Intranasal delivery of tapentadol hydrochloride–loaded chitosan nanoparticles: formulation,characterisation and its in vivo evaluation

The aim of the present investigation was to formulate tapentadol hydrochloride–loaded chitosan nanoparticles (CS-NPs) for nose to brain delivery. Chitosan nanoparticles were prepared using ionotropic gelation technique. Optimisation of the formulation and process parameters was done using Box–Behnken Design. The entrapment efficiency, drug loading, Z-average size and zeta potential of the optimised batch were 63.49?±?1.61%, 17.25?±?1.38%w/w, 201.2?±?1.5?nm and +49.3?mV, respectively. In-vitro release study showed 84.04?±?1.53% drug release after 28?h, while ex vivo studies indicated higher permeation of CS-NPs through nasal mucosa. The nanoparticles exhibited good mucoadhesiveness, haemocompatibility and safety as evidenced by histopathology. The results of the pharmacodynamic study revealed prolongation of the analgesic activity. The intranasal instillation of CS-NPs resulted in the higher concentrations in brain compared to the drug solution and intravenous administration of CS-NPs. In a nutshell, intranasal administration of tapentadol hydrochloride–loaded CS-NPs is a promising approach for effective pain management.     

Intranasal Drug Delivery of Frovatriptan Succinate–Loaded Polymeric Nanoparticles for Brain Targeting

The objective of the present study was to develop polymeric nanoparticles (PNPs) of frovatriptan succinate for brain targeting by nasal route. Double emulsion method was used to increase the entrapment efficiency of hydrophilic drug, and formulation was optimized by central composite design to achieve critical quality attributes namely particle size, zeta potential, and entrapment efficiency. Optimized batch was evaluated for surface morphology, in vitro release, permeation across nasal mucosa, stability, histopathology, and brain tissue uptake study. Prepared PNPs were found to be smooth with particle size of 264.4 ± 0.04 nm, zeta potential ?35.17 ± 0.07 mV, and 65.2 ± 0.06% entrapment efficiency. PNPs showed biphasic release pattern, initial burst release followed by sustained release up to 72 h. Ex vivo diffusion study using goat nasal mucosa at pH 6.8 revealed that PNPs permeation across nasal mucosa was about 3 times more than the pure drug solution, and quick delivery of PNPs in brain region was confirmed by fluorescence microscopic evaluation in male Wistar rats after intranasal administration. Histopathology studies further revealed integrity of nasal mucosa after treatment with PNPs. The investigation indicated that hydrophilic drug, frovatriptan succinate can be successfully entrapped in PNPs to target brain via nasal delivery, and thus it could be an effective approach for nose to brain delivery.     

Surface modified kokum butter lipid nanoparticles for the brain targeted delivery of nevirapine

Abstract

Aim: The present work investigates the efficacy of Polysorbate 80(P80) coated Kokum butter (KB) solid lipid nanoparticles (P80NvKLNs) for the brain targeted delivery of Nevirapine (Nv).

Methods: Solid lipid nanoparticles (SLNs) were prepared by nanoprecipitation technique and evaluated for drug excipient compatibility studies, z- average particle size (nm), zeta potential (mv), percentage drug entrapment efficiency (%EE), surface morphology and in-vitro drug release properties. The in-vivo biodistribution and brain targeting efficiency of nanoparticles were studied in healthy male Wistar rat (150–200?g).

Results: P80NvKLNs were found to be smooth surfaced, spherical shaped having average particle size of 177.80?±?0.82?nm, zeta potential of ?8.91?±?4.36?mv and %EE of 31.32?±?0.42%. P80NvKLNs remained in blood circulation for 48?h maintaining a sustained release in brain for 24?h (p?<?0.05).

Conclusion: The study proves the efficacy of Polysorbate 80 coated Kokum butter nanoparticles for brain-targeted delivery of drugs providing ample opportunities for further study.     

