Intranasal Drug Delivery Research Articles

EXTH-57. EXPLORING NOVEL ROUTES FOR NON-INVASIVE DRUG ADMINISTRATION: INTRADERMAL DELIVERY FOR THE TREATMENT OF BRAIN TUMORS

Abstract Effective non-invasive drug delivery to brain tumors remains challenging, despite extensive exploration of these methods, due to the blood-brain barrier (BBB). Intranasal drug delivery has emerged as a promising alternative approach, as it circumvents limitations on tumor access imposed by the BBB when administering therapeutics systemically and limits the occurrence of systemic toxic responses to treatment. The intranasal route of administration allows therapeutic access to brain tumors through pathways involving the olfactory and trigeminal nerves (TNs) that connect the nasal passage to the brain. However, effective nose-to-brain delivery is impeded by rapid mucosal drug clearance in the nasal cavity, drug aspiration, and ingestion. Since the TN arises from the brainstem and its branches innervate the facial skin, in addition to muscles, meninges, and respiratory mucosa, we tested the hypothesis that facial intradermal administration targeting the V2 branch of the TN could be an alternative strategy to harness TN-mediated brain delivery to bypass the BBB. Here, we developed Spherical Nucleic Acids (SNAs) consisting of a 15nm spherical gold nanoparticle core functionalized with radially oriented fluorophore-tagged ssDNA as a model therapeutic. We observed the delivery of the SNAs to the brain starting 4 hours post intradermal injection, with the SNA accumulation in the tumor persisting over time. Using ex vivo fluorescent imaging, comprehensive immunofluorescence microscopy, and flow cytometry we confirmed the SNA accumulation in the brain, dura, TN, and cervical lymph nodes. In particular, we demonstrated that SNAs were enriched in the neuronal cell bodies of the trigeminal ganglia and within the epineurium and perineurium of the TN. The SNAs were also enriched in CD45-positive immune cells. In conclusion, this study credentialed facial intradermal administration of SNAs as a promising non-invasive method for brain drug delivery to target intracranial tumors.

Chitosan-coated nanoemulsion for intranasal administration increases temozolomide mucosal permeation, cellular uptake, and In vitro cytotoxicity in glioblastoma multiforme cells

Glioblastoma multiforme (GBM) is the most prevalent and aggressive type of brain cancer in adults. Temozolomide (TMZ) is the chemotherapeutic agent used to treat primary central nervous system tumors. However, TMZ's clinical effectiveness faces several challenges due to its physical-chemical properties and biological features of GBM, such as the blood-brain barrier (BBB). Mucoadhesive nanosystems such as those coated with chitosan represent a promising alternative for optimizing the delivery of therapeutic agents to the central nervous system, as they possess ideal characteristics that enhance their interaction with the intranasal mucosa. We aimed to develop a chitosan-coated nanoemulsion containing temozolomide (CS-NE-TMZ) for nose-to-brain delivery and characterize its physical-chemical and in vitro biological properties. CS-NE-TMZ were obtained by emulsification followed by sonication. The optimized CS-NE-TMZ presented droplet size of 123,4 ± 2,3 nm, polydispersity index of 0.273 ± 0.028, zeta potential of +21,5 ± 0,81 mV, entrapment efficiency of 100 ± 1,91 % and drug loading of 2 ± 0,007 %. An in vitro release study of CS-NE-TMZ showed sustained release for up to 24 h following the Korsmeyer-Peppas model with Fickian diffusion. CS-NE-TMZ demonstrated significantly enhanced ex vivo mucosal permeation, compared to free TMZ, and showed enhanced in vitro cellular uptake, selectively increasing cytotoxicity in U-87MG glioma cells but not in healthy L929 fibroblasts, reinforcing the potential of mucoadhesive nanoemulsions as effective intranasal drug delivery systems for future brain cancer therapies.

Technological Strategies Applied to Pharmaceutical Systems for Intranasal Administration of Drugs Intended for Neurological Treatments: A Review.

