Development and evaluation of carboplatin-loaded PCL nanoparticles for intranasal delivery

Context: The study was aimed to develop a polymeric nanoparticle formulation of anticancer drug carboplatin using biodegradable polymer polycaprolactone (PCL). The formulation is intended for intranasal administration to treat glioma anticipating improved brain delivery as nasal route possess direct access to brain and nanoparticles have small size to overcome the mucosal and blood–brain barrier.

Objective: Development and evaluation of carboplatin-PCL nanoparticles for brain delivery by nasal route.

Methodology: Carboplatin-loaded PCL nanoparticles (CPCs) were prepared by double emulsion-solvent evaporation technique and characterized by particle size, zeta potential, entrapment efficiency, scanning electron microscopy and differential scanning calorimetry. The CPCs were assessed for in vitro release kinetics, ex vivo permeation and in situ nasal perfusion. Cytotoxic potential of CPCs in vitro was evaluated on LN229 human glioblastoma cells.

Results and discussion: The optimized formulation of carboplatin-PCL nanoparticle CPC-08 with particle size of 311.6?±?4.7?nm and zeta potential ?16.3?±?3.7?mV exhibited percentage entrapment efficiency of 27.95?±?4.21. In vitro drug release showed initial burst release followed by slow and continues release indicating biphasic pattern. The ex vivo permeation pattern through sheep nasal mucosa also exhibited a similar release pattern as for in vitro release studies. In situ nasal perfusion studies in Wistar rats demonstrate that CPCs show better nasal absorption than carboplatin solution. In vitro cytotoxicity studies on LN229 cells showed an enhancement in cytotoxicity by CPCs compared to carboplatin alone.

Conclusion: CPC-08 effectively improves nasal absorption of carboplatin and can be used for intranasal administration of carboplatin for improved brain delivery.     

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.     

Solid lipid nanoparticles of diethylcarbamazine citrate for enhanced delivery to the lymphatics: in vitro and in vivo evaluation

Objectives: The major objective is to target diethylcarbamazine citrate (DEC) to the lymphatics and to increase its retention time. The effect of various excipients on the physicochemical characteristics of the nanoparticles was also studied.

Materials and methods: Solid lipid nanoparticles (SLNs) of DEC were prepared by ultrasonication by varying the concentrations of compritol 888 ATO, poloxamer 188 and soya lecithin. The SLNs were evaluated for size, shape, texture, surface charge, physical nature of the entrapped drug, entrapment efficiency and in vitro drug release. In vivo animal studies were carried out to estimate the pharmacokinetic parameters in blood and drug concentration in lymph after oral administration.

Results: The size of the spherical particles was in the range of 27.25 ± 3.43 nm to 179 ± 3.08 nm and a maximum entrapment efficiency of 68.63 ± 1.53% was observed. In vitro release studies in pH 7.4 PBS displayed a rapid release and the maximum time taken for the complete drug to release was 150 min. In vivo studies indicated an enhancement in the amount of drug that reached lymphatics when administered via SLNs.

Conclusion: Targeting of DEC to the lymphatics is possible through SLNs and the retention time in the lymphatics can also be enhanced.     

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.     

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.     

Chitosan–sodium alginate blended polyelectrolyte complexes as potential multiparticulate carrier system: colon-targeted delivery and gamma scintigraphic imaging

Objectives: The objective of this study is to develop stable, biodegradable chitosan–sodium alginate-based dual, ionic cross-linked multiparticulate system (microbeads) of tinidazole for targeted colon delivery and sustained drug release for the treatment of amoebiasis and thereby evaluating its targeting approach through in vivo gamma scintigraphic imaging technique.

Methods: The chitosan–sodium alginate-based multiparticulate system developed was producing sustained effect by virtue of its mechanical strength using double ionotropic gelation method utilizing calcium chloride and sodium sulfate as first and second cross-linkers respectively. Prepared formulations were evaluated for percent yield, drug entrapment efficiency, particle size, degree of swelling, in vitro kinetics, and in vivo targeting potentials using gamma scintigraphic imaging technique.