Electrosteric stealth Rivastigmine loaded liposomes for brain targeting: preparation,characterization, ex vivo,bio-distribution and in vivo pharmacokinetic studies

Being one of the highly effective drugs in treatment of Alzheimer’s disease, Rivastigmine brain targeting is highly demandable, therefore liposomal dispersion of Rivastigmine was prepared containing 2?mol% PEG-DSPE added to Lecithin, Didecyldimethyl ammonium bromide (DDAB), Tween 80 in 1:0.02:0.25 molar ratio. A major challenge during the preparation of liposomes is maintaining a stable formulation, therefore the aim of our study was to increase liposomal stability by addition of DDAB to give an electrostatic stability and PEG-DSPE to increase stability by steric hindrance, yielding what we called an electrosteric stealth (ESS) liposomes. A medium nano-sized liposome (478?±?4.94?nm) with a nearly neutral zeta potential (ZP, ?8?±?0.2?mV) and an entrapment efficiency percentage of 48?±?6.22 was prepared. Stability studies showed no major alteration after three months storage period concerning particle size, polydispersity index, ZP, entrapment efficiency and in vitro release study confirming the successful formation of a stable liposomes. No histopathological alteration was recorded for ESS liposomes of the sheep nasal mucosa. While ESS liposomes showed higher % of drug permeating through the sheep nasal mucosa (48.6%) than the drug solution (28.7%). On completing the in vivo pharmacokinetic studies of 36 rabbits showed 424.2% relative bioavailability of the mean plasma levels of the formula ESS compared to that of RHT intranasal solution and 486% relative bioavailability of the mean brain levels.     

Optimization of artemether-loaded NLC for intranasal delivery using central composite design

Abstract

The objective of the study was to optimize artemether-loaded nanostructured lipid carriers (ARM-NLC) for intranasal delivery using central composite design. ARM-NLC was prepared by microemulsion method with optimized formulation having particle size of 123.4?nm and zeta potential of ?34.4?mV. Differential scanning calorimetry and powder X-ray diffraction studies confirmed that drug existed in amorphous form in NLC formulation. In vitro cytotoxicity assay using SVG p12 cell line and nasal histopathological studies on sheep nasal mucosa indicated the developed formulations were non-toxic and safe for intranasal administration. In vitro release studies revealed that NLC showed sustained release up to 96?h. Ex vivo diffusion studies using sheep nasal mucosa revealed that ARM-NLC had significantly lower flux compared to drug solution (ARM-SOL). Pharmacokinetic and brain uptake studies in Wistar rats showed significantly higher drug concentration in brain in animals treated intranasally (i.n.) with ARM-NLC. Brain to blood ratios for ARM-NLC (i.n.), ARM-SOL (i.n.) and ARM-SOL (i.v.) were 2.619, 1.642 and 0.260, respectively, at 0.5?h indicating direct nose to brain transport of ARM. ARM-NLC showed highest drug targeting efficiency and drug transport percentage of 278.16 and 64.02, respectively, which indicates NLC had better brain targeting efficiency compared to drug solution.     

Preparation and optimization of N-trimethyl-O-carboxymethyl chitosan nanoparticles for delivery of low-molecular-weight heparin

The aim of this study was preparation, optimization and in vitro characterization of nanoparticles composed of 6-[O-carboxymethyl]-[N,N,N-trimethyl] (TMCMC) for oral delivery of low-molecular-weight heparin. The chitosan derivative was synthesized. Nanoparticles were prepared using the polyelectrolyte complexation method. Box–Behnken response surface experimental design methodology was used for optimization of nanoparticles. The morphology of nanoparticles was studied using transmission electron microscopy. In vitro release of enoxaparin from nanoparticles was determined under simulated intestinal fluid. The cytotoxicity of nanoparticles on a Caco-2 cell line was determined, and finally the transport of prepared nanoparticles across Caco-2 cell monolayer was defined. Optimized nanoparticles with proper physico-chemical properties were obtained. The size, zeta potential, poly-dispersity index, entrapment efficiency and loading efficiency of nanoparticles were reported as 235?±?24.3?nm, +18.6?±?2.57?mV, 0.230?±?0.03, 76.4?±?5.43% and 12.6?±?1.37%, respectively. Morphological studies revealed spherical nanoparticles with no sign of aggregation. In vitro release studies demonstrated that 93.6?±?1.17% of enoxaparin released from nanoparticles after 600?min of incubation. MTT cell cytotoxicity studies showed no cytotoxicity at 3?h post-incubation, while the study demonstrated concentration-dependent cytotoxicity after 24?h of exposure. The obtained data had shown that the nanoparticles prepared from trimethylcarboxymethyl chitosan may be considered as a good candidate for oral delivery of enoxaparin.     