The complexity of treating neurological diseases has meant that new strategies have had to be developed to deliver drugs to the brain more efficiently and safely. Intranasal drug delivery is characterized by its ease of administration, safety, and rapid delivery directly from the nose to the brain. Several strategies have been developed to improve the delivery of drugs to the brain via nasal administration. These include the use of mucoadhesive and thermoresponsive polymers and their combination into polymer blends, as well as the use of liposomes, niosomes, and nano- and microemulsions. Therefore, this review focuses on technologies for developing pharmaceutical systems aimed at delivery via the nose to the brain, contributing to new treatments for difficult neurological disorders. Some of the most common and difficult-to-treat neurological conditions, the intranasal route of administration, and the anatomy of the nasal cavity have been discussed, as well as factors that may influence the absorption of drugs administered into the nose. The types of intranasal formulations and the devices that can be used to administer these products are also discussed in this review. Strategies for improving the transport of bioactive agents and increasing bioavailability are highlighted. The technologies discussed in this review can facilitate the development of formulations with improved properties, such as drug release and mucoadhesiveness, which have several advantages for patients requiring complex neurological treatments.

Unveiling the potential of intranasal delivery of renin-angiotensin system drugs: Insights on the pharmacokinetics of irbesartan

The therapeutic interest of renin-angiotensin system (RAS) drugs for the treatment of neuroinflammation has been recently acknowledged. Nevertheless, most RAS drugs display limited passage across the blood–brain barrier (BBB). Therefore, this study investigated the potential of intranasal (IN) delivery of six RAS drugs to circumvent the BBB and attain the brain, envisioning its future use in central nervous system (CNS) neuroinflammatory diseases, such as Alzheimer’s disease (AD).Captopril, enalaprilat, irbesartan, lisinopril, losartan and valsartan were firstly screened based on their impact on the viability of nasal, lung, and neuronal cell lines and their apparent permeability (Papp) across porcine olfactory mucosa. Irbesartan, identified as the one with the best safety and permeability balance, was selected for pharmacokinetic characterization following single and multidose IN administration to CD-1 mice. The results were compared to those obtained by intravenous (IV) injection to assess direct nose-to-brain drug delivery. Olfactory toxicity and anxiety were also evaluated after multidose IN treatment.Irbesartan IN administration significantly enhanced brain targeting, with a 3-fold increase in the maximum concentration (Cmax) and a 2.5-fold increase in the area under the curve (AUCt) in the brain compared to IV route. The drug exhibited a tmax of 15 min post-IN administration and achieved a brain targeting efficiency of 239.56%, with a significant direct transport percentage of 58.26%. Multidose administration indicated no systemic or tissue accumulation, with accumulation ratio (Rac) values below 1.0, and no significant olfactory toxicity.Overall, the study highlights the potential of IN delivery of irbesartan as a promising strategy to improve brain targeting and therapeutic outcomes in CNS diseases such as AD, providing an effective approach to bypass BBB limitations.

DES/O microemulsion for solubilizing and delivering curcumin via the nasal administration to treat acute asthma

As a natural small molecule drug derived from turmeric, curcumin is known for its good biosafety and a range of beneficial effects, including anti-inflammatory, anti-spasmodic, antioxidant, antibacterial, anti-tumor, and neuroprotective effects. Even though, its insolubility in water and instability severely limit its bioavailability and clinical applications. The present study developed a deep eutectic solvent (DES) in oil microemulsion (DES/O-ME) system loaded with Cur for intranasal administration, aiming to enhance both the solubility and permeability of Cur to significantly increase its bioavailability. The project first constructed and screened the optimal choline chloride-based DES. Subsequently, the DES/O-ME system was prepared and optimized to achieve uniform particle size and stability using a pseudo-ternary phase diagram and electrical conductivity measurements. The resulting DES/O-ME system was thoroughly evaluated for its solubilization efficacy, permeability, mucosal cytotoxicity, and stability. Additionally, the therapeutic efficacy of the Cur-DES/O-ME was assessed in vivo using a murine model of allergic asthma. This comprehensive evaluation highlights the potential of the DES/O-ME system as a promising intranasal drug delivery platform to overcome the limitations of curcumin’s bioavailability and clinical application.

