Nanostructured lipid carrier to overcome stratum corneum barrier for the delivery of agomelatine in rat brain; formula optimization, characterization and brain distribution study.

The current work attempted to achieve bypassed hepatic metabolism, controlled release, and boosted brain distribution of agomelatine by loading in NLC and administering via transdermal route. Agomelatine-loaded NLC (AG-NLC) was fabricated employing melt-emulsification technique and optimized using central composite design. The optimized AG-NLC had 183.16 ± 6.82 nm particle size, 0.241 ± 0.0236 polydispersity index, and 83.29 ± 2.76% entrapment efficiency. TEM and FESEM visually confirmed the size and surface morphology of AG-NLC, respectively. DSC thermogram confirmed the conversion of AG from crystalline to amorphous form, which indicates improved solubility of AG when loaded in NLC. For further stability and improved applicability, AG-NLC was converted into a hydrogel. The texture analysis of AG-NLC-Gel showed appropriate gelling property in terms of hardness (142.292 g), cohesiveness (0.955), and adhesiveness (216.55 g.sec). In comparison to AG-suspension-Gel (38.036 ± 6.058%), AG-NLC-Gel (89.440 ± 2.586%) exhibited significantly higher (P < 0.005) skin permeation profile during the 24 h study. In the CLSM study, Rhodamine-B loaded AG-NLC-Gel established skin penetration up to the depth of 45 µm, whereas AG-Suspension-Gel was restricted only to a depth of 25 µm. γ-scintigraphy in wistar rats revealed ~ 55.38% brain distribution potential of 99mTc-AG-NLC-Gel at 12 h, which was 6.31-fold higher than 99mTc-AG-Suspension-Gel. Overall, the gamma scintigraphy assisted brain distribution study suggests that NLC-Gel system may improve the brain delivery of agomelatine, when applied transdermally.

A review on chitosan and chitosan-based bionanocomposites: Promising material for combatting global issues and its applications.

Over the last few years, several attempts have been made to replace petrochemical products with renewable and biodegradable components. The most challenging part of this approach is to obtain bio-based materials with properties and functions equivalent to those of synthetic products. Various naturally occurring polymers such as starch, collagen, alginate, cellulose, and chitin represent attractive candidates as they could reduce dependence on synthetic products and consequently positively impact the environment. Chitosan is also a unique bio-based polymer with excellent intrinsic properties. It is known for its anti-bacterial and film-forming properties, has high mechanical strength and good thermal stability. Nanotechnology has also applied chitosan-based materials in its most recent achievements. Therefore, numerous chitosan-based bionanocomposites with improved physical and chemical characteristics have been developed in an eco-friendly and cost-effective approach. This review discusses various sources of chitosan, its properties and methods of modification. Also, this work focuses on diverse preparation techniques of chitosan-based bionanocomposites and their emerging application in various sectors. Additionally, this review sheds light on future research scope with some drawbacks and challenges to motivate the researchers for future outstanding research works.

Poloxamer-407 thickened lipid colloidal system of agomelatine for brain targeting: Characterization, brain pharmacokinetic study and behavioral study on Wistar rats.

The current study was designed to enhance the brain bioavailability and to extract maximum therapeutic benefit from a novel antidepressant drug, agomelatine. For this purpose, a thermoresponsive in situ gel was prepared by dissolving 20% w/v of Poloxamer-407 in agomelatine containing nanoemulsion. To impart mucoadhesive property, 0.5% w/v concentration of chitosan was ensured in the final formulation, named as Ago-NE-gel+0.5%chitosan. The gelling point and mucoadhesive strength of Ago-NE-gel+0.5%chitosan were found to be 28 ± 1 °C, and 6246.27 dynes/cm2 respectively. The size of free micelles of Poloxamer-407 was recorded graphically at 18.43 ± 0.95 nm whereas the size of sterically stabilized Ago-NE was observed at 142.58 ± 4.21 nm. The viscosity and pH of Ago-NE-gel+0.5%chitosan were found to be 2439 ± 23 cP (at 35 ± 1 °C temperature) and 5.8 ± 0.2 respectively. The developed formulation was found safe on nasal mucosa during the toxicity study. CLSM based brain distribution study suggested that Ago-NE-gel+0.5%chitosan is more competent to deliver the drug into the brain as compared to agomelatine-suspension. After intranasal administration of Ago-NE-gel+0.5%chitosan in Wistar rats, the AUC0-8h in brain and plasma were found to be 1418.591 ± 71.87 and 473.901 ± 32.42 ng.h/ml respectively. The hypothesis conceived at the beginning of this research work was delivered as 2.82 folds enhanced bioavailability of agomelatine in the brain. The behavioral studies confirmed that the antidepressant activity of agomelatine can be improved by loading the drug into a mucoadhesive-nanoemulsion-gel system followed by its intranasal administration.