Development and evaluation of co-formulated docetaxel and curcumin biodegradable nanoparticles for parenteral administration

Context: Technology for development of biodegradable nanoparticles encapsulating combinations for enhanced efficacy.

Objective: To develop docetaxel (DTX) and curcumin (CRM) co-encapsulated biodegradable nanoparticles for parenteral administration with potential for prolonged release and decreased toxicity.

Materials and methods: Modified emulsion solvent-evaporation technique was employed in the preparation of the nanoparticles optimized by the face centered-central composite design (FC-CCD). The uptake potential was studied in MCF-7 cells, while the toxicity was evaluated by in vitro hemolysis test. In vivo pharmacokinetic was evaluated in male Wistar rats.

Results and discussion: Co-encapsulated nanoparticles were developed of 219?nm size, 0.154 PDI, ?13.74?mV zeta potential and 67.02% entrapment efficiency. Efficient uptake was observed by the nanoparticles in MCF-7 cells with decreased toxicity in comparison with the commercial DTX intravenous injection, Taxotere®. The nanoparticles exhibited biphasic release with initial burst release followed by sustained release for 5 days. The nanoparticles displayed a 4.3-fold increase in AUC (391.10?±?32.94 versus 89.77?±?10.58?μg/ml min) in comparison to Taxotere® with a 6.2-fold increase in MRT (24.78?±?2.36 versus 3.58?±?0.21?h).

Conclusion: The nanoparticles exhibited increased uptake, prolonged in vitro and in vivo release, with decreased toxicity thus exhibiting potential for enhanced efficacy.     

Preparation of surface multiple-coated polylactide acid drug-loaded nanoparticles for intranasal delivery and evaluation on its brain-targeting efficiency

Purpose: To prepare a mixture of multiple-coated aniracetam nasal polylactic-acid nanoparticles (M-C-PLA-NP) and evaluate its stability preliminarily in vitro and its brain-targeting efficiency in vivo.

Methods: The solvent diffusion–evaporation combined with magnetic stirring method has been chosen for the entrapment of aniracetam. The M-C-PLA-NP was characterized with respect to its morphology, particle size, size distribution and aniracetam entrapment efficiency. The in vivo distribution was studied in male SD rats after an intranasal administration.

Results: In vitro release of M-C-PLA-NP showed two components with an initial rapid release due to the surface-associated drug and followed by a slower exponential release of aniracetam, which was dissolved in the core. The AUC_0→30?min of M-C-PLA-NP in brain tissues resulted in a 5.19-fold increase compared with aniracetam solution. The ratios of AUC in brain to that in other tissues obtained after nasal application of M-C-PLA-NP were significantly higher than those of aniracetam solution.

Conclusion: Therefore, it can be concluded that M-C-PLA-NP demonstrated its potential on increasing the brain-targeting efficiency of drugs and will be used as novel brain-targeting agent for nasal drug delivery.     

Nanostructured lipid carriers as a delivery system of biochanin A

Abstract

The aim of this study was to explore the nanostructured lipid carriers as a delivery system of biochanin A so as to supply a method to improve its bioavailability. Biochanin A–loaded nanostructured lipid carriers (BCA-NLCs) were prepared by the method of emulsion-evaporation and low temperature solidification. Pharmacokinetics was carried out in rats upon oral administration at a dose of 10?mg/kg. BCA-NLC showed spherical formulation and had mean diameter174.68?±?0.96?nm, zeta potential ?20.9?±?0.8?mv and entrapment efficiency 97.36?±?0.14%. DSC and XRD studies indicated that BCA was not in crystal state in NLC. In in vitro release study, the BCA from BCA-NLC exhibited a biphasic release pattern with burst release initially and sustained release afterwards. BCA-NLC showed higher AUC value and circulated in blood for a longer time than BCA suspension. The studies demonstrated that NLC could be a potential delivery system for BCA to improve bioavailability.     

