the kojisome. Cholesterol may enhance the number and rigidity of bilayers that induced a size enhancement and entrapment efficiency. The skin permeability test revealed that kojisome gel had more kojic acid in dermal layers (437.563 ± 29.857 μg/cm2 or 16.624 ± 1.379%) than kojic acid plain gel (161.290 ± 14.812 μg/cm2 or 6.128 ± 0.672%). The niosome's lipophilicity allowed for gradual penetration, possibly due to better contact with the skin layers. Also, the extended-release behavior of improved kojisome exhibited high safety profile and low side effect in In vitro cytotoxicity assay, dermal irritation test, and Histo-pathological evaluation. Furthermore, optimum kojisome inhibited melanin formation (53.093 ± 2.985% at 1000 µM) higher than free kojic acid (62.383 ± 1.958%) significantly (p < 0.05). In addition, Kojisome 6 inhibited L-dopa auto-oxidation greater extent (94.806 ± 2.411%) than pure kojic acid solution (72.953 ± 2.728%). Kojisome by delivering and targeting large amount of kojic acid on specific site causes high efficacy in inhibition of melanin synthesis. The observations of this study revealed that the produced kojisome might be used as a potential nano-vehicle for kojic acid dermal administration, thereby opening up innovative options for the treatment of hyperpigmentation problems.

Gout therapeutics and drug delivery

Gout is a common inflammatory arthritis caused by persistently elevated uric acid levels. With the improvement of people's living standards, the consumption of processed food and the widespread use of drugs that induce elevated uric acid, gout rates are increasing, seriously affecting the human quality of life, and becoming a burden to health systems worldwide. Since the pathological mechanism of gout has been elucidated, there are relatively effective drug treatments in clinical practice. However, due to (bio)pharmaceutical shortcomings of these drugs, such as poor chemical stability and limited ability to target the pathophysiological pathways, traditional drug treatment strategies show low efficacy and safety. In this scenario, drug delivery systems (DDS) design that overcome these drawbacks is urgently called for. In this review, we initially describe the pathological features, the therapeutic targets, and the drugs currently in clinical use and under investigation to treat gout. We also comprehensively summarize recent research efforts utilizing lipid, polymeric and inorganic carriers to develop advanced DDS for improved gout management and therapy.

Nanovesicular-Mediated Intranasal Drug Therapy for Neurodegenerative Disease

Numerous neurodegenerative conditions, such as Alzheimer's, Huntington's, Parkinson's, amyotrophic lateral sclerosis, and glioblastoma multiform are now becoming significant concerns of global health. Formulation-related issues, physiological and anatomical barriers, post-administration obstacles, physical challenges, regulatory limitations, environmental hurdles, and health and safety issues have all hindered successful delivery and effective outcomes despite a variety of treatment options. In the current review, we covered the intranasal route, an alternative strategic route targeting brain for improved delivery across the BBB. The trans-nasal pathway is non-invasive, directing therapeutics directly towards brain, circumventing the barrier and reducing peripheral exposure. The delivery of nanosized vesicles loaded with drugs was also covered in the review. Nanovesicle systems are organised in concentric bilayered lipid membranes separated with aqueous layers. These carriers surmount the disadvantages posed by intranasal delivery of rapid mucociliary clearance and enzymatic degradation, and enhance retention of drug to reach the site of target. In conclusion, the review covers in-depth conclusions on numerous aspects of formulation of drug-loaded vesicular system delivery across BBB, current marketed nasal devices, significant jeopardies, potential therapeutic aids, and current advancements followed by future perspectives.

Niosome as an Effective Nanoscale Solution for the Treatment of Microbial Infections

Numerous disorders go untreated owing to a lack of a suitable drug delivery technology or an appropriate therapeutic moiety, particularly when toxicities and side effects are a major concern. Treatment options for microbiological infections are not fulfilled owing to significant adverse effects or extended therapeutic options. Advanced therapy options, such as active targeting, may be preferable to traditional ways of treating infectious diseases. Niosomes can be defined as microscopic lamellar molecules formed by a mixture of cholesterol, nonionic surfactants (alkyl or dialkyl polyglycerol ethers), and sometimes charge-inducing agents. These molecules comprise both hydrophilic and hydrophobic moieties of varying solubilities. In this review, several pathogenic microbes such as Staphylococcus aureus, Pseudomonas aeruginosa, Klebsiella pneumoniae, Plasmodium, Leishmania, and Candida spp. have been evaluated. Also, the development of a proper niosomal formulation for the required application was discussed. This review also reviews that an optimal formulation is dependent on several aspects, including the choice of nonionic surfactant, fabrication process, and fabrication parameters. Finally, this review will give information on the effectiveness of niosomes in treating acute microbial infections, the mechanism of action of niosomes in combating microbial pathogens, and the advantages of using niosomes over other treatment modalities.