Design Formulation of Nanospanlastic Novel Carriers as a Promising Approach to Enhanced Bioavailability in Intranasal Drug Delivery for Sinusitis: Statistical Optimization and In vitro and In vivo Characterization

Background: Most new biologically active chemicals require better water solubility and slower dissolution rates. Cefdinir (CFD) has a very low bioavailability in its crystalline form and is poorly soluble in water. Objective: By preparing cefdinir's spanlastic nanovesicles (SNVs) using the ethanol injection method, the current study has attempted to enhance the drug's solubility and bioavailability using a statistical design approach. Methods: Independent variables, including the nonionic surfactant concentration, edge activator (EA), sonication time, SNVs entrapment efficiency, particle size, zeta potential, PDI, and in vitro release, have been evaluated. The best CFD-SNVs were positioned within in situ gel with muco-adhesive properties made of hydroxypropyl methylcellulose and deacetylated gellan gum. By contrasting intranasal injection of the produced gel with an IV solution, animal models have been used to investigate CFD's systemic and cerebral dynamics. Results: Statistical analysis has suggested an ideal SNVs formulation with nonionic surfactant (65 mg), EA (15 mg), and sonication (3 min). The sol-gel temperature for forming the mucoad-hesive in situ gel containing SNVs has been found to be 34.03°C, and 18.36 minutes has been the extended mucociliary transit time. Following intranasal injection, compared to SNV dispersion, the gelling system has exhibited higher brain bioavailability (2251.9 ± 75 vs. 5281.6 ± 51%, re-spectively). The gel has also demonstrated effective drug targeting of the brain with higher direct transport percentage indices. Conclusion: Mucoadhesive in situ gel with CFD-loaded SNVs can be administered via the in-tranasal route. To enhance bioavailability in the brain and drug targeting from the nose to the brain, nasal in situ gel loaded with CFD-SNVs could be a new carrier to be employed in sinusitis.

Intranasal administration of liposomes: Potential brain delivery with prospective ophthalmic reach

The low efficacy of drug transportation from the bloodstream to specific tissues remains a challenge in drug delivery to the central nervous system (CNS), primarily because of the presence of the blood-brain and blood-retinal barriers. There is a need for non-invasive drug delivery techniques to the CNS given the intrusive nature of and potential patient burden associated with intraventricular, intrathecal, and intravitreal administration. Recently, the focus has shifted towards intranasal (i.e., nose-to-brain) drug delivery. Furthermore, there have been reports indicating that the use of drug nanocarriers, such as liposomes, facilitates efficient drug delivery via the intranasal pathway. This study investigates the brain penetration capabilities of intranasally administered liposomes using the hydrophobic fluorescent molecule, 1,1′-dioctadecyl-3,3,3′,3′-tetramethyl lindodicarbocyanine, 4-chlorobenzene sulfonate salt (DiD), as a model compound. The primary objective of this study was to elucidate the penetration of intranasally administered liposomes into the CNS, including the eyes. An examination of DiD distribution in the dissected brain and ocular tissues showed that DiD concentrations were elevated specifically at the limbus of the ocular tissue when surface-modified liposomes were employed. These findings suggest that intranasal liposome administration can deliver drugs to the posterior ophthalmic region, specifically the optic nerve, in addition to the brain.

Recent opportunities and application of gellan gum based drug delivery system for intranasal route.