Nanoparticle-based topical ophthalmic formulation for sustained release of stereoisomeric dipeptide prodrugs of ganciclovir

Poly(d,l-lactic-co-glycolic acid) (PLGA) nanoparticles (NP) of Val-Val dipeptide monoester prodrugs of ganciclovir (GCV) including L-Val-L-Val-GCV (LLGCV), L-Val-D-Val-GCV (LDGCV) and D-Val-L-Val-GCV (DLGCV) were formulated and dispersed in thermosensitive PLGA-PEG-PLGA polymer gel for the treatment of herpes simplex virus type 1 (HSV-1)-induced viral corneal keratitis. Nanoparticles containing prodrugs of GCV were prepared by a double-emulsion solvent evaporation technique using various PLGA polymers with different drug/polymer ratios. Nanoparticles were characterized with respect to particle size, entrapment efficiency, polydispersity, drug loading, surface morphology, zeta potential and crystallinity. Prodrugs-loaded NP were incorporated into in situ gelling system. These formulations were examined for in vitro release and cytotoxicity. The results of optimized entrapment efficiencies of LLGCV-, LDGCV- and DLGCV-loaded NP are of 38.7?±?2.0%, 41.8?±?1.9%, and 45.3?±?2.2%; drug loadings 3.87?±?0.20%, 2.79?±?0.13% and 3.02?±?0.15%; yield 85.2?±?3.0%, 86.9?±?4.6% and 76.9?±?2.1%; particle sizes 116.6?±?4.5, 143.0?±?3.8 and 134.1?±?5.2?nm; and zeta potential ?15.0?±?4.96, ?13.8?±?5.26 and ?13.9?±?5.14?mV, respectively. Cytotoxicity studies suggested that all the formulations are non-toxic. In vitro release of prodrugs from NP showed a biphasic release pattern with an initial burst phase followed by a sustained phase. Such burst effect was completely eliminated when NP were suspended in thermosensitive gels with near zero-order release kinetics. Prodrugs-loaded PLGA NP dispersed in thermosensitive gels can thus serve as a promising drug delivery system for the treatment of anterior eye diseases.     

Design,characterization, and evaluation of aceclofenac-loaded Eudragit RS 100 nanoparticulate system for ocular delivery

The aim of the present study was to develop and evaluate positively charged nanoparticles of aceclofenac for ocular delivery. The nanoparticles were prepared by the nanoprecipitation method using Eudragit RS 100. The optimized nanoparticles were found to have narrow particle size range (238.9?±?8?nm) with nearly spherical shape, positive zeta potential (40.3?±?3.8). Higher entrapment efficiency of aceclofenac (94.53?±?1.0%) with prolonged in vitro drug release profiles was also observed. Powder X-ray diffraction and differential scanning calorimetry studies indicated decrease in crystallinity of drug within the nanoparticulate polymeric matrix. The formulation was found to have higher permeation as compared to aceclofenac aqueous solution. Nanoparticle formulation was found to be quite stable and well tolerated with no signs of corneal damage. The in vivo studies involving the arachidonic acid-induced ocular inflammation in rabbits showed optimal efficacy of the nanoparticles with significantly higher inhibition of polymorphonuclear leukocytes migration (p?<?0.05) and lid closure scores.     

Fabrication and evaluation of lipid nanoparticulates for ocular delivery of a COX-2 inhibitor

Context: The unique physiological limitations of the eye have been assigned as reason of low bioavailability by conventional drug delivery systems. There is need of such drug carriers, which ensure improved bioavailability as well as patient compliance upon instillation into the eye.

Objective: The present investigation deals with development of solid lipid nanoparticles (SLNs) containing celecoxib (CXB) for treatment of ophthalmic inflammations.

Materials and methods: The SLNs were formulated by melt-emulsion sonication and low temperature-solidification process and evaluated for particle size, surface morphology, physicochemical properties, percentage drug incorporation efficiency, in vitro drug release, in vitro trans-corneal permeation, in vivo efficacy in ocular inflammation, stability study and gamma scintigraphy study to assess the residence of solid lipid nanoparticles over ocular surfaces.

Results: The SLNs were spherical and the optimized formulation had particle size of 198.77?±?7.5?nm, which is quite suitable for ocular applications. The maximum entrapment efficiency of 92.46?±?0.07% was achieved for formulation SLN 20. The permeation across the cornea was also significantly better than aqueous suspension (8.21?±?0.67 versus 4.61?±?0.71) at p?<?0.05.

Discussion and conclusion: The SLN formulations demonstrated improved performance of entrapped CXB while mitigating the key parameters of ocular inflammation in rabbits. The particulate formulations have exhibited prolonged retention over ocular surfaces as evident from results of gamma scintigraphy using ^99mTc labeled SLNs.     