Design and development of letrozole nanoemulsion: A comparative evaluation of brain targeted nanoemulsion with free letrozole against status epilepticus and neurodegeneration in mice.

The target of the current study is to formulate letrozole loaded nanoemulsion (LET-NE) for the direct nose to brain delivery to reduce peripheral effects of letrozole (LET). LET-NE is compared against intraperitoneally administered free LET in kainic acid (KA) induced status epilepticus (SE) in mice. LET loaded nanoemulsion (LET-NE) was prepared by aqueous microtitration method using Triacetin, Tween 80 and PEG-400 as the oil phase, surfactant, and co-surfactant. Nanoemulsion was studied for droplet size, polydispersity index (PDI), zeta potential, percentage transmittance, drug content, surface morphology. TEM images of developed formulation demonstrated spherical droplets with a mean diameter of 95.59 ±â€¯2.34 nm, PDI of 0.162 ±â€¯0.012 and zeta potential of -7.12 ±â€¯0.12 mV respectively. In in-vitro and ex-vivo drug release, LET-NE showed prolonged drug release profile as compared to suspension. SE was induced by KA (10 mg/kg, i.p.) in Swiss albino mice. Behavioral seizure monitoring, biochemical estimations, and histopathological examination were performed. The onset time of SE was significantly enhanced and % incidence of SE was reduced by intranasal administration of LET-NE as compared to KA and LET administered intraperitoneally. Biochemical estimations revealed that LET-NE effectively decreased levels of 17-ß estradiol while the levels of 5α-Dihydrotestosterone (5α-DHT) and 3α-androstanediol (3α-Diol) were significantly increased in the hippocampus. In cresyl violet staining LET-NE showed better protection of the hippocampus from neurotoxicity induced by KA as compared to LET. Also, in gamma scintigraphy of mouse brain, intranasal administration of nanoemulsion exhibited the presence of high concentration of LET. The study demonstrates the anticonvulsant and neuroprotective effect of LET-NE probably by inhibition of aromatization of testosterone into 17-ß estradiol, proconvulsant, and diverting the pathway into the synthesis of testosterone metabolites, 3α-Diol with known anticonvulsant and neuroprotective action. Brain targeting of LET-NE showed better anticonvulsant and neuroprotective action than LET.

Carboxymethyl Assam Bora rice starch coated SPIONs: Synthesis, characterization and in vitro localization in a micro capillary for simulating a targeted drug delivery system.

Carboxymethyl Assam Bora rice starch coated superparamagnetic iron oxide nanoparticles (CM-ABRS SPIONs) were chemically synthesized by co-precipitation method and particle size reduction was controlled by high energy homogenization process. Effects of various process variables (polymer concentration, homogenization speed and cycles) were optimized on the basis of average particle size (Z-average) and polydispersity index (PDI) of CM-ABRS SPIONs. The optimized CM-ABRS SPIONs were characterized for their particle size, surface morphology, electrokinetic potential, chemical interactions, crystallinity, magnetic properties, and targeting potential in presence of external magnetic field. In vitro localization of CM-ABRS SPIONs in a suspension of FITC (Fluorescein isothiocyanate) labeled RBCs (Red blood cells; hematocrit value; 45% (v/v)) was conducted inside a square glass capillary (500 × 500 µm2 cross section) in the presence of an externally applied magnetic field (Ms = 150 mT), simulating the case of magnetic drug targeting (MDT) approach. The aggregation dynamics of CM-ABRS SPIONs inside a micro capillary was observed with respect to time (t = 0 to 600 s), which shows proportionality to time of exposure to the externally applied magnetic field. This in vitro study acts as an important platform for design and optimization of active targeted drug delivery system.

Ultrasonically tailored, chemically engineered and "QbD" enabled fabrication of agomelatine nanoemulsion; optimization, characterization, ex-vivo permeation and stability study.