Phytoconstituents Based Nanomedicines for the Management of Diabetes: A Review

Diabetes mellitus (DM) is a life-threatening multifactorial metabolic syndrome that is still one of the most difficult unsolved health concerns. Different herbal drugs have been proposed to be useful in treating diabetes and its associated complications. Two major obstacles in plant extracts are their limited solubility and bioavailability of lipophilic bioactive components. Applying nanotechnology has opened new avenues to improve solubility, bioavailability, compliance, and efficacy by overcoming the pharmacokinetic and biopharmaceutical obstacles associated with herbal extracts and phytochemicals. Herbal nanomedicines can overcome the drawbacks of conventional therapy of DM, its complications like delayed wound healing, and also decrease the side effects of synthetic drugs. The targeted delivery of herbal nanoparticles employing nano-pumps, nanorobots, smart cells, and nanosized herbal medications is recognized today as one of the most far-reaching discoveries in the therapy of DM. This paper focuses on using nanotechnology and herbal therapies to manage diabetes effectively. The review provides a detailed and up-to-date overview of phytonanoformulations in treating diabetes and its consequences.

Preparation and in vitro investigation of prostate-specific membrane antigen targeted Lycopene loaded niosomes on prostate cancer cells

In this study, it's aimed to develop prostate-specific membrane antigen (PSMA) targeted niosomes with a multifunctional theranostic approach. With this aim, PSMA-targeted niosomes were synthesized by a thin-film hydration method followed by bath sonication. Drug-loaded niosomes (Lyc-ICG-Nio) were coated with DSPE-PEG-COOH (Lyc-ICG-Nio-PEG) and subsequently anti-PSMA antibody conjugated to niosomes (Lyc-ICG-Nio-PSMA) with amide bond formation. Dynamic light scattering (DLS) analysis showed that the hydrodynamic diameter of Lyc-ICG-Nio-PSMA was approximately 285 nm and it was found with transmission electron microscopy (TEM) that the niosome formulation was spherical. Encapsulation efficiency was 45% and %65 upon dual encapsulation of ICG and lycopene. The results of fourier-transform infrared spectroscopy (FTIR) and X-ray photoelectron spectroscopy (XPS) demonstrated that PEG coating and antibody coupling were successfully done. In vitro studies showed that cell viability decreased when lycopene was entrapped into niosomes applied while the total apoptotic cell population rose slightly. When Lyc-ICG-Nio-PSMA was applied to cells, decreased cell viability and enhanced apoptotic effect were seen compared to those for Lyc-ICG-Nio. In conclusion, it was demonstrated that targeted niosomes displayed improved cellular association and decreased cell viability on PSMA+ cells.

On the relationship between the properties of planar structures of non-ionic surfactants and their vesicular analogues - Niosomes

In recent years, the study of niosomes as nanocarriers alternative to liposomes has received increasing attention. In contrast to well-studied liposome membranes, many aspects of the behavior of analogous niosome bilayers have not been studied. This paper considers one of these aspects related to the communication between the physicochemical properties of planar and vesicular objects. We present the first results of comparative studies of Langmuir monolayers of binary and ternary (with cholesterol) mixtures of non-ionic surfactants based on sorbitan esters and niosomal structures assembled from the same materials. The Thin-Film Hydration (TFH) method in the gentle shaking version was used to produce the particles of large sizes, while small unilamellar high quality vesicles with a unimodal distribution of particles were prepared by TFH using ultrasonic treatment and extrusion. An analysis of the structural organization and phase state of monolayers based on compression isotherms and supplemented by thermodynamic calculations, as well as the results of determining the particle morphology, polarity and microviscosity of niosome shells, made it possible to obtain fundamental data on the intermolecular interactions of the components and their packing in shells and to relate these data to the properties of niosomes. This relationship can be used to optimize the composition of niosome membranes and predict the behavior of these vesicular systems. It was shown that cholesterol excess creates regions of bilayers with increased rigidity (like "lipid rafts"), which hinders the process of folding film fragments into small niosomes.

