Eudragit S100 coated microsponges for Colon targeting of prednisolone.

CONTEXT: Microsponge is a novel approach for targeting the drug to the colon for the management of colon ailments such as inflammatory bowel disease. OBJECTIVE: Prednisolone loaded microsponges (PLMs) were prepared and coated with Eudragit S 100 (ES) and evaluated for colon-specific drug delivery. MATERIALS AND METHODS: PLMs were prepared using quasi emulsion solvent diffusion technique using ethyl cellulose, triethylcitrate (1% v/v, plasticizer) and polyvinyl alcohol (Mol. Wt. 72 kDa, emulsifying agent). The developed microsponges were compressed into tablets via direct compression technique using sodium carboxymethyl cellulose (Na CMC) and magnesium stearate as super-disintegrant and lubricant, respectively. The tablets were then coated with ES to provide protection against harsh gastric environment and manifest colon-specific drug release. RESULTS: PLMs were found to be nano-porous spherical microstructures with size around 35 µm and 86% drug encapsulation efficiency. Finally, they were compressed into tablets which were coated with Eudragit S 100 In vitro drug release from ES coated tablets was carried out at various simulated gastrointestinal fluids i.e. 1 hr in SGF (pH 1.2), 2 to 3 h in SIF (pH 4.6), 4-5 h in SIF (pH 6.8), and 6-24 h in SCF (pH 7.4) and the results showed the biphasic release pattern indicating prolonged release for about 24 h. DISCUSSION AND CONCLUSION: In vitro drug release studies revealed that drug starts releasing after 5 h by the time PLMs may enter into the proximal colon. Hence maximum amount of drug could be released in the colon that may result in reduction in dose and dose frequency as well as side effects of drug as observed with the conventional dosage form of prednisolone.

Chondroitin sulphate: a focus on osteoarthritis.

Chondroitin sulfate (CS) being a natural glycosaminoglycan is found in the cartilage and extracellular matrix. It shows clinical benefits in symptomatic osteoarthritis (OA) of the finger, knee, hip joints, low back, facial joints and other diseases due to its anti-inflammatory activity. It also helps in OA by providing resistance to compression, maintaining the structural integrity, homeostasis, slows breakdown and reduces pain in sore muscles. It is most often used in combination with glucosamine to treat OA. CS is a key role player in the regulation of cell development, cell adhesion, proliferation, and differentiation. Its commercial applications have been continuously explored in the engineering of biological tissues and its combination with other biopolymers to formulate scaffolds which promote and accelerate the regeneration of damaged structure. It is approved in the USA as a dietary supplement for OA, while it is used as a symptomatic slow-acting drug (SYSADOA) in Europe and some other countries. Any significant side effects or overdoses of CS have not been reported in clinical trials suggesting its long-term safety. This review highlights the potential of CS, either alone or in combination with other drugs, to attract the scientists engaged in OA treatment and management across the world.

Dual Drug Delivery Using Lactic Acid Conjugated SLN for Effective Management of Neurocysticercosis.

PURPOSE: The debut study was aimed to develop Lactic acid (LA)-conjugated solid lipid nanoparticles (SLN-LA) bearing albendazole (ALB) and prednisolone (PRD) for effective management of neurocysticercosis (NCC). METHODS: LA was coupled to SLN by post-insertion technique. SLNs were characterized for particle size and size distribution, shape, and percent drug entrapment efficiency. In vitro drug release kinetics, fluorescence study and in vitro transendothelial transport, hematological studies and pharmacokinetic studies were carried out to predict the fullest drug delivery potential. RESULTS: Spherical SLNs (~100 nm) with good drug entrapments (~64 and ~78% for ALB and PRD, respectively) showed in vitro initial fast release (i.e., 20-40% drugs release in 4 h) followed by sustained release for more than 48 h. Fluorescence study and in vitro transendothelial transport depicted selective brain uptake of SLN-LA compared to SLN attributed to carrier mediated transport via monocarboxylic acid transporters (MCT - 1/2/3). Pharmacokinetic parameters such as AUC0-t and AUMC0-t and Cllast showed good drugs withholding capacity of SLNs. Organ distribution studies reflected high accumulation of drugs (ALB, 7.6 ± 0.31%; PRD, 5.21 ± 0.24%) in the brain after 24 h in case of SLN-LA as compared to plain drugs solution. SLN-LA in hematological studies revealed insignificant toxicity to blood cells. CONCLUSIONS: The overall study paved the potential advances in brain targeting with synergistic acting drugs for effective management of NCC.