Formulation development of albumin based theragnostic nanoparticles as a potential delivery system for tumor targeting

Background: Generally, chemotherapeutic drugs attack on both normal and tumor cells non-specifically causing life threatening side effects, necessitating targeted drug delivery to tumors.

Purpose: The purpose of this study is to formulate albumin-based nanoparticles for tumor targeted drug delivery and noninvasive diagnosis.

Methods: Albumin based nanoparticles (NPs) were developed as a potential tumor theragnostic agent by entrapping an anti cancer drug, doxorubicin and a near infrared dye, indocyanine green. Theragnostic nanoparticles were prepared using a well established coacervation/nanoprecipitation method followed by lyophilization. The formulation was optimized by varying process parameters using full factorial design of experiments. Release of dye and drug from NPs and physical state of the drug in NPs was studied using DSC. The NPs were injected into tumor bearing mice intravenously and imaged using a bio-imager.

Results: The optimized nanoparticle formulation had a particle size of 125.0?±?1.8?nm, poly dispersity index of 0.180?±?0.057 and zeta potential of ?32.7?±?0.9 mV. The release of dye and drug from the nanoparticles was determined to be quasi-fickian diffusion mediated. Differential scanning calorimetry (DSC) studies revealed the stability of drug in the NP. The in-vivo studies showed enhanced accumulation of the dye loaded NPs at the tumor site than the dye solution, thus allowing noninvasive tumor monitoring.

Conclusion: These results project the newly proposed and evaluated nanoparticle formulation as a potential tumor targeting and imaging delivery system.     

Development,characterization and nasal delivery of rosmarinic acid-loaded solid lipid nanoparticles for the effective management of Huntington’s disease

Abstract

Objective: The objective of the present study was to investigate the potential use of solid lipid nanoparticles (SLNs) as a drug delivery system to enhance the brain-targeting efficiency of rosmarinic acid (RA) following intranasal (i.n.) administration.

Materials and methods: The RA-loaded SLNs was prepared by the hot homogenization technique, in which glycerol monostearate (GMS) as lipid, tween 80 and soya lecithin were used as surfactant along with hydrogenated soya phosphatidyl choline (HSPC) as a stabilizer, and were characterized for particle size, zeta potential (ZP), in vitro study. Nasal delivery of the developed formulation followed by the study of behavioral (locomotor, narrow beam, body weight) and biochemical parameters (glutathione, lipid peroxidation, catalase and nitrite) in wistar rat was carried out.

Results: Optimized RA-loaded SLNs using tween 80 (SLNPRT) have the mean size of (149.2?±?3.2?nm), ZP (?38.27?mV) entrapment efficiency (61.9?±?2.2%). 3-NP-treated rat significantly increased behavioral alterations, oxidative damage as compared with the control group. SLNPRT treatment significantly improved behavioral abnormalities and attenuated the oxidative stress in 3NP-treated rats. However, the nasal delivery of SLNPRT produced significant therapeutic action as compared to intravenous application. In the organ distribution study, brain drug concentration was found to be 5.69?µg, in pharmacokinetic study C_max, t_max, t_1/2, AUC values were found to be 0.284?µg/ml, 1.5?h, 3.17?h, and 1.505?µg/ml/h, respectively.

Conclusion: The encouraging results confirmed the developed optimized RA-loaded SLNs formulation following the non-invasive nose-to-brain drug delivery that is a promising therapeutic approach for the effective management in Huntington disease.     

Formulation and in vitro characterization of poly(dl-lactide-co-glycolide)/Eudragit RLPO or RS30D nanoparticles as an oral carrier of levofloxacin hemihydrate

The main objective of this study was to design positively charged Levofloxacin Hemihydrate (Levo-h)-loaded nanoparticles with improved entrapment efficiency and antibacterial activity. PLGA alone or in combinations with Eudragit® RLPO or RS30D with or without positively charged inducing agent; 1,2-dioleoyl-3-trimethylammonium-propane, chloride salt (DOTAP); were used for preparation of nanoparticles. Blending between PLGA and Eudragit® RLPO or RS30D with inclusion of DOTAP caused a marked increase in entrapment efficiency and switched zeta potential from negative to positive. Nanoparticle formulations; NR3 (Levo-h:PLGA:Eudragit® RLPO; 1:1:1 w/w with DOTAP) and NS3 (Levo-h:PLGA:Eudragit® RS30D; 1:1:1 w/w with DOTAP) that possess high positive zeta potential (59.3?±?7.5 and 55.1?±?8.2?mV, respectively) and Efficient Levo-h entrapment (89.54?±?1.5 and 77.65?±?1.8%, respectively) were selected for further examinations; in vitro release, physical stability and microbiological study. NR3 and NS3 showed significant sustained release of Levo-h. NR3 and NS3 exhibited good stability after storage at room temperature. Microbiological assay showed strengthened antibacterial activity of NR3 against both types of gram-negative bacteria (E. coli, Ps. aeruginosa) and of NS3 against Ps. aeruginosa compared to free Levo-h solution. NR3 and NS3 appear to be promising oral delivery system for Levo-h.     