Preparation and physicochemical properties of cisplatin and doxorubicin encapsulated by niosome alginate nanocarrier for cancer therapy

Alginate (AL), in the form of a hydrogel, is extensively used in drug delivery. In the current study, an optimum formulation of alginate-coated niosome-based nanocarriers for co-delivery of doxorubicin (Dox) and cisplatin (Cis) was obtained for the treatment of breast and ovarian cancers in an attempt to decrease drug doses and overcome multidrug resistance. The physiochemical characteristics of uncoated niosomes containing Cis and Dox (Nio-Cis-Dox) compared to alginate-coated niosomes formulation (Nio-Cis-Dox-AL). The three-level Box-Behnken method was examined to optimize the particle size, polydispersity index, entrapment efficacy (%), and percent drug release of nanocarriers. Nio-Cis-Dox-AL showed appropriate encapsulation efficiencies of 65.54 ± 1.25 % and 80.65 ± 1.80 % for Cis and Dox, respectively. Maximum drug release decreased from niosomes in case coated by alginate. Also, the zeta potential value of Nio-Cis-Dox nanocarriers decreased after coating with alginate. In vitro cellular and molecular experiments were performed to investigate the anticancer activity of Nio-Cis-Dox and Nio-Cis-Dox-AL. MTT assay showed the IC₅₀ of Nio-Cis-Dox-AL was much lower than the Nio-Cis-Dox formulations and free drugs. Cellular and molecular assays demonstrated that Nio-Cis-Dox-AL caused significant increase in apoptosis induction rate and cell cycle arrest in MCF-7 and A2780 cancer cells, as compared to Nio-Cis-Dox and free drugs. Also, the Caspase 3/7 activity increased after treatment with coated niosomes compared to uncoated nisomes and the drug-free case. Synergetic cell proliferation inhibitory impacts of Cis and Dox were demonstrated against MCF-7 and A2780 cancer cells. All anticancer experimental data demonstrated that the co-delivery of Cis and Dox through alginate-coated niosomal nanocarriers was effective for ovarian and breast cancer treatment.

An Eco-Friendly and Hopeful Promise Platform for Delivering Hydrophilic Wound Healing Agents in Topical Administration for Wound Disorder: Diltiazem-Loaded Niosomes

Purposes

Calcium channel blockers, such as diltiazem (DLZ), are important drugs for wound repair treatment. This current study used an ultrasonic method to increase the cutaneous delivery of (DLZ) niosomes.

Methods

The impact of the cholesterol:surfactant ratio on the DLZ-loaded niosome formulations was investigated. Differential scanning calorimetry (DSC), powder X-ray diffraction (PXRD), scanning electron microscopy (SEM), attenuated total reflectance-Fourier transform infrared (ATR-FTIR) spectroscopy, drug release, skin sensitivity, animal wound repair model, and histopathological assessment were applied to investigate the characteristics, morphology, and therapeutic effectiveness of the DLZ noisome.

Results

The results showed that changes in the cholesterol:surfactant ratio can influence the zeta potential and the size of the niosome. The maximum entrapment efficiency was observed to be about 94% when the cholesterol content in the formulation was high. The DLZ release studies revealed that the niosomal formulation was released slowly over the course of 24 h. Macroscopic observations of the wound demonstrated that wound closure in the DLZ-niosome-treated group and the commercial brand was equal and higher than in the other groups (gel base, placebo gel, and negative control). Pathological studies described that the wound repair in the DLZ-niosomal gel group was greater than in the other treatment. All the preparations tested for cutaneous irritation on Wistar rats showed the DLZ niosomal gels to be non-irritating.

Conclusion

The findings of this study revealed that the prepared DLZ-niosome could be used as a possible nano-vesicle for DLZ cutaneous delivery thus potentially opening up new prospects for the treatment of wound disorders.

Niosomes for Topical Application of Antioxidant Molecules: Design and In Vitro Behavior

In the present study, gels based on xanthan gum and poloxamer 407 have been developed and characterized in order to convey natural antioxidant molecules included in niosomes. Specifically, the studies were conducted to evaluate how the vesicular systems affect the release of the active ingredient and which formulation is most suitable for cutaneous application. Niosomes, composed of Span 20 or Tween 20, were produced through the direct hydration method, and therefore, borate buffer or a micellar solution of poloxamer 188 was used as the aqueous phase. The niosomes were firstly characterized in terms of morphology, dimensional and encapsulation stability. Afterwards, gels based on poloxamer 407 or xanthan gum were compared in terms of spreadability and adhesiveness. It was found to have greater spreadability for gels based on poloxamer 407 and 100% adhesiveness for those based on xanthan gum. The in vitro diffusion of drugs studied using Franz cells associated with membranes of mixed cellulose esters showed that the use of a poloxamer micellar hydration phase determined a lower release as well as the use of Span 20. The thickened niosomes ensured controlled diffusion of the antioxidant molecules. Lastly, the in vivo irritation test confirmed the safeness of niosomal gels after cutaneous application.

