Girish K. Gupta

Emerging trend in nano-engineered polyelectrolyte-based surrogate carriers for delivery of bioactives.

Importance of the field: In recent decades a new colloidal drug delivery system based on layer-by-layer (LbL) technology has emerged, which offers promising means of delivering bioactive agents, specifically biological macromolecules including peptides and DNA. Nano-engineered capsules specifically fabricated from biocompatible and biodegradable polyelectrolytes (PEs) can provide a better option for encapsulation of cells thereby protecting cells from immunological molecules in the body, and their selective permeability can ensure the survival of encapsulated cells. Areas covered in this review: This review encompasses a strategic approach to fabricate nano-engineered microcapsules through meticulous selection of polyelectrolytes and core materials based on LbL technology. The content of the article provides evidence for its wide array of applications in medical therapeutics, as indicated by the quantity of research and patents in this area. Recent developments and approaches for tuning drug release, biocompatibility and cellular interaction are discussed thoroughly. What the reader will gain: This review aims to provide an overview on the development of LbL capsules with specific orientation towards drug and macromolecular delivery and its integration with other drug delivery systems, such as liposomes. Take home message: Selection of PEs for the fabrication of LbL microcapsules has a profound effect on stability, drug release, biocompatibility and encapsulation efficacy. The release can be easily modulated by varying different physicochemical as well as physiological conditions. Scale-up approaches for the fabrication of LbL microcapsules by means of automation must be considered to improve the possibility of application of LbL microcapsules on a large scale.

In vivo efficacy studies of layer-by-layer nano-matrix bearing kaempferol for the conditions of osteoporosis: A study in ovariectomized rat model

A prototype formulation based on layer-by-layer (LbL) nano-matrix was developed to increase bioavailability of kaempferol with improved retention in bone marrow to achieve enhanced bone formation. The layer-by-layer nano-matrix was prepared by sequential adsorption of biocompatible polyelectrolytes over the preformed kaempferol-loaded CaCO(3) template. The system was pharmaceutically characterized and evaluated for osteogenic activity in ovariectomized (OVx) rats. Data have been compared to the standard osteogenic agent parathyroid hormone (PTH). Single oral dose of kaempferol loaded LbL nano-matrix formulation increased bioavailability significantly compared to unformulated kaempferol. Three months of Formulated kaempferol administration to osteopenic rats increased plasma and bone marrow Kaempferol levels by 2.8- and 1.75-fold, respectively, compared to free Kaempferol. Formulated Kaempferol increased bone marrow osteoprogenitor cells, osteogenic genes in femur, bone formation rate, and improved trabecular micro-architecture. Withdrawal of Formulated kaempferol-in OVx rats resulted in the maintenance of bone micro-architecture up to 30days, whereas micro-architectural deterioration was readily observed in OVx rats treated with unformulated kaempferol-within 15days of withdrawal. The developed novel formulation has enhanced anabolic effect in osteopenic rats through increased stimulatory effect in osteoblasts. Treatment post-withdrawal sustenance of formulated kaempferol could become a strategy to enhance bioavailability of flavanoids.

Osteogenic efficacy enhancement of kaempferol through an engineered layer-by-layer matrix: a study in ovariectomized rats

AIM A layer-by-layer matrix (LBL) comprising kaempferol (LBL-KEM) was prepared for improved osteogenic action. MATERIALS & METHODS The LBL-KEM consisted of alternate layers of sodium alginate and protamine sulfate, which were sequentially deposited on the preformed kaempferol (KEM)-loaded CaCO3 core (CaCO3-KEM) by LBL self-assembly. The LBL matrix developed was evaluated for layer growth by ζ-potential and size alterations after self-assembly of each layer. Its physicochemical properties and intestinal absorption pattern were characterized and its pharmacokinetic behavior, mineralization of bone marrow cells, bone mineral density, bone strength, microcrack formation and estrogenicity were evaluated after oral administration. RESULTS The entrapment efficiency of KEM was 94 ± 2% and the cumulative %KEM released from LBL-KEM was 19.2 and 63.5% at pH 1.4 and 7.4, respectively, after 24 h. Stepwise polyelectrolyte assembly onto initially positively charged particles (+21.2 mV) resulted in alterations between -28.5 and +10.9 mV. A final ζ-potential of -8.9 mV was obtained after terminal surface modification with sodium deoxycholate. Fluorescein isothiocyanate-labeled LBL matrix was diffused into the basolateral lacteal region upon oral administration to rats. The area under the KEM serum concentration curve following oral administration of LBL-KEM to rats was 2479 ± 682 ng·h/ml, nearly twofold higher than free KEM. The concentration-time profile in bone marrow indicated improved penetration and retention of KEM on administration of LBL-KEM. Treatment with LBL-KEM restored bone mineralization, bone mineral density, microcrack formation and empty osteocyte lacunae density in ovariectomized (OVx) rats, which was significantly (p < 0.05) improved in femoral diaphysea, tibial head and vertebrae compared with free KEM treatment. Administration of LBL-KEM to growing female rats for 4 weeks resulted in no estrogenicity when compared with OVx rats. CONCLUSION The data suggests that LBL matrix enhanced drug delivery, improved pharmacokinetics and maintained better bone quality under OVx conditions.