In the recent years, in-situ hydrogel based on gellan gum has been investigated for delivery of various drug molecules particularly to treat neurological disorders via intranasal route. The major objective of the present manuscript is to review the recent research studies exploring gellan gum as ionic triggered in-situ gel for intranasal administration to enhance absorption of drugs and to increase their therapeutic efficacy. This review include literature from 1982 to 2023 and were collected from various scientific electronic databases like Scopus, PubMed and Google Scholar to review source, chemistry, ionotropic gelation mechanism, and recent research studies for gellan gum based in-situ hydrogel for intransasl administration.Keywords such as gellan gum, in-situ hydrogel, intranasal administration and brain targeting were used to search literature. The present review included the research studies which explored gellan gum based in-situ gel for intranasal drug delivery. The findings have shown enhanced biavailability of various drugs upon intranasal administration using gellan-gum based in-situ hydrogel.Moreover, the review indicated that intranasal administration of in-situ hydrogel facilitate to overcome blood brain barrier effectively. Hence, significantly higher drug concentration was found to be achieved in brain tissues upon intranasal administration than that of other routes like oral and intravenous. The present work conducted a comprehensive review for gellan gum based in-situ hydrogel particularly for intransal administration to overcome BBB. The study concluded that gellan gum based in-situ hydrogel could be potential promising delivery system for intranasal administration to improve bioavailability and efficacy of drugs specifically to treat neurological disorders.

Preparations, Applications, Patents, and Marketed Formulations of Nanoemulsions - A Comprehensive Review.

Nanoemulsions have emerged as versatile colloidal dispersions with promising applications in various fields, including pharmaceuticals, food, and cosmetics. These nano-sized emulsions, stabilized by surfactants, offer unique advantages such as enhanced ingredient penetration efficacy and versatile dosage forms. This article provides an extensive overview of nanoemulsions, covering their composition, methods of preparation, and applications in drug delivery, the food industry, and cosmetics. Various high-energy and low-energy methods for nanoemulsion preparation are discussed, along with their advantages and limitations. Additionally, the article highlights the potential of nanoemulsions in improving drug bioavailability, stability, and therapeutic efficacy, especially in oral, topical, parenteral, intranasal, ocular, and pulmonary drug delivery. Furthermore, nanoemulsions are explored as carriers for encapsulating flavoring agents, nutraceuticals, and natural preservatives in the food industry, as well as their use in cosmetic formulations. Current clinical trials involving nanoemulsions and recent patents in the field are also summarized, providing insights into ongoing research and development efforts. Lastly, a selection of marketed nanoemulsion formulations is presented, showcasing their practical applications and commercial availability. Overall, nanoemulsions hold great promise as effective delivery systems with broad applications across various industries.

Optimizing the Formula of Polymeric-Based Aripiprazole Nanosuspension Using Response Surface Methodology for Intranasal Drug Delivery

This study aimed to optimize the formula of aripiprazole nanosuspension for intranasal drug delivery. Response Surface Methodology (RSM) was employed to determine the influence of independent variables, including drug concentration, polymer concentration, and the ratio of polymer combination, on the nanosuspension characteristics. The parameters under investigation were particle size (d mean), polydispersity index, and drug content. Fifteen formulas were prepared using the high-shear homogenization–ultrasonication method, and the Design Expert software was applied for optimum formula determination. The result showed significant effects of the independent variables on the nanosuspension characteristics, with particle sizes ranging from 143.6 – 334.6 nm, PDI values of 0.302 – 0.649, and drug content was 98.7 – 102.1 %. The predicted optimum formula had a drug concentration of 28 mg/mL in the organic solvent, polymer concentration of 1.5% (w/v), and HPMC to PVP ratio of 1.4 with desirability of 0.94. Additionally, it exhibited desirable characteristics, such as a particle size of 171.2  11.4 nm, a PDI value of 0.317  0.02, and a high drug content of 100.04  0.65%. In conclusion, the presented methodology appeared to be perfect for the optimization of the aripiprazole nanosuspension formula to ensure suitability for nose-to-brain drug delivery.