Properties and Applications of Highly Stable Vesicles Formed by Nanoarchitectonics of Amphiphilic Molecules

Vesicles (liposomes and niosomes) are bilayer membranous capsules composed of amphiphilic molecules having aqueous phase in their interior and can encapsulate drug ingredients to act as drug delivery systems, a bio-membrane model, and so on. Vesicles also find their applications in cosmetics and foods industries since they can not only entrap water-soluble substances in their core, but also solubilize oily substances in the bilayer membrane. Almost half a century has passed since the discovery of vesicles by Bangham, and research on their basic properties and applications has been gaining momentum once again. In this article, the preparation and properties of vesicles (liposomes, niosomes) with excellent dispersion stability, especially formed in mixtures of amphiphilic molecules, are reported. Furthermore, the preparation of nano-sized silica hollow particles using vesicles as a structure-directing agent and their application to anti-reflection film are also described.

Preparation and Evaluation of Paclitaxel-Loaded PEGylated Niosomes Composed of Sorbitan Esters

Niosomes are non-ionic surfactant (NIS)-based bilayer vesicles and, like liposomes, have great potential as drug-delivery systems. Our previous study revealed that polyethylene glycol (PEG) niosomes using different sorbitan ester (Span) surfactants (sorbitan monoester, Span 20, 40, 60, 80; sorbitan triester, Span 65) distributed within tumors similarly to PEG liposomes. The aim of this study was to encapsulate efficiently an anti-cancer drug, paclitaxel (PTX) into Span PEG niosomes, and evaluate PTX release profiles and anti-tumor efficacy of PTX-loaded Span PEG niosomes. Niosome sizes ranged between 100-150 nm, and the PTX encapsulation efficiency was more than 50%. All niosomes examined, in the presence of serum, yielded sustained PTX-release profiles. PTX release at 24 and 48 h from Span 80 PEG niosomes was significantly the highest among the other Span PEG niosomes examined. In C26 tumor-bearing mice, PTX-loaded Span 40 PEG niosomes (the lowest PTX release in vitro) suppressed tumor growth while PTX-loaded Span 80 PEG niosomes (the highest PTX release in vitro) did not. Thus, we succeeded in the control of PTX release from Span PEG niosomes by modifying the component of niosomes, and it influenced the effects of drugs loaded into niosomes. This demonstrates that the excellent NIS physicochemical properties of Spans make them an ideal candidate for anti-cancer drug-carrier niosomes.

The effectiveness of ursolic acid niosomes with chitosan coating for prevention of liver damage in mice induced by n-nitrosodiethylamine

Ursolic acid (UA) is a pentacyclic triterpene carboxylic acid which produces various effects, including anti-cancer, hepatoprotective, antioxidant and anti-inflammatory. However, UA demonstrates poor water solubility and permeability. Niosomes have been reported to improve the bioavailability of low water-soluble drugs. This study aimed to investigate the protective action of UA-niosomes with chitosan layers against liver damage induced by N-Nitrosodiethylamine (NDEA). UA niosomes were prepared using a thin layer hydration method, with chitosan being added by vortexing the mixtures. For the induction of liver damage, the mice were administered NDEA intraperitoneally (25 mg/kgBW). They were given niosomes orally (11 mg UA/kgBW) seven and three days prior to NDEA induction and subsequently once a week with NDEA induction for four weeks. The results showed that chitosan layers increased the particle sizes, PDI, and ζ-potentials of UA niosomes. UA niosomes with chitosan coating reduced the SGOT and SGPT level. The histopathological evaluation of liver tissue showed an improvement with reduced bile duct inflammation and decreasing pleomorphism and enlargement of hepatocyte cell nuclei in UA niosomes with the chitosan coating treated group. It can be concluded that UA niosomes with chitosan coating improved the efficacy of preventive UA therapy in liver-damaged mice induced with NDEA.