Uptake of Biodegradable Gel-Assisted LBL Nanomatrix by Leishmania donovani-Infected Macrophages

The aim of this study was to develop novel gel-assisted layer-by-layer (LBL) nanomatrix with high payload of doxorubicin (DOX) and to assess its efficacy against Leishmania donovani. The biodegradable LBL nanomatrix was fabricated using LBL technique using polyions (protamine and sodium alginate) on decomposable core. The developed system was characterized in vitro in terms of layer-by-layer growth and payload efficiency. The efficacy of optimized formulations was evaluated against L. donovani strain in terms of inhibitory concentration (IC50). Uptake studies by infected macrophages were investigated both qualitatively and quantitatively using fluorescence microscopy and flow cytometry. The autogelling property subsequent to core removal inside the nanomatrix resulted in high payload efficiency of DOX (i.e., >70%). The reversal in charge followed the same trend with additional layers, and the magnitude of the charge remained constant up to five complete bilayers of polyions. The DOX can be effectively encapsulated, delivered, and subsequently taken up by L. donovani-infected macrophage cells. The matrix is completely internalized into macrophages showing improved efficacy (IC50 of formulation is almost ≤1.9-fold as compared to plain drug, P < 0.05) against intracellular amastigotes. Having ample of opportunity to manipulate surface architecture, this system demonstrates unique platform as a low cost ideal substitute for visceral leishmaniasis to expensive lipid-based formulations.

Development of docetaxel nanocapsules for improving in vitro cytotoxicity and cellular uptake in MCF-7 cells

Abstract The aim of this study was to fabricate docetaxel loaded nanocapsules (DTX-NCs) with a high payload using Layer-by-Layer (LbL) technique by successive coating with alternate layers of oppositely charged polyelectrolytes. Developed nanocapsules (NCs) were characterized in terms of morphology, particle size distribution, zeta potential (ζ-potential), entrapment efficiency and in vitro release. The morphological characteristics of the NCs were assessed using transmission electron microscopy (TEM) that revealed coating of polyelectrolytes around the surface of particles. The developed NCs successfully attained a submicron particle size while the ζ-potential of optimized NCs alternated between (+) 34.64 ± 1.5 mV to (−) 33.25 ± 2.1 mV with each coating step. The non-hemolytic potential of the NCs indicated the suitability of the developed formulation for intravenous administration. A comparative study indicated that the cytotoxicity of positively charged NCs (F4) was significant higher (p < 0.05) rather than negative charged NCs (F3), plain drug (DTX) and marketed preparation (Taxotere®) when evaluated in vitro on MCF-7 cells. Furthermore, cell uptake studies evidenced a higher uptake of positive NCs (≥1.2 fold) in comparison to negative NCs. In conclusion, formulated NCs are an ideal vehicle for passive targeting of drugs to tumor cells that may result in improved efficacy and reduced toxicity of encapsulated drug moiety.

Galactose‐grafted chylomicron‐mimicking emulsion: evaluation of specificity against HepG‐2 and MCF‐7 cell lines

Objectives A chylomicron‐mimicking lipid emulsion was prepared and loaded with paclitaxel (paclitaxel‐CM) and was further grafted with galactose (paclitaxel‐GCM) using palmitoyl‐galactosamine, which was synthesized by reacting galactosamine hydrochloride with N‐hydroxy succinimide ester of palmitic acid. Palmitoyl‐galactosamine was used as a ligand for asialoglycoprotein receptors.