Results: The obtained particulates were spherical, free flowing, and had a mean particle size ranging from 1.422 mm to 1.881 mm, whereas percent yield and percent drug entrapment efficiency was found to be in between 72.61 to 82.43% and 63.25 to 79.32% respectively.

Conclusion: The prepared multiparticulate system showed better sustained release property and in vivo ability to target colon for drug delivery. Hence, the developed multiparticulate system could be a promising device to achieve greater site-specificity to colon.     

Design and characterization of chitosan-alginate microspheres for ocular delivery of azelastine

Abstract

The use of mucoadhesive biopolymers is one of the best approaches to prolong the drug residence inside the cul-de-sac, consequently increasing the bioavailability. Thus, the focus of this work was to develop mucoadhesive microspheres to overcome the limitations of ocular drug delivery. The chitosan-sodium alginate microspheres of azelastine hydrochloride were fabricated using modified ionotropic gelation technique. The particle size, zeta potential, entrapment efficiency and drug release kinetics were evaluated and characterized by SEM, FT-IR, DSC, in vitro mucoadhesion and in vivo study. The microspheres had average particle size in the range of 3.55 to 6.70?µm and zeta potential +24.55 to +49.56?mV. The fabricated microspheres possess maximum drug entrapment of 73.05% with 65% mucin binding efficiency and revealed a controlled release over the 8-h period following a non-Fickian diffusion. SEM showed that microspheres were distinct solid with irregular shape. FT-IR and DSC results concluded the drug entrapment into microspheres. In vivo studies on ocular rat model revealed that azelastine microspheres had better efficacy. Chitosan sodium alginate microspheres prepared were in particle size range suitable for ocular purpose. In vitro release and in vivo efficacy studies revealed that the microspheres were effective in prolonging the drug’s presence in cul de sac with improved therapeutic efficacy.     

Formulation,development and optimization of raloxifene-loaded chitosan nanoparticles for treatment of osteoporosis

Abstract

Context: Osteoporosis (OP) is a disease of skeletal system and is associated with fragility fracture at the hip, spine and wrist. Various drugs have been used to treat OP. One of them is raloxifene hydrochloride (RLX), a second-generation selective estrogen receptor modulator (SERM) approved by the USFDA. RLX possesses only 2% absolute bioavailability (BA) by oral route due to its extensive first-pass metabolism.

Objective: The purpose of the current research work was to develop and evaluate RLX-loaded chitosan nanoparticles (CS-NPs) for treatment of OP with enhanced BA.

Materials and methods: The RLX-loaded CS-NPs were prepared by gelation of CS with tripolyphosphate (TPP) by ionic cross-linking. Formulation was optimized and in vitro drug release and in vivo study were performed.

Results and discussions: CS-NPs were formed by the ionic gelation method. The particle size, entrapment efficiency and loading efficiency varied from 216.65 to 1890?nm, 32.84 to 97.78% and 23.89 to 62.46%, respectively. Release kinetics showed diffusion-controlled and Fickian release pattern. In vivo study indicated higher plasma drug concentration with NPs administered intranasally as compared to drug suspension administered through oral route (p?<?0.05). A significantly higher drug concentration in plasma was achieved in 10?min after nasal administration with respect to oral administration.

Conclusion: The results suggest that RLX-loaded CS-NPs have better BA and would be a promising approach for intranasal (i.n.) delivery of RLX for the treatment of OP.     

Formulation of plumbagin loaded long circulating pegylated liposomes: in vivo evaluation in C57BL/6J mice bearing B16F1 melanoma

Context and Objective: Plumbagin (2-methyl, 5-hydroxy, 1, 4-naphthoquinone), an anticancer agent is encapsulated either as conventional or long circulating liposomal formulations to enhance its biological half-life and antitumor efficacy.

Methods: The liposomes were prepared by thin film hydration method and in vitro characterization was carried out to examine the particle size, zeta potential, drug encapsulation efficiency and in vitro release. The optimized formulations were tested for pharmacokinetic and pharmacodynamic efficacy against mice bearing B16F1 melanoma. Also in vivo toxicity studies were carried out.