Targeting liver cancer via ASGP receptor using 5-FU-loaded surface-modified PLGA nanoparticles.

CONTEXT: Liver cancer is widespread liver malignancy in the world, for an estimated one million deaths annually. OBJECTIVE: In present work, lactobionic acid conjugated PLGA nanoparticles (LDNPs) bearing 5-Fluorouracil (5-FU) were developed for targeted delivery to hepatocellular carcinoma. MATERIALS AND METHODS: Lactobionic acid conjugated PLGA was used to prepare LDNPs using modified emulsion diffusion method. RESULTS: They were characterised for particle morphology, particle size (below 150 nm), zeta potential and polydispersity index (PDI ∼0.35), entrapment efficiency (∼60.23%), and cumulative percent drug release. DISCUSSION: LDNPs in ex-vivo cell line studies on human cancer cell line HepG2 exhibited significantly higher cytotoxicity compared to 5-FU and DNPs (unconjugated PLGA NPs) with growth inhibition 50% (GI50) of 66.7 µg/mL, 50.2 µg/mL and 35.5 µg/mL, respectively. In vivo studies exhibited higher drug concentration about 37.52 ± 0.68% in liver as compared to other organs and plasma. CONCLUSION: Thus, LDNPs showed high drug loading, specificity, biocompatibility and efficacy in treatment of liver cancer.

Development of surface-functionalised nanoparticles for FGF2 receptor-based solid tumour targeting.

The surface-functionalised gelatin nanoparticles (GNPs) containing cisplatin were developed and characterised for breast cancer targeting using fibroblast growth factor-2 (FGF2) receptors which are overexpressed on breast cancer cells. The GNPs were prepared using two-step desolvation method and then the surface of GNPs was functionalised with activated heparin. They were characterised for surface morphology, particle size and size distribution, surface charge, entrapment efficiency and in vitro drug release. The results revealed that the mean diameter of GNPs was 173 ± 2.2 nm with smooth surface, which was increased to 189 ± 3.4 nm after coupling with heparin (H-GNPs). The targeting effect of H-GNPs and GNPs was investigated by in vitro cell uptake study on human breast cancer MDA-MB-231 cell line, which exhibited greater uptake of H-GNPs as compared to GNPs. Therefore, it is suggested that H-GNPs can be used as an effective carrier for solid tumour targeting.

Development of liposomes using formulation by design: Basics to recent advances.

In couple of decennia, optimization tactics for drug delivery systems have been explored widely employing Design of Experiments (DoE) for desired outcomes to overcome drawbacks of "One Factor at a Time (OFAT)"conventional technique.. To pace with advances in computational approaches engaged in research domain, QbD-based tactic i.e. Formulation by Design (FbD) is under extensive investigation by budding scientists for better know-how of the product and process development for an unequivocal universal acceptation. Like other vesicular drug carriers, liposomes also demand robustness and reproducibility to scale up at industrial outset. Based on said outlook, this review focuses on the fundamentals and methodologies like Central Composite, Simplex Mixture, Box-Behnken, Factorial, Taguchi, Simplex Centroid, d-optimal, Placket Burman, and Orthogonal array with special reference to applications of FbD in the development of liposomes.

Oral Insulin: Myth or Reality.

BACKGROUND: Diabetes Mellitus (DM) is a disorder of glucose metabolism marked by hyperglycemia, glycosuria, hyperlipidemia, negative nitrogen balance and ketonaemia. DM is a major healthcare problems today and its treatment costs billions of dollars worldwide annually. The cases of diabetes have increased rapidly in recent years throughout the world. Currently, for the management of Type-1 Diabetes Mellitus (TIDM), Multiple Daily Insulin (MDI) injections is the most popular treatment. Oral administration of insulin is the most suitable and attractive as compared to subcutaneous route but unfortunately cannot be utilized for the administration of peptides and proteins due to poor epithelial permeability and enzymatic degradation within the gastrointestinal tract. Since many years, extensive research has been carried out to explore the potential ways of insulin administration based on novel methods such as liposome, microsphere, nanoparticle, mouth dissolving strips, sprays exploiting oral and pulmonary route. These next generation efficient therapies for T1DM may help to improve the quality of life of diabetic patients especially in Insulin Dependent Diabetes Mellitus (IDDM). CONCLUSION: This review emphasizes on the most recent progress made in the development of oral insulin delivery formulations, and focuses on key lessons and implications from studies undertaken till date with the oral insulin formulations. Further, this review analyzes effectiveness of the advancements, applications and limitations of the technologies in delivering insulin to the targeted site through oral administration.

