Nanotechnology-Powered Meningitis Therapies: Lipid Nanoparticles Lead the Way.

The meninges serve as a protective layer, and the fluid around the brain and spinal cord can become inflamed, known as meningitis. Lipid-based pharmaceutical formulations, by their high lipophilicity, can negotiate the Blood-Brain Barrier (BBB). The current mode of treatment of meningitis is mainly through antibiotics, which, at best, is partially effective. The success of antibiotic therapy depends on several factors, for example, the difficulty of reaching the infection site, maintaining proper concentrations of the drug after crossing the BBB, and finally, its efficacy in preventing recurrent infection. In this context, interest has focused on organic and inorganic nanostructures for meningitis and transporting antibiotics to the selected region through the BBB. A focus has also been placed on several polymeric nanotechnology techniques for detecting various types of meningitis. This review focuses on nano interventions and their most recent meningitis treatments using nanotechnology.

Advanced Targeted Drug Delivery of Bioactive Agents Fortified with Graft Chitosan in Management of Cancer: A Review.

Cancer is characterized by the uncontrolled proliferation and spread of abnormal cells in the body, resulting in the development of tumors or clusters of irregular cells. The factors contributing to cancer are intricate, involving a combination of genetic, environmental, and lifestyle elements. Risk factors for cancer include the use of nicotine, excessive alcohol consumption, exposure to radiation or specific chemicals, and a family history of the disease. Common treatment methods for cancer encompass surgery, radiation therapy, chemotherapy, immunotherapy, and targeted therapy. These treatments aim to eliminate cancer cells while minimizing harm to healthy cells. Recent research has extensively explored the potential of bioactive compounds as agents for combating cancer. However, effectively delivering such compounds to specific target sites is a complex undertaking. Consequently, there has been widespread exploration of polymer applications in the development of nanomedicine for delivering bioactive substances. Additionally, the technique of grafting native excipients onto polymers has been investigated to enhance their versatility in the delivery of these compounds to specific tumor cells. This review offers a brief yet informative summary of how grafted chitosan is employed as a delivery system for bioactive phytopharmaceuticals possessing anticancer properties. In essence, it delves into the use of grafted chitosan in facilitating the transport and targeted release of these natural compounds that have demonstrated potential in combating cancer. This innovative approach has the potential to enhance the effectiveness of anticancer treatments and minimize their adverse effects on healthy cells.

Chitosan-Based Hydrogel in the Management of Dermal Infections: A Review.

The main objective of this review is to provide a comprehensive overview of the current evidence regarding the use of chitosan-based hydrogels to manage skin infections. Chitosan, a naturally occurring polysaccharide derived from chitin, possesses inherent antimicrobial properties, making it a promising candidate for treating various dermal infections. This review follows a systematic approach to analyze relevant studies that have investigated the effectiveness of chitosan-based hydrogels in the context of dermal infections. By examining the available evidence, this review aims to evaluate these hydrogels' overall efficacy, safety, and potential applications for managing dermal infections. This review's primary focus is to gather and analyze data from different recent studies about chitosan-based hydrogels combating dermal infections; this includes assessing their ability to inhibit the growth of microorganisms and reduce infection-related symptoms. Furthermore, this review also considers the safety profile of chitosan-based hydrogels, examining any potential adverse effects associated with their use. This evaluation is crucial to ensure that these hydrogels can be safely utilized in the management of dermal infections without causing harm to patients. The review aims to provide healthcare professionals and researchers with a comprehensive understanding of the current evidence regarding the use of chitosan-based hydrogels for dermal infection management. The findings from this review can contribute to informed decision-making and the development of potential treatment strategies in this field.

Novel Approaches in the Drug Development and Delivery Systems for Age-Related Macular Degeneration.

The number of patients with ocular disorders has increased due to contributing factors such as aging populations, environmental changes, smoking, genetic abnormalities, etc. Age-related macular degeneration (AMD) is one of the common ocular disorders which may advance to loss of vision in severe cases. The advanced form of AMD is classified into two types, dry (non-exudative) and wet (exudative) AMD. Although several therapeutic approaches are explored for the management of AMD, no approved therapy can substantially slow down the progression of dry AMD into the later stages. The focus of researchers in recent times has been engaged in developing targeted therapeutic products to halt the progression and maintain or improve vision in individuals diagnosed with AMD. The delivery of anti-VEGF agents using intravitreal therapy has found some success in managing AMD, and novel formulation approaches have been introduced in various studies to potentiate the efficacy. Some of the novel approaches, such as hydrogel, microspheres, polymeric nanoparticles, liposomes, implants, etc. have been discussed. Apart from this, subretinal, suprachoroidal, and port delivery systems have also been investigated for biologics and gene therapies. The unmet potential of approved therapeutic products has contributed to several patent applications in recent years. This review outlines the current treatment options, outcomes of recent research studies, and patent details around the novel drug delivery approach for the treatment of AMD.