Antiviral efficacy of homœopathic drugs against animal viruses

Summary The antiviral effect of homœopathic drugs against two animal viruses, Chicken Embryo Virus (CEV) of fowls and Simliki Forest Virus (SFV), causing encephalitis and death in mice were investigated. In all 10 drugs in 33 potencies were tested against CEV and 8 drugs in 26 potencies showed varying degree of virus inhibition. The drugs that caused 100% inhibition of CEV were Typhoidinum 200, Hydrophobinum 1000, Tuberculinum 1000, Nux vomica 200, and Malandrinum 1000. Of the drugs tested in 11 potencies against SFV, none were found effective in either preventing disease or death of mice infected with this virus.

Ciprofloxacin surf-plexes in sub-micron emulsions: A novel approach to improve payload efficiency and antimicrobial efficacy

The aim of this study was to investigate antimicrobial efficacy and pharmacokinetic profile of ciprofloxacin (CFn) loaded oil-in-water (o/w) submicron emulsion (SE-CFn). This study emphasized on development of hydrophobic ion-pair complexes of CFn with sodium deoxycholate (SDC) [CFn-SDC], which was incorporated in the core of SE (SE-CFn-SDC). SE-CFn-SDC was characterized for globulet size (278±12 nm), zeta potential (-25.3±1 mV), viscosity (2.6±0.3 cP), transmission electron microscopy (TEM), drug entrapment and for in vitro release profile. The entrapment efficiency (EE) was significantly improved (≥80%; p≤0.05) on ion-pairing while it was merely 27.2±3.1% for free CFn. The cytotoxicity studies of formulations on J774 macrophage cells showed that more than 90±3% of cells were viable, even at high concentration (100 μg/ml). SE-CFn-SDC was further modified with cationic inducer chitosan (SE-CH-CFn-SDC), which showed almost twofold and fourfold enhancement in antimicrobial efficacy as compared to SE-CFn-SDC and SE-CFn, respectively when tested in vitro against E. coli, S. aureus, and P. aeruginosa. When tested in male Balb/c mice, the AUC(0-24h) of SE-CH-CFn-SDC (23.27±2.8 h μg/ml) was found to be 1.7-fold and 5-fold higher as compared to SE-CFn-SDC (13.17±0.88 h μg/ml) and CFn solution (4.70±0.77 h μg/ml), respectively. The study demonstrates that surfactant based ionic complex formation incorporated in surface modified submicron emulsion is a promising approach to improve payload efficiency of poorly water soluble drugs with improved antimicrobial efficacy and pharmacokinetic profile.

Investigations on cellular interaction of polyelectrolyte based nano-walled reservoir using MCF-7 cell lines: a novel chemotherapeutic approach

Objectives A polyelectrolyte (PE) based nano‐walled reservoir (NwR) was developed using alternate deposition of natural polyions on a decomposable core (CaCO3). The system was charged with paclitaxel (PTX) using the trigger property of an organic solvent (NwR‐PTX). In addition, the surface of the nano‐walled reservoir was modified with PE‐PEG2000 (NwR‐PTX‐PEG)) in order to investigate any changes in the interaction of surface‐modified polyelectrolyte shells with breast cancer cells, since surface chemistry greatly influences the performance of microcapsules in the biological environment.

Templated Ultrathin Polyelectrolyte Microreservoir for Delivery of Bovine Serum Albumin: Fabrication and Performance Evaluation

The aim of the study was to develop ultrathin polyelectrolyte microreservoir (UPM) using two combinations of synthetic/synthetic (S/s; poly(allylamine hydrochloride) (PAH)/sodium poly(styrenesulfonate)) and synthetic/natural (S/n; PAH/sodium alginate) polyelectrolytes over spherical porous CaCO3 core particles (CP) followed by core removal and to evaluate its biocompatibility and integrity of loaded model protein bovine serum albumin (BSA). A novel process for synthesis of CP was developed to obtain maximum yield of monodisperse vaterite (spherical) polymorph. The prepared UPM was characterized for surface morphology, layer-by-layer growth, pay load efficiency, integrity of BSA, as well as viability and cell adhesion using murine J 774 macrophages (Φ). In vitro release profile revealed that both S/s and S/n UPM were able to provide sufficient diffusion barrier to release protein at physiological pH. It has been observed that S/n UPM are fully biocompatible due to obvious reason of using natural polymer. In a separate experiment, the S/s UPM surface was modified with pluronic F-68 to tune biocompatibility which provides evidences for safety and tolerability of the S/s UPM as well. In nutshell, the proposed system could successfully be used for the delivery of proteins, and moreover, the system can be tailored to impart desired properties at any stage of layering especially in terms of drug release and to retain the integrity of proteins.