Intranasal Nanoemulsion: A Promising Approach for the Management of Parkinson’s Disease

Parkinson's Disease (PD) is a neurodegenerative syndrome defined by the deterioration of dopamine neurons, showing a loss of motor activity. The treatment of PD is still challenging despite the development of numerous management techniques. Blood-brain Barrier (BBB) provides limited access to drug transport, being a major limiting factor in the treatment of Central Nervous System (CNS) disorders. Further, the major challenges in neurodegenerative diseases are low bioavailability and side effects. Intranasal drug delivery has become increasingly accessible for the treatment of several CNS disorders, including PD. The nasal cavity has direct access to the brain and drugs may be delivered at the site of action by bypassing the blood-brain barrier. Therapeutic molecules could be directly delivered to the brain through the olfactory region in the nasal cavity; further, the first-pass effects of drugs could also be eliminated. Several novel and promising developments in non-invasive approaches have been revealed for brain targeting by the nasal route. Among them, Nanoemulsions (NEs)-based drug delivery has been most widely explored, which can assist in several significant issues, such as limited BBB permeability, limited solubility, poor bioavailability, limited onset of action, and less enzymatic degradation. Several research reports have indicated intranasal NEs to have potential brain-targeting abilities, which may be widely explored for the treatment of PD. Therefore, the present review article has focused on the current scenario of intranasal NEs for the management of PD, with recent outcomes outlined through various research studies.

Recent developments in intranasal drug delivery of nanomedicines for the treatment of neuropsychiatric disorders.

Neuropsychiatric disorders are multifaceted syndromes with confounding neurological explanations. It includes anxiety, depression, autism spectrum disorder, attention deficit hyperactivity disorder, schizophrenia, Tourette's syndrome, delirium, dementia, vascular cognitive impairment, and apathy etc. Globally, these disorders occupy 15% of all diseases. As per the WHO, India has one of the largest populations of people with mental illnesses worldwide. The blood-brain barrier (BBB) makes it extremely difficult to distribute medicine to target cells in the brain tissues. However, it is possible through novel advancements in nanotechnology, molecular biology, and neurosciences. One such cutting-edge delivery method, nose-to-brain (N2B) drug delivery using nanoformulation (NF), overcomes traditional drug formulation and delivery limitations. Later offers more controlled drug release, better bioavailability, improved patient acceptance, reduced biological interference, and circumvention of BBB. When medicines are delivered via the intranasal (IN) route, they enter the nasal cavity and go to the brain via connections between the olfactory and trigeminal nerves and the nasal mucosa in N2B. Delivering phytochemical, bioactive and synthetic NF is being investigated with the N2B delivery strategy. The mucociliary clearance, enzyme degradation, and drug translocations by efflux mechanisms are significant issues associated with N2B delivery. This review article discusses the types of neuropsychiatric disorders and their treatment with plant-derived as well as synthetic drug-loaded NFs administered via the IN-delivery system. In conclusion, this review provided a comprehensive and critical overview of the IN applicability of plant-derived NFs for psychiatric disorders.

Intranasal transfersomal based in situ gel for augmenting methylphenidate bioavailability and brain delivery: In vitro and in vivo evaluation

Methylphenidate, a CNS stimulant drug, has poor oral bioavailability due to extensive first-pass effect. In this study, Methylphenidate loaded transfersomes based in situ gel (MPH-TFs Gel) was prepared for brain targeting through intranasal (IN) drug delivery. Methylphenidate transfersomes (MPH-TFs) were prepared using the thin film hydration method. Box-Behnken Design expert software was utilized for the optimization by assessing the effect of independent variables phospholipon 90-G, Tween-80, and Methylphenidate (MPH) on particle size (PS), zeta potential (ZP), Polydispersity index (PDI), and Entrapment Efficiency (EE). The observed mean particle size of the optimized MPH-TFs was found to be 139.7 ± 3.75 nm, mono dispersion with PDI (0.208 ± 0.002), negatively charged (−27.9 ± 0.287 mV) and had an excellent entrapment efficiency (86 ± 3 %). Fourier-Transform Infrared (FTIR) spectra have depicted the compatibility of the components. X-r Diffraction analysis showed the conversion of crystalline structure methylphenidate to amorphous. The optimized MPH-TFs were then subsequently incorporated into an already optimized MPH-TFs Gel. MPH-TFs Gel was then characterized for its physicochemical properties, in vitro and in vivo studies. In vitro release and ex vivo permeation analysis showed sustained release and improved permeation of the MPH-TFs Gel, respectively. Additionally, histopathological studies of nasal membrane affirmed the safety of MPH-TFs Gel after intranasal application. In vivo pharmacokinetic study demonstrated improved brain bioavailability of MPH-TFs Gel compared to orally administered Methylphenidate solution (MPH-Sol).