Results and Discussion: The optimum particle size and entrapment efficiency was observed at drug to lipid molar ratio of 1:20. The in-vitro release of plumbagin from the liposomal formulations in phosphate-buffered saline (pH 7.4) showed biphasic release with an initial burst release followed by sustained release phase. Elimination half life (T_1/2) of pegylated, conventional and free plumbagin was 1305.76?±?278.16, 346.87?±?33.82 and 35.89?±?7.95?min respectively. Further, plumbagin exhibited better antitumor efficacy in vivo when administered as long circulating liposomes with no signs of normal tissue toxicity.

Conclusion: It can be concluded that the pegylated liposomes could provide a promising parenteral platform for plumbagin with enhanced plasma half-life and therapeutic efficacy.     

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.     

Brain-targeted delivery of doxorubicin using glutathione-coated nanoparticles for brain cancers

Abstract

Objectives: To prepare and characterize in vitro a novel brain-targeted delivery of doxorubicin using glutathione-coated nanoparticles (NPs) for the treatment of brain cancer.

Methods: Doxorubicin-loaded NPs were prepared by the nanoprecipitation method using PLGA-COOH (dl-lactide-co-glycolide). The NPs were coated with a glutathione-PEG conjugate (PEG-GSH) in order to target delivery to the brain. The NPs were characterized via in vitro studies to determine particle size, drug release, cellular uptake, immunofluorescence study, cytotoxic assay, and in vitro blood–brain barrier (BBB) assay.

Results: The NPs showed a particle size suitable for BBB permeation (particle size around 200?nm). The in vitro release profile of the NPs exhibited no initial burst release and showed sustained drug release for up to 96?h. The immunofluorescence study showed the glutathione coating does not interfere with the drug release. Furthermore, in vitro BBB Transwell? study showed significantly higher permeation of the doxorubicin-loaded NPs compared with the free doxorubicin solution through the coculture of rat brain endothelial (RBE4) and C6 astrocytoma cells (p?<?0.05).

Conclusions: We conclude that the initial in vitro characterization of the NPs demonstrates potential in delivering doxorubicin to cancer cells with possible future application in targeting brain cancers in vivo.     

Nanotransfersomes of carvedilol for intranasal delivery: formulation,characterization and in vivo evaluation

Context: Development of carvedilol-loaded transfersomes for intranasal administration to overcome poor nasal permeability and hepatic first pass effect so as to enhance its bioavailability.

Objective: The purpose of this study was to develop carvedilol-loaded transfersomes containing different edge activators (EAs) then evaluating the in vivo behavior of the optimized formula in rabbits.

Methods: The vesicles were prepared by incorporating different EAs including Span 20, Span 60, Tween 20, Tween 80, and sodium deoxycholate (SDC) in the lipid bilayer and each EA was used in three different ratios with respect to phosphatidylcholine (PC) including 95:5%, 85:15%, and 75:25% w/w (PC:EA). Evaluation of transfersomes was carried out in terms of shape, size, entrapment efficiency (EE), in vitro release, ex vivo permeation, confocal laser scanning microscopy (CLSM), and stability studies. The pharmacokinetic study of the optimized formula was conducted in rabbits.

Results: The mean diameter of the vesicles was in the range of 295–443?nm. Transfersomes prepared with 95:5% (w/w) (PC:EA) ratio showed highest EE% where Span 60 gave the highest values. Whereas those prepared using 85:15% w/w ratio showed highest percentages of drug release where SDC was superior to other EAs. The developed transfersomes exhibited significantly higher amounts of carvedilol permeated through nasal mucosa. CLSM of formula T14 containing SDC with 85:15% (w/w) (PC:EA) ratio revealed high permeation across the nasal mucosa.

Conclusion: The nanotransfersomal vesicles were significantly more efficient in nasal delivery of carvedilol with absolute bioavailability of 63.4%.     