Incorporation of rosuvastatin-loaded chitosan/chondroitin sulfate nanoparticles into a thermosensitive hydrogel for bone tissue engineering: preparation,characterization, and cellular behavior

Rosuvastatin (RSV) has been shown to have significant impact on the simulation of bone regeneration after local injection. The current study aimed to develop a localized controlled delivery system from RSV by incorporating RSV-loaded chitosan/chondroitin sulfate (CTS/CS) nanoparticles into thermosensitive Pluronic F127/hyaluronic acid (PF127/HA) hydrogel. RSV-loaded CTS/CS nanoparticles were prepared by ionic gelation, and the impact of various formulation variables was assessed using the Box–Behnken design. Consequently, optimized RSV-loaded nanoparticles were incorporated into the PF127/HA hydrogel. Rheological properties, degradation rates of hydrogels, and the release rate of RSV from hydrogel were examined. Mean particle size, zeta potential, entrapment efficiency, and mean release time of the optimized RSV-loaded nanoparticles were confirmed as 283.2?±?16?nm, –31.2?±?6.8?mV, 63.1?±?4.2%, and 6.14?±?0.3?h, respectively. The hydrogel containing 3% w/v CTS/CS nanoparticles existed as a solution with low viscosity at room temperature converted to a semisolid upon increasing the temperature to 35?°C. Hydrogel engrafted with CTS/CS showed controlled release of RSV during 48?h with superior in vitro gel stability. As revealed by cytotoxicity and mineralization assays, incorporation of RSV-loaded particles into PF127/HA hydrogel led to improvement in osteoblast viability and proliferation.     

Perspectives of nanoemulsion assisted oral delivery of docetaxel for improved chemotherapy of cancer

Abstract

Context: Nanoemulsions (NE) are one of the robust delivery tools for drugs due to their higher stability and efficacy.

Objectives: The purpose of present investigation is to develop stable, effective and safe NE of docetaxel (DTX).

Methods: Soybean oil, lecithin, Pluronic F68, PEG 4000 and ethanol were employed as excipients and NEs were prepared by hot homogenization followed by ultra-sonication. NEs were optimized and investigated for different in vitro and in vivo parameters viz. droplet size, poly dispersity index, charge; zeta potential, drug content and in vitro drug release, in vitro cytotoxicity, in vitro cell uptake and acute toxicity. Transmission electron microscopy was performed to study morphology and structure of NEs. Stability studies of the optimized formulation were performed.

Results: Droplet size, poly dispersity index, zeta potential, drug content and in vitro drug release were found to be 233.23?±?4.3?nm, 0.24?±?0.010, ?43.66?±?1.9?mV, 96.76?±?1.5%, 96.25?±?2.1%, respectively. NE F11 exhibited higher cell uptake (2.83 times than control) and strong cytotoxic activity against MCF-7 cancer cells (IC₅₀; 13.55?±?0.21?µg/mL at 72?h) whereas no toxicity or necrosis was observed with liver and kidney tissues of mice at a dose of 20?mg/kg. Transmission electron microscopy ensured formation of poly-dispersed and spherical droplets in nanometer range. NE F11 (values indicated above) was selected as the optimized formulation based on the aforesaid parameters.

Conclusion: Conclusively, stable, effective and safe NE was developed which might be used as an alternative DTX therapy.     

Biodegradable intranasal nanoparticulate drug delivery system of risedronate sodium for osteoporosis

Context: Osteoporosis (OP) is the most common metabolic bone disease predominantly found in elderly people. It is associated with reduced bone mineral density, results in a higher probability of fractures, especially of the hip, vertebrae, and distal radius. Worldwide prevalence of OP is considered a serious public health concern.