Phosphatidylcholine (PCL) fortified nano-phytopharmaceuticals for improvement of therapeutic efficacy.

Phytopharmaceuticals, derived from plants, are increasingly recognized for their potential therapeutic benefits. However, their effectiveness is often hindered by challenges such as poor bioavailability, stability, and targeted delivery. In this study, we aimed to address these limitations by developing PCL (phosphatidylcholine) fortified nano-phytopharmaceuticals to enhance therapeutic efficacy. PCL, a biocompatible and biodegradable polymer, was employed to encapsulate the phytopharmaceuticals, thereby improving their stability and bioavailability. The encapsulation process utilized nanoprecipitation, resulting in the formation of nanoparticles with controlled size and morphology. Various analytical techniques were employed to characterize the physicochemical properties of PCL fortified nano-phytopharmaceuticals, including dynamic light scattering, scanning electron microscopy, and Fourier-transform infrared spectroscopy. Furthermore, the release kinetics of encapsulated phytopharmaceuticals from PCL nanoparticles were evaluated, demonstrating sustained and controlled release profiles, essential for prolonged therapeutic effects. Cytotoxicity studies conducted on in vitro cell culture models confirmed the biocompatibility and non-toxic nature of the developed nano-phytopharmaceuticals. Additionally, in vivo studies were conducted to assess the therapeutic efficacy of PCL fortified nano-phytopharmaceuticals in animal models. The results showIased improved bioavailability, targeted tissue distribution, and enhanced therapeutic effects compared to free phytopharmaceuticals. Moreover, the developed nano-phytopharmaceuticals exhibited prolonged circulation time in the bloodstream, enabling improved drug delivery and reduced dosing frequency. This review highlights the promising potential of PCL fortified nano-phytopharmaceuticals as an effective approach for enhancing the therapeutic efficacy of phytopharmaceuticals. The improved stability, bioavailability, sustained release, and targeted delivery achieved through this formulation strategy offer promising opportunities for advancing plant-based therapies. See also the Graphical abstract(Fig. 1).

Design and optimization of curcumin loaded nano lipid carrier system using Box-Behnken design.

Herbal antioxidant like curcumin holds great potential to treat neurodegenerative disease like Alzheimer's disease. However, its therapeutic potency is obstructed due to rapid metabolism, poor solubility, GI susceptibility, enzymatic degradation and lower bioavailability. Thus, the present work aimed to design and optimize curcumin-loaded NLC (CNL) with higher drug entrapment, prolonged release and better stability. CNL was prepared by modified melt emulsification method followed by ultrasonication. The formulation was optimized by 3 factor 3 level Box-Behnken design using solid: liquid lipid, surfactant concentration and ultrasonication time as independent variable while particle size, entrapment efficiency and % drug release as dependant variable. The design suggested 3.092 solid:liquid lipid, 2.131% surfactant and 4.757 min ultrasonication fit best to get the optimized formulation. The size of the optimized CNL was noted 124.37 ± 55.81 nm, which is in the acceptable range for brain delivery. SEM results also comply with this size range (near 150 nm) and demonstrated almost spherical and uniform particles with porous and uneven surface structures. PDI, zeta potential, entrapment efficiency and % drug release were observed as 0.201 ± 0.00, - 17.2 ± 2.35 mV, 93.62 ± 0.68% and 92.73 ± 0.06%, respectively. The NLC demonstrated initial burst release with subsequent prolonged release of drug for 48 h. Weibull kinetic equation with 0.9958 R2, minimum AIC and maximum MSC value was found best fit to explain the release behavior. The ß exponent and diffusional coefficient (n) indicated combined release mechanism with Fickian diffusion as drug release mechanism. Formulation was also found stable at different storage condition.

Intranasal delivery of topiramate nanoemulsion: Pharmacodynamic, pharmacokinetic and brain uptake studies.