Topotecan Liposomes: A Visit from a Molecular to a Therapeutic Platform.

Topotecan (TPT), a potent anticancer camptothecin analog, is well described for the treatment of ovarian cancer, but has also anticancer activity against small-cell and non-small-cell lung cancer, breast cancer, and acute leukemia. Various nanocarriers, including liposomes, have been exploited for targeted delivery of TPT. However, there are a number of challenges with TPT delivery using TPT liposomes (TLs), such as low encapsulation efficiency, physiological pH labile E ring (hydrolysis), accelerated blood clearance, multidrug resistance, and cancer metastases. This review discusses these problems and the means to overcome them, including modification of TLs using zwitterionic poly(carboxybetaine), prolongation in dosing interval (long-term therapy), and modified liposomal encapsulation techniques including active loading methods. We also explore engineered TLs (surface and integral modifications) such as PEGylated TLs, ligand-anchored TLs, and stimuli-sensitive TLs. Further, potential applications, manifestations at the molecular level, patents granted, and preclinical and clinical outlook for TLs are discussed.

Microsponges: A Pioneering Tool for Biomedical Applications.

Microparticulate drug delivery systems have been explored across the globe due to their various advantages. In 1987, Won developed microsponge systems (Micsys), also known as solid-phase porous microspheres, having numerous interconnected voids, which serve as non-collapsible residence for bioactive compounds. A Micsys particle ranges from 5 to 300 µm in size and shows a wide range of entrapment efficiency with desired release rates. This topical drug delivery system bestows a controlled release of bioactive compounds into the skin with reduced systemic side effects. Currently, the application fields of this promising system include oral, ocular, pulmonary, and parenteral delivery of bioactive compounds. In the present review, we summarize the updated biomedical application potential of Micsys as an effective drug-delivery vector, including an in-depth explanation of the drug-release kinetic models and drug-release mechanisms. We also discuss different techniques used to prepare a Micsys, along with their advantages and disadvantages. Moreover, in this review, we report a plethora of Micsys details, such as drug candidates and polymers, exploited in this field, along with marketed formulations, characterization methods, clinical perspectives, and patents received. This assembly of detailed literature summaries will contribute to future advances in the development of porous carriers.

Targeting of AIDS related encephalopathy using phenylalanine anchored lipidic nanocarrier.

Transport of the anti-HIV agents across the blood-brain barrier (BBB) is a prerequisite to treat acquired immunodeficiency syndrome (AIDS) related encephalopathy. In the present study, we explored facilitated transport of efavirenz (EFV, a non-nucleoside reverse transcriptase inhibitor) across BBB using phenylalanine anchored solid lipid nanoparticles (PA-SLN). PA (amino acid micro-nutrient) was used as a ligand which facilitated carrier mediated transport (CMT) via l-amino acid transporter i.e. LAT1 to traverse BBB. PA was coupled to SLN via amide linkage using carbodiimide chemistry and coupling was confirmed by comparative infrared spectroscopic analysis. SLNs (SLN and PA-SLN) were nanometric in size (around 150nm) and possessed good entrapment efficiency (around 70%). In vitro drug release revealed controlled release pattern for more than 24h. In vivo studies showed 2-3-folds and 7-8-folds accumulation of PA-SLN in brain as compared to SLN and EFV, respectively. Further, transcytosis studies confirmed capability of PA-SLN to cross BBB i.e. 10-fold higher transcytosis potential as compared to EFV. Fluorescence microscopic imaging reassured enhanced brain localization of PA-SLN. Thus, PA-SLN improved the EFV bioavailability and maintained therapeutic levels in the brain for an extended period of time that can result in significant eradication of the viral load therein. Such nutrient mediated drug targeting could bring forth advances in biocompatible and biodegradable drug delivery systems.

Eudragit S100 Coated Citrus Pectin Nanoparticles for Colon Targeting of 5-Fluorouracil.