Optimization of Nanostructured Lipid Carriers of Lurasidone Hydrochloride Using Box-Behnken Design for Brain Targeting: In Vitro and In Vivo Studies

Intranasal nanostructured lipid carrier (NLC) of lurasidone hydrochloride (LRD) for brain delivery was prepared by the solvent evaporation method. The effects of independent variables, X1-lipid concentration, X-2 surfactant, and X-3 sonication times on dependent variables, Y1-particle size, Y-2 polydispersity index, and Y-3% entrapment efficiency were determined using Box-Behnken design. Optimized LRD-NLC was selected from the Box-Behnken design and evaluated for their morphological, physiological, nasal diffusion, and in vivo distribution in the brain after intranasal administration. Particle size, polydispersity index, and entrapment efficiency of optimized LRD-NLC were found to be 207.4 ± 1.5 nm, 0.392 ± 0.15, and 92.12 ± 1.0%, respectively. Transmission electron microscopy and scanning electron microscopy was used to determine the particle size and surface morphology of LRD-NLC. The prepared LRD-NLC follows biphasic in vitro drug release. Prepared NLC showed a 2-fold increase in LRD concentration in the brain when compared with the drug solution following intranasal administration. Results showed that intranasal route can be a good and efficient approach for delivering the drug directly to the brain and enhancing the drug efficacy in the brain for the management of schizophrenia and a good alternative to oral drug delivery.     

Bioavailability enhancement of ondansetron after nasal administration of Caesalpinia pulcherrima-based microspheres

Abstract

Context: Natural polymers have attracted a great deal of attention for use as potential carriers in site-specific delivery over past decades. Mucoadhesive microspheres are useful tools for nasal drug delivery.

Objectives: To prepare and evaluate mucoadhesive microspheres as mode for nasal delivery of ondansetron using Caesalpinia pulcherrima galactomannan (CPG).

Materials and methods: Conventional spray-dried CPG nasal microspheres loaded with ondansetron for intranasal drug delivery in order to avoid the first pass metabolism with improved therapeutic efficiency in treatment of nausea and vomiting as an alternative therapy to parenterals. Developed microspheres were evaluated for characteristics like particle size, entrapment efficiency, zeta potential, swelling ability, in-vitro mucoadhesion, in-vitro drug release, DSC, XRD study and histopathological evaluation of tissue. CPG-based ondansetron microspheres were studied in rabbits for screening nasal absorption potential of nasal formulation.

Results: Developed nasal microspheres possess entrapment efficiency of 80–89%, higher mucoadhesion of 72–84% across goat nasal mucosa. In-vivo study showed that microspheres based on mucoadhesive polymer were able to promote quick drug absorption as well as enhanced bioavailability of drug.

Discussion: Histopathological studies evaluated biocompatible and nontoxic nature of CPG in nasal cavity. Developed mucoadhesive microspheres by nasal route showed enhancement of bioavailability as compared to oral route in rabbits.

Conclusion: CPG-based mucoadhesive microspheres can successfully deliver ondansetron intranasally, sustain its effect, avoid first pass effect, an alternative route of administration to injection and thus enhance systemic bioavailability of ondansetron hydrochloride.     

Mannose 6‐phosphate‐modified bovine serum albumin nanoparticles for controlled and targeted delivery of sodium ferulate for treatment of hepatic fibrosis

Objectives The aim was to prepare neoglycoprotein‐based nanoparticles for targeted drug delivery to hepatic stellate cells, and to evaluate their characteristics in vitro and in vivo. Methods The neoglycoprotein of bovine serum albumin modified with mannose 6‐phosphate was synthesised from mannose, and used as wall material to nanoencapsulate the model natural antifibrotic substance sodium ferulate using a desolvation method. The morphology, drug loading capacity, release in vitro and biodistribution in vivo of the nanoparticles were studied. Selectivity of the nanoparticles for hepatic stellate cells was evaluated by immunohistochemical analysis of fibrotic rat liver sections. Key findings The spherical nanoparticles were negatively charged with zeta potential ranging from ?2.73 to ?35.85 mV, and sizes between 100 and 200 nm with a narrow size distribution. Drug entrapment efficiency of about 90% (w/w) and loading capacity of 20% (w/w) could be achieved. In vitro, the nanoparticles showed an initial rapid continuous release followed by a slower sustained release. After intravenous injection into mice, the nanoparticles showed a slower elimination rate and a much higher drug concentration in liver compared with the sodium ferrate solution, and less distribution to the kidneys and other tissues. Immunohistochemistry indicated that the neoglycoprotein‐based nano‐particles were taken up specifically by hepatic stellate cells. Conclusions The nanoparticles may be an efficient drug carrier targeting hepatic stellate cells.     