Epilepsy is the noncommunicable and chronic central nervous system disorder characterized by frequent, unprovoked seizures, or electrical disturbances in the brain. Topiramate is used as an antiepileptic drug for the treatment of partial onset seizures, generalized seizures and Lennox-Gastaut Syndrome. Topiramate, a BCS class II drug, has a relatively low bioavailability. It is also a substrate of P-glycoprotein and Blood Brain Barrier restricts its entry into the brain. This investigation was aimed to prepare O/W nanoemulsion delivery system of topiramate to improve its brain bioavailability. Topiramate loaded nanoemulsion was prepared by phase titration method. It was consisting of 2% w/w Capmul MCM C8, 32% w/w Tween 20:Carbitol (2:1) and 66% w/w water. It was characterized for globule size, viscosity, polydispersibility index, zeta potential, pH, conductivity values, transmittance and TEM. Pharmacodynamic, pharmacokinetic and brain drug uptake study was carried out using wistar albino rats post intranasal and oral administration. Topiramate loaded nanoemulsion was having a globule size of 4.73 ± 0.52 nm. It was stable for six months. Brain uptake of topiramate post intranasal administration of topiramate loaded nanoemulsion was significantly (P < 1.86 × 10-8) higher when it was compared with oral administration of topiramate loaded nanoemulsion. This study indicates that intranasal administration of topiramate containing nanoemulsion could be an encouraging approach for the treatment of epilepsy to minimize the dose of topiramate in direction to avoid dose related adverse events.

Nutraceutical regulations: An opportunity in ASEAN countries.

In today's era of increased standards of lifestyle and life expectancy, there has been a constant demand for supplements by consumers. Nutraceuticals are among the supplements in demand. Although there is a big opportunity for the nutraceutical business, there are no uniform regulatory requirements in different regions. Nations are looking to the nutraceutical sector to help keep their populations healthy and safe by introducing certain rules and regulations. Generally, developed countries have regulations in place, but there are some countries, such as those in the Asia Pacific regions or in Association of Southeast Asian Nations (ASEAN) countries, that have not yet fine-tuned their regulations for nutraceutical products. The ASEAN countries involve highly commercialized markets such as Singapore, Thailand, Malaysia, and the Philippines. The overall nutraceutical market of ASEAN countries is growing at a compound annual growth rate of ∼8.4%. About 40% of the ASEAN population consumes nutraceuticals on a daily basis. ASEAN countries are forming harmonized regulations for dietary supplements. This could be a big opportunity for manufacturers to introduce their products into the ASEAN market. A special unit of the Traditional Medicine and Health Supplements Product Working Group (TMHA PWG) helps manufacturers understand the regulatory procedures of these countries. Despite countries' own special requirements, manufacturers can follow the standards and harmonized guidelines put forth by TMHA PWG. The aim of this review is to introduce the regulatory procedure and requirements for international business developers to launch any new nutraceutical products into the ASEAN market.

Recent strategies and advances in the fabrication of nano lipid carriers and their application towards brain targeting.

In last two decades, the lipid nanocarriers have been extensively investigated for their drug targeting efficiency towards the critical areas of the human body like CNS, cardiac region, tumor cells, etc. Owing to the flexibility and biocompatibility, the lipid-based nanocarriers, including nanoemulsion, liposomes, SLN, NLC etc. have gained much attention among various other nanocarrier systems for brain targeting of bioactives. Across different lipid nanocarriers, NLC remains to be the safest, stable, biocompatible and cost-effective drug carrier system with high encapsulation efficiency. Drug delivery to the brain always remains a challenging issue for scientists due to the complex structure and various barrier mechanisms surrounding the brain. The application of a suitable nanocarrier system and the use of any alternative route of drug administration like nose-to-brain drug delivery could overcome the hurdle and improves the therapeutic efficiency of CNS acting drugs thereof. NLC, a second-generation lipid nanocarrier, upsurges the drug permeation across the BBB due to its unique structural properties. The biocompatible lipid matrix and nano-size make it an ideal drug carrier for brain targeting. It offers many advantages over other drug carrier systems, including ease of manufacturing and scale-up to industrial level, higher drug targeting, high drug loading, control drug release, compatibility with a wide range of drug substances, non-toxic and non-irritant behavior. This review highlights recent progresses towards the development of NLC for brain targeting of bioactives with particular reference to its surface modifications, formulations aspects, pharmacokinetic behavior and efficacy towards the treatment of various neurological disorders like AD, PD, schizophrenia, epilepsy, brain cancer, CNS infection (viral and fungal), multiple sclerosis, cerebral ischemia, and cerebral malaria. This work describes in detail the role and application of NLC, along with its different fabrication techniques and associated limitations. Specific emphasis is given to compile a summary and graphical data on the area explored by scientists and researchers worldwide towards the treatment of neurological disorders with or without NLC. The article also highlights a brief insight into two prime approaches for brain targeting, including drug delivery across BBB and direct nose-to-brain drug delivery along with the current global status of specific neurological disorders.