The objective of present study was to develop a nanoemulsion formulation of agomelatine (BCS class II drug) for the solubility enhancement. Capmul MCM, Tween 80 and PEG-400 were selected as oil, surfactant and co-surfactant respectively. The high energy ultrasonication method was used for the preparation of nanoemulsion. Three-factor three-level central composite design was employed to get the best formulation. The independent variables selected for the optimization were % oil, %Smix and sonication time (second). Based on the constraints applied to independent and dependent variables, the optimized formulation was selected with 2% oil, 10% Smix and 45s sonication time. The experimental values for dependent variables such as hydrodynamic diameter (nm), % transmittance and % CDR were found to be 73.72±2.53nm, 98.2±0.42%, 84.71±4.05% respectively. TEM and AFM-assisted morphological characterization of optimized Ago-NE was done and it was found with a spherical shape. The PDI, Zeta potential and the refractive index of optimized Ago-NE were found to be 0.137±0.016, -7.40±0.12mV and 1.423±0.045 respectively. The viscosity, pH and drug content of optimized Ago-NE were found as 25.12±0.67cP, 6.4±0.17 and 97.83±1.03% respectively. The ex-vivo permeation profile of optimized Ago-NE and agomelatine suspension through goat nasal mucosa were compared till 12h and % cumulative drug permeated was found to be 90% and 40% respectively. The higher drug permeation profile of optimized Ago-NE confirmed that the solubility of agomelatine has been improved.

Glial Cell: A Potential Target for Cellular and Drug Based Therapy in Various CNS Diseases.

Glial cells are integrated part of neurovascular unit of blood brain barrier (BBB). They undergo mitosis and mainly classified as astrocytes, oligodendrocytes, microglia, ependymal cells and nerve glial antigen 2 cells. Being a most versatile glial cell, astrocytes provide structural support to neurons, maintain brain homeostasis, take part in neuronal communication, and perform some housekeeping functions. Oligodendrocytes myelinate the neuronal axons for proper transmission of nerve impulse and microglia are brain immune cells. Multiple sclerosis is a prototype glia mediated disease that manifests demyelination. Fingolimod is already being marketed for this disease, while guanabenz and ibudilast are facing clinical trials. Many researches revealed the role of glial cells in Alzheimer's disease, in which riluzole (a glutamate modulator already in market for amyotrophic lateral sclerosis-ALS) was found to be effective. Q-cells® are glial cell-based therapeutic agent to treat ALS that only produce astrocytes and oligodendrocytes, when transplanted in vivo. hIL13-PE is a gene based therapeutic agent that has been smartly designed for the treatment of glioma. Although for CNS diseases, drugs are available, still it is not easy to extract satisfactory therapeutic effect of most of the drugs due to the presence of BBB. This barrier can be overcome by implanting a drug reservoir in brain parenchyma (wafer), by judicious selection of drug delivery system (nanoparticulate system), or by using an alternative route of administration (intranasal route). This review revolves around cellular and drug based modulation of glial cells to achieve maximum therapeutic benefit for some of the CNS diseases.

In vitro and preclinical assessment of factorial design based nanoethosomes transgel formulation of an opioid analgesic.

CONTEXT: Tramadol is a centrally acting analgesic and requires frequent dosing. Hence, judicious selection of retarding formulations is necessary. Transdermal ethosomal gel delivery has been recognized as an alternative route to oral delivery. OBJECTIVE: The objective was to develop statistically optimized ethosomal systems for enhanced transdermal activity of tramadol vis-à-vis traditional liposomes. MATERIALS AND METHODS: Box-Behnken design was employed for optimization of nanoethosomes using phospholipon 90G (A), ethanol (B), and sonication time (C) as independent variables while dependent variables were the vesicle size (Y1), entrapment efficiency (Y2), and flux (Y3). It was prepared by rotary evaporation method and characterized for various parameters including entrapment efficiency, size and transflux. Preclinical assessments were conducted on Wistar rats to measure the performance of developed formulations. RESULTS: The optimized formulation provided mean vesicles size, reasonable entrapment efficiency and enhanced flux when compared with liposome (control). In-vivo absorption study showed a significant increase in bioavailability (7.51 times) compared with oral tramadol. The average primary irritancy index was found to be 1.4, indicating it to be non-irritant and safe for use. DISCUSSION AND CONCLUSION: The results also demonstrated that encapsulated tramadol increases its biological activity due to the superior skin penetration potential. The preclinical study indicates a significant (P < 0.05) extended analgesic effect compared to oral solution using the hot plate test method. The overall results suggest that developed formulation is an efficient carrier for transdermal delivery of tramadol.