Floating-bioadhesive gastroretentive Caesalpinia pulcherrima-based beads of amoxicillin trihydrate for Helicobacter pylori eradication

Abstract

Context: An oral dosage form containing floating bioadhesive gastroretentive microspheres forms a stomach-specific drug delivery system for the treatment of Helicobacter pylori.

Objectives: To prepare and evaluate controlled release floating bioadhesive gastroretentive chitosan-coated amoxicillin trihydrate-loaded Caesalpinia pulcherrima galactomannan (CPG)-alginate beads (CCA-CPG-A), for H. pylori eradication.

Materials and methods: CCA-CPG-A beads were prepared by ionotropic gelation, using 2³ factorial design with quantity of drug, combination of CPG with sodium alginate and concentration of calcium chloride as variables. Beads facilitated mucoadhesion to gastric mucosa with floating nature caused by chitosan coating for wide distribution throughout GIT. Developed beads were evaluated for characteristics like beads size-morphology, entrapment efficiency, DSC, XRD, FTIR, swelling ratio, in vitro mucoadhesion, in vitro drug release, in vitro floating and in vitro H. pylori growth inhibition studies. CCA-CPG-A beads were studied in Wistar rats for in vivo gastric mucoadhesion, in vivo H. pylori growth inhibition studies using PCR amplification of isolated DNA, rapid urease test.

Result: Developed beads possess drug release of 79–92%, entrapment efficiency of 65–89%, mucoadhesion of 61–89%. In vivo mucoadhesion study showed more than 85% mucoadhesion of beads even after 7th hour. In vitro–in vivo growth inhibition study showed complete eradication of H. pylori.

Discussion: CPG-alginate and chitosan in beads interacts with gastric mucosubstrate surface for prolonged gastric residence with floating bioadhesion mechanism for H. pylori eradication in rats.

Conclusion: Floating bioadhesive CCA-CPG-A beads offer a promising drug delivery system for H. pylori eradication at lower dose, reduced adverse effect and enhance bioavailability.     

羟基喜树碱脂质体的制备及质量评价研究

目的:制备羟基喜树碱(HCPT)脂质体,并对其质量进行评价.方法:采用薄膜分散-高压乳匀法制备羟基喜树碱脂质体;用激光粒度分析仪测定其Zeta电位、粒径大小;考察其在0.9%NaCl溶液、水、5%葡萄糖溶液中8 h的稳定性;用凝胶柱层析法考察包封率;采用薄膜透析法考察体外释药性质.结果:羟基喜树碱脂质体Zeta电位为(-33.1±1.3) mV,平均粒径(182.5±5.6) nm,8 h内在水、5%葡萄糖溶液中稳定性良好;包封率(91.2±1.2)%;体外释药曲线符合Higuchi方程Q=1.291 6t1/2 0.309 8,r=0.980 3.结论:本试验制备的羟基喜树碱脂质体稳定性好,大小均匀, 包封率高,并具有延缓药物释放的性质.     

Development and characterization of glutathione-conjugated albumin nanoparticles for improved brain delivery of hydrophilic fluorescent marker