Exploring nalbuphine loaded chitosan nanoparticles for effective pain management through intranasal administration: a comparative study

Background Intranasal drug delivery shows potential for brain access via olfactory and trigeminal routes. Purpose This work aimed to ensure brain availability of nalbuphine via the nasal route. Method Chitosan based nanoparticles loaded with nalbuphine were successfully prepared using ionic gelation method and characterised. Result SEM results revealed that the nanoparticles were spherical in shape, with an average size of 192.4 ± 11.6 nm. Zeta potential and entrapment efficiency was found 32.8 mV and 88.43 ± 7.75%, respectively. The X-ray diffractometry and DSC results unravel a profound understanding on the physical and thermal characteristics. The in-vitro release of nalbuphine from the nanoparticles was biphasic, with an initial burst release followed by a slow-release profile. In-vitro cell study on HEK-293 cells and microscopic images of brain tissue confirmed the safety profile of formulation. In-vivo efficacy studies on animal confirmed the effectiveness of developed intranasal formulation as compared to the standard therapy. The in-vivo pharmacokinetic studies showed that the prepared nanoparticles were able to efficiently deliver nalbuphine to the brain in comparison to the other body organs. Gamma scintigraphy images showed retention of the drug in the brain. Furthermore, the efficacy studies confirmed that the nanoparticles were found significantly more effective than the marketed formulation in pain management.

Ribavirin in Modern Antitumor Therapy: Prospects for Intranasal Administration.

Ribavirin has been used as an antiviral agent to treat a variety of viral infections since the 1970s. Over the past few decades, studies have been conducted on the pharmacology of ribavirin, and the possibility of its use in new indications has been explored. According to the results of a number of studies, ribavirin efficacy in the therapy of malignant neoplasms of various genesis has been proven. Furthermore, due to the complexity of brain tumor therapy using surgical methods, targeted delivery of ribavirin to the brain becomes a promising alternative to existing treatment methods. Targeting of active pharmaceutical ingredient (API) to the brain tumor is achieved by intranasal drug delivery via a Nose-to-Brain mechanism. In addition, using this delivery mechanism, it is possible to reach the brain while bypassing the blood-brain barrier (BBB), thus avoiding the effects of the first passage through the liver. Despite the significant advantages of the method, there are limiting factors to its application - mucociliary clearance, which aims to remove foreign bodies from the surface of the nasal mucosa. In situ, systems are able to reduce the intensity of interfering factors on API and allow the achievement of maximum bioavailability during intranasal administration.

A Comprehensive Review on the Nanotechnology-based Intranasal Drug Delivery Systems for Brain Targeting

A Comprehensive Review on the Nanotechnology-based Intranasal Drug Delivery Systems for Brain Targeting

Use of process intensification concepts for targeted delivery of inhaled aerosolized medicines

Process intensification (PI) concepts have potential applications beyond the classic industrial problems solved by chemical engineering. This paper discusses the flow and mass transfer intensification using acoustic waves to enhance drug delivery to the nasal cavity. The efficiency of drug delivery to the nose still needs improvement, and the mechanisms related to using acoustic waves to increase it have yet to be studied. The influence of pressure pulsations induced by an acoustic wave (∼100 Hz) on the concentration, droplet size, and flow structure of the mists delivered from medical nebulizers was studied. The direct visualization showed that pulsations intensify aerosol deposition inside narrow channels due to particle displacement perpendicularly to the main flow direction. This motion also allows for particle penetration via narrow openings. UV-assisted observation of the intensified aerosol deposition inside the anatomical cast of the nasal cavity confirmed the importance of acoustic pulsations for intranasal drug delivery, also helping aerosol penetrate hard-to-reach areas (including the paranasal sinuses). A new idea regarding appropriate time control of acoustic pulsations has been proposed to improve the aerosol drug mass transfer in the nose. The study shows that PI has great potential to expand into new and interdisciplinary areas.