Objective: The purpose of the present work was to develop and evaluate polymeric nanoparticles (NPs) of risedronate sodium (RIS) for the treatment of OP using intranasal (IN) route in order to reduce peripheral toxic effects.

Materials and methods: Polymeric NPs of RIS were prepared by nanoprecipitation methods. Formulations were developed and evaluated in context to in vitro drug release, ex vivo permeation, in vivo study, and biochemical studies.

Results and discussions: The particles size, entrapment efficiency (EE) (%), and loading capacity (LC) (%) of optimized formulations were found to be 127.84?±?6.33?nm, 52.65?±?5.21, and 10.57?±?1.48, respectively. Release kinetics showed diffusion-controlled, Fickian release pattern. Ex vivo permeation study showed RIS from PLGA-NPs permeated significantly (p?<?0.05) through nasal mucosa. In vivo study showed a marked difference in micro-structure (trabeculae) in bone internal environment. Biochemical estimation of treated group and RIS PLGA indicated a significant recovery (p?<?0.01) as compared with the toxic group.

Conclusion: Polymeric NPs of RIS were prepared successfully using biodegradable polymer (PLGA). Intranasal delivery showed a good result in in vivo study. Thus PLGA-NPs have great potential for delivering the RIS for the treatment and prevention of OP after clinical evaluation in near future.     

Optimization of nanostructured lipid carriers of lamotrigine for brain delivery: in vitro characterization and in vivo efficacy in epilepsy

Objective: The aim of the present work was to investigate the efficacy of nanostructured lipid carriers (NLCs) to enhance the brain targeting of lamotrigine (LMT) following intranasal (IN) administration.

Methods: Formulation was optimized using four-factor three levels Box– Behnken design to establish the functional relationships between variables on responses, that is, particle size, entrapment efficiency (EE) and percentage cumulative drug release of LMT-loaded NLCs. NLCs were evaluated for particle size, surface morphology, %EE and in vitro release and ex vivo permeation. The developed formulation was subjected to stability study, in vivo efficacy and scintigraphic study in Wistar rat model.

Results: The NLCs had a mean particle size of 151.6 ± 7.6 nm, polydispersity index of 0.249 ± 0.035, zeta potential of 11.75 ± 2.96 mV and EE of 96.64 ± 4.27%. The drug release from NLCs followed Fickian diffusion with a flux value of 11.73 μgcm^?2h^?1. Sustained drug concentration was obtained in NLCs carrying LMT after IN administration after 24 h. γ scintigraphy studies further proved high accumulation of drug in brain.

Conclusion: Hence we can conclude that IN administration of LMT NLCs in rats is able to maintain higher brain concentration of LMT compared to IN and oral drug solution.     

Novel Topical Ophthalmic Formulations for Management of Glaucoma

Purpose

Preparation of topical ophthalmic formulations containing brimonidine-loaded nanoparticles prepared from various biodegradable polymers—PCL, PLA and PLGA—for sustained release of brimonidine as a once daily regimen for management of glaucoma.

Methods

Nanoparticles were prepared using spontaneous emulsification solvent diffusion method then characterized regarding their particle size, zeta potential, morphology and drug contents. Brimonidine-loaded nanoparticles were incorporated into eye drops, temperature-triggered in situ gelling system and preformed gel and characterized regarding their pH, viscosity, uniformity of drug contents, in vitro release study, in vitro cytotoxicity and in vivo intraocular pressure (IOP) lowering effects.

Results

The results of optimized brimonidine-loaded PCL-, PLGA- and PLA-NPs respectively, are: particle sizes of 117.33?±?4.58 nm, 125.67?±?5.15 nm and 131.67?±?3.79 nm; zeta potentials of ?18.5?±?2.87 mV, ?21.82?±?2.7 mV and ?28.11?±?2.21 mV; and encapsulation efficiencies of 77.97?±?1.38%, 68.65?±?3.35% and 73.52?±?2.92%. TEM analyses revealed that all NPs have spherical shapes with dense core and distinct coat. In vitro release data showed a sustained release without any burst effect with Higuchi non-Fickian diffusion mechanism. Cytotoxicity studies revealed that all formulations are non-toxic. Also all formulations possessed a sustained IOP lowering effect compared to Alphagan® P eye drops.

Conclusions

Our formulations showed prolonged management of glaucoma that should meet with better patient compliance as a once-daily formulation.