Abstract

The glutathione-conjugated bovine serum albumin (BSA) nanoparticles were constructed in the present exploration as a novel biodegradable carrier for brain-specific drug delivery with evaluation of its in vitro and in vivo delivery properties. BSA nanocarriers were activated and conjugated to the distal amine functions of the glutathione via carbodiimide chemistry using EDAC as a mediator. These nanoparticles were characterized for particle shape, average size, SPAN value, drug entrapment and in vitro drug release. Further, presence of glutathione on the surface of BSA nanoparticles was confirmed by Ellman’s assay, which has suggested that approximately 750 units of glutathione were conjugated per BSA nanoparticle. To evaluate the brain delivery properties of the glutathione-conjugated BSA nanoparticles fluorescein sodium was used as a model hydrophilic compound. Permeability and neuronal uptake properties of developed formulations were evaluated against the MDCK-MDR1 endothelial and neuro-glial cells, respectively. The permeability of glutathione-conjugated BSA nanoparticles across the monolayer of MDCK-MDR1 endothelial tight junction was shown significantly higher than that of unconjugated nanoparticles and fluorescein sodium solution. Similarly, glutathione-conjugated nanoparticles exhibited considerably higher uptake by neuro-glial cells which was inferred by high fluorescence intensity under microscope in comparison to unconjugated nanoparticles and fluorescein sodium solution. Following an intravenous administration, nearly three folds higher fluorescein sodium was carried to the rat brain by glutathione-conjugated nanoparticles as compared to unconjugated nanoparticles. The significant in vitro and in vivo results suggest that glutathione-conjugated BSA nanoparticles is a promising brain drug delivery system with low toxicity.     

Transferrin coupled vesicular system for intracellular drug delivery for the treatment of cancer: Development and characterization

Objectives: In the present study attempt has been made to enhance the selective tumor cell killing in mouse xenograft model using DQAsomes as a mitochondriotropic carrier and transferrin (Tf) as a ligand to target tumor cells.

Methods: Tf modified DQAsomes (Tf-DQAsomes) were prepared by incubating preformed paclitaxel loaded DQAsomes with Tf in the presence of 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide hydrochloride. Developed systems were characterized for size and size distribution, entrapment efficiency, and in vitro drug release. Fluorescence microscopy and flow cytometry were performed to evaluate cellular uptake of the carriers. Antitumor activity was determined using HeLa cells. In vivo therapeutic efficacy was determined in xenograft mouse model.

Key findings: Uptake studies demonstrated that Tf-DQAsomes result in higher flurescence intensity to the cancer cells as compared to plain DQAsomes. Tf-DQAsomes exhibited better antitumor activity in vitro as compared to plain DQAsomes and paclitaxel solution. In vivo biodistribution study revealed that paclitaxel concentration in the tumor was much higher in the case of Tf-DQAsomes as compared to plain DQAsomes and paclitaxel solution; however in other organs it was much lower than the latter two formulations. Tf-DQAsomes exhibited significant antitumor activity in the mouse xenograft model.

Conclusions: The finding demonstrated that Tf conjugated DQAsomes can effectively be delivered to the tumor in vivo and exhibit significant antitumor activity.     

Enhancement of oral insulin bioavailability: in vitro and in vivo assessment of nanoporous stimuli-responsive hydrogel microparticles

ABSTRACT

Objective: Oral insulin administration suffers gastrointestinal tract (GIT) degradation and inadequate absorption from the intestinal epithelium resulting in poor bioavailability. This study entails in vitro and in vivo assessment of stimuli-responsive hydrogel microparticles (MPs) in an attempt to circumvent GI barrier and enhance oral insulin bioavailability.

Methods: Bacterial cellulose-g-poly(acrylic acid) (BC-g-P(AA)) hydrogel MPs were evaluated for morphology, swelling, entrapment efficiency (EE), in vitro insulin release and enzyme inhibition. The ex vivo mucoadhesion, insulin degradation and transport were investigated in excised intestinal tissues. The effect of MPs on paracellular transport was studied in Caco-2/HT29-MTX monolayers. The in vivo hypoglycemic effect and pharmacokinetics of insulin-loaded MPs were investigated in diabetic rats.

Results: Hydrogel MPs efficiently entrapped insulin (EE up to 84%) and exhibited pH-responsive in vitro release. The MPs decreased the proteolytic activity of trypsin (up to 60%). Insulin transport across monolayers was increased up to 5.9-times by MPs. Histological assessment of GI tissues confirmed the non-toxicity of MPs. Orally administered insulin-loaded MPs showed higher hypoglycemic effect as compared to insulin solution and enhanced relative oral bioavailability of insulin up to 7.45-times.

Conclusion: These findings suggest that BC-g-P(AA) MPs are promising biomaterials to overcome the barriers of oral insulin delivery and enhancing its bioavailability.