In the present study, Eudragit S100 coated Citrus Pectin Nanoparticles (E-CPNs) were prepared for the colon targeting of 5-Fluorouracil (5-FU). Citrus pectin also acts as a ligand for galectin-3 receptors that are over expressed on colorectal cancer cells. Nanoparticles (CPNs and E-CPNs) were characterized for various physical parameters such as particle size, size distribution, and shape etc. In vitro drug release studies revealed selective drug release in the colonic region in the case of E-CPNs of more than 70% after 24 h. In vitro cytoxicity assay (Sulphorhodamine B assay) was performed against HT-29 cancer cells and exhibited 1.5 fold greater cytotoxicity potential of nanoparticles compared to 5-FU solution. In vivo data clearly depicted that Eudragit S100 successfully guarded nanoparticles to reach the colonic region wherein nanoparticles were taken up and showed drug release for an extended period of time. Therefore, a multifaceted strategy is introduced here in terms of receptor mediated uptake and pH-dependent release using E-CPNs for effective chemotherapy of colorectal cancer with uncompromised safety and efficacy.

Aceclofenac-loaded chondroitin sulfate conjugated SLNs for effective management of osteoarthritis.

UNLABELLED: Abstract Background: In intra-articular drug delivery, there are number of shortcomings such as lymphatic drainage from the synovial cavity, frequent dosing, adverse side effects and patient discomfort in the management of osteoarthritis (OA). PURPOSE: This research work reports the development and characterization of aceclofenac-loaded chondroitin sulfate (CS) conjugated (CS-SLN) and unconjugated solid lipid nanoparticles (SLN) for the effective management of OA. METHODS: The SLNs were prepared using modified solvent injection method and coupled with CS. They were further characterized for size and size distribution, zeta potential, surface morphology, % entrapment efficiency and in vitro drug release profile. Anti-inflammatory activity and in vivo performance was also predicted. RESULTS: The particle size of the SLN and CS-SLN was found to be 143.4 ± 0.9 nm and 154.2 ± 1.1 nm, respectively. SLNs exhibited sustained drug release (SLN, 64.25 ± 0.75%; CS-SLN, 57.82 ± 0.62%) in vitro for more than 24 h. In vivo performance studies revealed the highest uptake of SLNs by the knee joint. DISCUSSION: SLNs enhanced accumulation at the knee joint due to specific interactions with CD44, annexin and leptin receptors attributed to CS coupling. CONCLUSION: CS-SLN could be potentially effective vector for the treatment or management of OA.

Development and validation of the HPLC method for simultaneous estimation of Paclitaxel and topotecan.

A simple, rapid, accurate and precise high performance liquid chromatography (HPLC) method for simultaneous analysis of Paclitaxel and Topotecan was developed. Different analytical parameters, such as linearity, accuracy, precision, specificity with intentional degradation, limit of detection and limit of quantification (LOQ), were determined according to the ICH guidelines. Acetonitrile-water (70:30, 0.1% trifluoroacetic acid) was run on a Phenomenex Luna C-18(2) column in isocratic mode at a flow rate of 1.2 mL/min for simultaneous analysis of the two drugs using a UV detector set at 227 nm. The proposed method showed a retention time (Rt) of 14.56 min for Topotecan and 23.81 min for Paclitaxel with a continuous run up to 30 min. The linearity of the calibration curves for each analyte in the desired concentration range was found to be good (r(2) > 0.9995). The recovery ranged from 97.9 to 101% for each drug with a relative standard deviation (%RSD) of <2%. Peaks corresponding to each of the drugs exhibited  positive values for the minimum peak purity index over the entire range of integrated chromatographic peak indicating high purity of the peaks. Stability analysis revealed that the drugs remained stable for sufficient time. Thus, the developed method was found to be robust and it can be employed to quantify Paclitaxel and Topotecan in commercial sample and rat blood/serum.

Low Density Lipid Nanoparticles for Solid Tumor Targeting.