Engineered hyaluronic acid-decorated niosomal nanoparticles for controlled and targeted delivery of epirubicin to treat breast cancer

Targeted drug delivery systems using nanocarriers offer a versatile platform for breast cancer treatment; however, a robust, CD44-targeted niosomal formulation has not been developed and deeply studied (both in vitro and in vivo) yet. Here, an optimized system of epirubicin (Epi)-loaded niosomal nanoparticles (Nio) coated with hyaluronic acid (HA) has been engineered for targeting breast cancer cells. The nanoformulation was first optimized (based on size, polydispersity index, and entrapment efficiency); then, we characterized the morphology, stability, and release behavior of the nanoparticles. Epirubicin release from the HA-coated system (Epi-Nio-HA) showed a 21% (acidic buffer) and 20% (neutral buffer) reduction in comparison with the non-coated group (Epi-Nio). The cytotoxicity and apoptosis results of 4T1 and SkBr3 cells showed an approximately 2-fold increase in the Epi-Nio-HA system over Epi-Nio and free epirubicin, which confirms the superiority of the engineered nanocarriers. Moreover, real-time PCR data demonstrated the down-regulation of the MMP-2, MMP-9, cyclin D, and cyclin E genes expression while caspase-3 and caspase-9 gene expression were up-regulated. Confocal microscopy and flow cytometry studies uncovered the cellular uptake mechanism of the Epi-Nio-HA system, which was CD44-mediated. Furthermore, in vivo studies indicated Epi-Nio-HA decreased mice breast tumor volume by 28% (compared to epirubicin) without side effects on the liver and kidney. Conclusively, our results indicated that the HA-functionalized niosomes provide a promising nanoplatform for efficient and targeted delivery of epirubicin to potentially treat breast cancer.

Evaluation of the skin protective effects of niosomal-entrapped annona squamosa against UVA irradiation

Annona squamosa is a medicinal plant that has been used in folk medicine since antiquity. The goal of this study is to see how effective Annona squamosa leaf extract (A.S.L.E) or its niosomal-entrapped preparation is at protecting skin from UVA irradiation. The prepared niosomal-entrapped A.S.L.E has been characterized via spectrophotometry and transmission electron microscopy imaging. Furthermore, the entrapment efficiency and in vitro release of A.S.L.E were determined. In this study, ex vivo and freshly prepared samples from the dorsal region of the rats' skin were used as biological samples, which were divided into five groups: control UVA-unexposed, unprotected UVA-exposed, A.S.L.E-protected UVA-exposed, and niosomal-entrapped A.S.L.E UVA-exposed. UVA irradiation was performed by exposing the skin samples to a UVA-producing lamp for 4 h. Samples from various groups were then examined using FTIR spectroscopy, histopathology, and protein electrophoresis methods. The results showed that A.S.L.E has a skin protective effect against UVA irradiation. The niosomal-entrapped A.S.L.E was more effective than the native plant leaf extract in protecting skin from the damaging effects of UVA. Therefore, the nanotechnologically formulated preparation, niosomal-entrapped A.S.L.E, can be used as an effective photoprotector (sunscreen) against the adverse effects of UVA radiation.

Novel Mucoadhesive Chitosomes as a Platform for Enhanced Oral Bioavailability of Cinnarizine

PURPOSE

Cinnarizine (CIN) is a class II BSC drug, suffering from erratic bioavailability due to its pH-dependent solubility. It has preferential absorption in the stomach. In this study, new chitosan (CS) coated niosomes of CIN (CIN-loaded chitosomes) have been developed to extend the gastric retention and ameliorate CIN oral bioavailability.

METHODS

Various CIN-loaded niosomes were fabricated by thin-film hydration technique and fully characterized. Based on the predetermined criteria of low particle size (PS) and high entrapment efficiency percent (EE%), niosomal formulation F1 was selected and further coated with different CS concentrations. The optimized chitosomal formulation (C2) was evaluated through solid state characterization and mucoadhesive efficiency testing. It was also subjected to cytotoxicity study on Caco-2 cells; besides, in vitro drug release, stability and pharmacokinetic studies were assessed.

RESULTS

The optimized chitosomal formulation (C2) exhibited an EE% of 58.30±2.75%, PS of 440 ±13.03 nm, PDI of 0.335±0.21 and ZP of +28.1±0.10 mv. Solid state characterization results revealed the compatibility between the vesicle components and the entrapment of CIN within niosomal vesicles. C2 formulation demonstrated favorable mucoadhesive efficiency. The cytotoxicity study on Caco-2 cells manifested the safety of the optimized chitosomal formulation (C2) over the free drug. Additionally, it displayed a remarkable sustaining of CIN in vitro release up to 8 h and exhibited a good stability at the refrigerated temperature up to 3 months. In vivo pharmacokinetic assessment revealed that the CIN bioavailability from the optimized chitosomal formulation C2 was enhanced by 2.79 and 1.92 folds compared to the free drug and uncoated niosomal formulation F1, respectively. The priority of the chitosomal formulation (C2) over the niosomal one (F1) was also conferred.

CONCLUSION

Novel formulation of chitosan coated niosomes (chitosomes) could be presented as a promising platform to improve the oral bioavailability of drugs with narrow absorption window.