Amalgamation of Stem Cells with Nanotechnology: A Unique Therapeutic Approach.

In the last few years, the stem cell therapy has gained much popularity among researchers and scientists of biomedical field. It became an effective and alternative approach for the treatment of various physiological conditions (like accidental injuries, burn damage, organ failure, bone marrow transfusion, etc.) and chronic disorders (diabetes, cancer, neurodegenerative disorders, periodontal diseases, etc.). Due to the unique ability of cellular differentiation and regeneration, stem cell therapy serves as the last hope for various incurable conditions and severe damages. The amalgamation of stem cell therapy with nanotechnology brings new prospects to the stem cell research, as it improves the specificity of the treatment and controls the stem cell proliferation and differentiation. In this review article, we have discussed various nanocarrier systems such as carbon nanotubes, quantum dots, nanofibers, nanoparticles, nanodiamonds, nanoparticle scaffold, etc. utilized for the delivery of stem cell inside the body.

Recent Biomedical Applications on Stem Cell Therapy: A Brief Overview.

Stem cells are the specialized cell population with unique self-renewal ability and act as the precursor of all the body cells. Broadly, stem cells are of two types one is embryonic stem cells while the other is adult or somatic stem cells. Embryonic stem cells are the cells of zygote of the blastocyst which give rise to all kind of body cells including embryonic cells, and it can reconstruct a complete organism. While the adult stem cells have limited differentiation ability in comparison with embryonic stem cells and it proliferates into some specific kind of cells. This unique ability of the stem cell makes it a compelling biomedical and therapeutic tool. Stem cells primarily serve as regenerative medicine for particular tissue regeneration or the whole organ regeneration in any physical injury or disease condition (like diabetes, cancer, periodontal disorder, etc.), tissue grafting and plastic surgery, etc. Along with this, it is also used in various preclinical and clinical investigations, biomedical engineering and as a potential diagnostic tool (such as the development of biomarkers) for non-invasive diagnosis of severe disorders. In this review article, we have summarized the application of stem cell as regenerative medicine and in the treatment of various chronic diseases.

Nanomedicine for Intranasal Delivery to Improve Brain Uptake.

Intranasal drug delivery system provides distinct advantage over conventional drug delivery system for a drug that is pharmacokenetically or biologically unstable. Major concern for the treatment of central nervous system diseases is, low concentration of therapeutically active molecule within brain as blood brain barrier is creating obstacle, where intranasal drug delivery provides direct transport of therapeutically active moiety into brain via olfactory or trigeminal pathway. Nasal mucosa provides distinct advantages like improved bioavailability, law dose and quick onset of action and high patient compliance, and the major disadvantage is residence time of drug and irreversible entrapment of drug. This article provides anatomical and physiological information about nasal route and various factors. Article discusses various types of nanoparticles used intranasally and moreover article also emphasizes patents, formulation under development and some.

Recent expansion of pharmaceutical nanotechnologies and targeting strategies in the field of phytopharmaceuticals for the delivery of herbal extracts and bioactives.

Application of pharmaceutical nanotechnology (nanomedicines) for plant actives and extracts, is gaining a tremendous growth and interest among the scientists. This emerging herbal revolution has headed towards the development of another approaches for the delivery of poorly soluble herbal bioactives and plant extracts for enhancing their bioavailability and efficacy. In the same context, a majority of pharmaceutical nanotechnologies and targeting strategies including phytosomes, nanoparticles, hydrogels, microspheres, transferosomes and ethosomes, self nano emulsifying drug delivery systems (SNEDDS), self micro emulsifying drug delivery systems (SMEDDS) has been applied for the delivery of bioactives and plant extracts and were identified and explored. These pharmaceutical nanotechnologies have been proven to be the most efficient and reliable delivery systems, as these enhance the solubility, absorption, pharmacokinetics, bioavailability and provide protection from toxicity. Considering these aspects, the present review highlights the present scenario related to the expansion of novel herbal formulations utilizing the nanotechnologies and compilation of their delivery types and mechanism, methodology, loaded drug, drug size, entrapment efficiency of drug, in vivo activity and its application. Moreover, this review article provides an understanding of therapeutic efficacy of the herbal medicines to be loaded into the novel drug delivery system for various biomedical applications.

HPTLC Method for Estimation of Topiramate in Solubility Studies, Diffusion Studies, Plasma, Brain Homogenate and Pharmaceutical Formulation.