One of the most significant characteristics of cancer cells is their rapid dividing ability and overexpression of LDL receptors, which offers an opportunity for the selective targeting of these cells. 5-Fluorouracil (5-FU)-encapsulated low density lipid nanoparticles (LDLN) were prepared by the emulsion congealing method which mimics the plasma-derived LDL by acquiring the apolipoprotein B-100 from the blood. The average particle size, transmission electron microscope (TEM), and drug content of the prepared LDLN dispersion were found to be 161±3.5 nm, with spherical shape, and 0.370±0.05 mg/mL, respectively. In vitro release studies revealed a sustained profile which decreased with a lapse of time. In vivo studies of 5-FU serum concentration and biodistribution revealed a 5-FU serum concentration of 8.5% in tumor cells and about 2.1% in the liver at the end of 24 hr from LDLN. Tumor growth suppression studies showed 185.42% average tumor growth and 89.76% tumor height as compared to the control exhibiting tumor growth at 1166.47% and tumor height at 176.07%. On the basis of these collective data, it is suggested that a higher accumulation of LDLN, when given as an IV, in solid tumors is attributed to the active uptake of LDLN via LDL receptors via apolipoprotein B-100.

Insulin delivery through nasal route using thiolated microspheres.

The aim of the present study was to investigate the potential of developed thiolated microspheres for insulin delivery through nasal route. In the present study, cysteine was immobilized on carbopol using EDAC. A total of 269.93 µmol free thiol groups per gram polymer were determined. The prepared nonthiolated and thiolated microspheres were studied for particle shape, size, drug content, swellability, mucoadhesion and in vitro insulin release. The thiolated microspheres exhibited higher mucoadhesion due to formation of covalent bonds via disulfide bridges with the mucus gel layer. Drug permeation through goat nasal mucosa of nonthiolated and thiolated microspheres were found as 52.62 ± 2.4% and 78.85 ± 3.1% in 6 h, respectively. Thiolated microspheres bearing insulin showed better reduction in blood glucose level (BGL) in comparison to nonthiolated microspheres as 31.23 ± 2.12% and 75.25 ± 0.93% blood glucose of initial BGL were observed at 6 h after nasal delivery of thiolated and nonthiolated microspheres in streptozotocin-induced diabetic rabbits.

A new horizon in modifications of chitosan: syntheses and applications.

Chitosan is a naturally occurring biopolymer having diversified applications not only in the pharmaceutical field, but also in the biomedical profession. The presence of functional groups, i.e., hydroxyl, acetamido, and amine in the chitosan parent backbone, makes it a suitable candidate for chemical modification, and introduces desired physicochemical and biochemical properties, without any changes in its fundamental skeleton. The various modifications, i.e., alkylation, acylation, quaternization, hydroxyalkylation, carboxyalkylation, thiolation, sulfation, phosphorylation, enzymatic modifications, oligomerization, and graft copolymerization with assorted modifications, and their pharmaceutical and biomedical applications, are discussed in this article. Additionally, it is also limelighted how the chemically engineered chitosan has established a better place with regard to the vista of applications in the arena of sciences such as pharmaceutical, biomedical, biotechnological, tissue engineering, the textile industry, chemistry, the food industry, and many more. This review, hopefully, could enrich knowledge and bring forth new thoughts in line with progress in chitosan polymer science.

Peptide and protein delivery using new drug delivery systems.

Pharmaceutical and biotechnological research sorts protein drug delivery systems by importance based on their various therapeutic applications. The effective and potent action of the proteins/peptides makes them the drugs of choice for the treatment of numerous diseases. Major research issues in protein delivery include the stabilization of proteins in delivery devices and the design of appropriate target-specific protein carriers. Many efforts have been made for effective delivery of proteins/peptidal drugs through various routes of administrations for successful therapeutic effects. Nanoparticles made of biodegradable polymers such as poly lactic acid, polycaprolactone, poly(lactic-co-glycolic acid), the poly(fumaric-co-sebacic) anhydride chitosan, and modified chitosan, as well as solid lipids, have shown great potential in the delivery of proteins/peptidal drugs. Moreover, scientists also have used liposomes, PEGylated liposomes, niosomes, and aquasomes, among others, for peptidal drug delivery. They also have developed hydrogels and transdermal drug delivery systems for peptidal drug delivery. A receptor-mediated delivery system is another attractive strategy to overcome the limitation in drug absorption that enables the transcytosis of the protein across the epithelial barrier. Modification such as PEGnology is applied to various proteins and peptides of the desired protein and peptides also increases the circulating life, solubility and stability, pharmacokinetic properties, and antigenicity of protein. This review focuses on various approaches for effective protein/peptidal drug delivery, with special emphasis on insulin delivery.