Construction of an intranasal drug delivery system with hypothalamus‐targeting nanoparticles

AbstractDysfunction of the hypothalamus is associated with endocrine imbalances, growth abnormalities, and reproductive disorders. However, there is a lack of targeted treatment strategies focused on the hypothalamus. In this study, we constructed a multifunctional nanocarrier system (S@ANP) to directly target the hypothalamic neurokinin receptor 3 (NK3R) via an intranasal delivery strategy. This system could overcome the primary obstacles in drug delivery for hypothalamus‐related diseases. Under the guidance of a modified (Trp7, β‐Ala8)‐neurokinin A (4‐10) peptide with cysteine, nanoparticles encapsulated with SB222200, an NK3R inhibitor, were found to readily penetrate hypothalamic cells with substantial loading capacity, encapsulation efficiency, and sustained release in vitro. Moreover, intranasal delivery represents an optimal delivery strategy that allows for a significant reduction in oral dosage and enables nanoparticles to bypass the blood‒brain barrier and target relevant parts of the brain. The mucolytic agent N‐acetyl‐L‐cysteine (NAC) was loaded into the nanoparticles (S@ANP + NAC) to increase mucosal solubility and intranasal delivery efficiency. In vivo evaluations showed that S@ANP + NAC could effectively target the hypothalamus and modulate NK3R‐regulated hypothalamic functions in mice. Due to its high hypothalamic targeting efficiency and low toxicity, this intranasal nanoparticle drug delivery system may serve as a potential strategy for precision therapy of hypothalamic disorders.

Intranasal delivery of liposome encapsulated flavonoids ameliorates l-DOPA induced dyskinesia in hemiparkinsonian mice

In the present study, we explored the development of a novel noninvasive liposomal drug delivery material for use in intranasal drug delivery applications in human diseases. We used drug entrapment into liposomal nanoparticle assembly to efficiently deliver the drugs to the nasal mucosa to be delivered to the brain. The naturally occurring flavonoid 7,8-dihydroxyflavone (7,8-DHF) has previously been shown to have beneficial effects in ameliorating Parkinson's disease (PD). We used both naturally occurring 7,8-DHF and the chemically modified form of DHF, the DHF-ME, to be used as a drug candidate for the treatment of PD and l-DOPA induced dyskinesia (LID), which is the debilitating side effect of l-DOPA therapy in PD. The ligand-protein interaction behavior for 7,8-DHF and 6,7-DHF-ME was found to be more effective with molecular docking and molecular stimulation studies of flavonoid compounds with TrkB receptor. Our study showed that 7,8-DHF delivered via intranasal route using a liposomal formulation ameliorated LID in hemiparkinsonian mice model when these mice were chronically administered with l-DOPA, which is the only current medication for relieving the clinical symptoms of PD. The present study also demonstrated that apart from reducing the LID, 7,8-DHF delivery directly to the brain via the intranasal route also corrected some long-term signaling adaptations involving ΔFosB and α Synuclein in the brain of dopamine (DA) depleted animals.

Chitosan Nanoparticles for Intranasal Drug Delivery.

This manuscript explores the use of nanostructured chitosan for intranasal drug delivery, targeting improved therapeutic outcomes in neurodegenerative diseases, psychiatric care, pain management, vaccination, and diabetes treatment. Chitosan nanoparticles are shown to enhance brain delivery, improve bioavailability, and minimize systemic side effects by facilitating drug transport across the blood-brain barrier. Despite substantial advancements in targeted delivery and vaccine efficacy, challenges remain in scalability, regulatory approval, and transitioning from preclinical studies to clinical applications. The future of chitosan-based nanomedicines hinges on advancing clinical trials, fostering interdisciplinary collaboration, and innovating in nanoparticle design to overcome these hurdles and realize their therapeutic potential.