Topiramate, 2,3:4,5-bis-O-(1-methylethylidene)-ß-d-fructopyranose, is an anticonvulsant drug indicated in the treatment and control of partial seizures and severe tonic-clonic (grand mal) seizures in adults and children. An economic and rapid high-performance thin-layer chromatographic (HPTLC) method was developed and was validated for the quantitative determination of topiramate in plasma, brain homogenate and pharmaceutical formulation. The simple extraction method was used for the isolation of topiramate from formulation, plasma and brain homogenate samples. HPTLC separation was achieved on an aluminum-backed layer of silica gel 60F254 plates using toluene : acetone (5.0 : 2.0, v/v) as mobile phase. Spots of developed plates were visualized by spraying of reagent [3.0% phenol in the mixture of ethanol : sulfuric acid (95 : 5, v/v)]. Quantitation was achieved by densitometric analysis at 340 nm over the concentration range of 1,000-5,000 ng/spot. The method was found to give compact spot for the drug (Rf: 0.61 ± 0.018). The regression analysis data for the calibration plots showed good relationship with a correlation coefficient of 0.9983. The minimum detectable amount was found to be 165 ng/spot, whereas the limit of quantitation was found to be 500 ng/spot. Statistical analysis of the data showed that the method is precise, accurate, reproducible and selective for the analysis of topiramate. The developed method was successfully employed for the estimation of topiramate in samples of equilibrium solubility study, diffusion study, microemulsion formulation and suspension formulation (developed in-house), rat plasma and rat brain homogenate samples.

Nanoemulsions for Intranasal Delivery of Riluzole to Improve Brain Bioavailability: Formulation Development and Pharmacokinetic Studies.

BACKGROUND: Amyotrophic Lateral Sclerosis (ALS), a motor neuron disease (MND), is a progressive neurodegenerative disorder characterized by the deterioration of both upper and lower motor neurons. Only one drug (riluzole) has been approved for the treatment of ALS. Riluzole is a BCS class II drug having 60% absolute bioavailability. It is a substrate of P-glycoprotein and BBB restricts its entry in brain. OBJECTIVE: This investigation was aimed to develop O/W nanoemulsion system of riluzole to improve its brain bioavailability. METHODS: Riluzole loaded nanoemulsion was prepared by phase titration method. It was consisting of 3% w/w Sefsol 218, 28.3% w/w Tween 80:Carbitol (1:1) and 68.7% w/w water. It was characterized for drop size, drop size distribution, transmittance, viscosity, pH, zeta potential, conductivity and nasal ciliotoxicity study. Thermodynamic stability and room temperature stability of prepared nanoemulsion formulation were evaluated. Pharmacokinetic and brain uptake study was carried out using albino rats (wistar) post intranasal and oral administration. RESULTS: Riluzole loaded nanoemulsion was having a drop size of 23.92±0.52 nm. It was free from nasal ciliotoxicity and stable for three months. Brain uptake of riluzole post intranasal administration of riluzole loaded nanoemulsion was significantly (P <4.10 × 10-6) higher when it was compared with oral administration of riluzole loaded nanoemulsion. CONCLUSION: This study indicates that nanoemulsion of riluzole for intranasal administration could be a promising approach for the treatment of ALS to minimize the dose of riluzole in order to avoid dose related adverse events.

Recent expansions in an emergent novel drug delivery technology: Emulgel.

Emulgel is an emerging topical drug delivery system to which if more effort is paid towards its formulation & development with more number of topically effective drugs it will prove a boon for derma care & cosmetology. Emulgels are either emulsion of oil in water or water in oil type, which is gelled by mixing it with gelling agent. Incorporation of emulsion into gel increases its stability & makes it a dual control release system. Due to lack of excess oily bases & insoluble excipients, it shows better drug release as compared to other topical drug delivery system. Presence of gel phase makes it a non greasy & favors good patient compliance. These reviews give knowledge about Emulgel including its properties, advantages, formulation considerations, and its recent advances in research field. All factors such as selection of gelling agent, oil agent, emulsifiers influencing the stability and efficacy of Emulgel are discussed. All justifications are described in accordance with the research work carried out by various scientists. These brief reviews on formulation method have been included. Current research works that carried out on Emulgel are also discussed and highlighted the wide utility of Emulgel in topical drug delivery system. After the vast study, it can be concluded that the Emulgels appear better & effective drug delivery system as compared to other topical drug delivery system. The comprehensive analysis of rheological and release properties will provide an insight into the potential usage of Emulgel formulation as drug delivery system.