Development, optimization, and in vitro characterization of dasatinib-loaded PEG functionalized chitosan capped gold nanoparticles using Box-Behnken experimental design.

OBJECTIVE: The purpose of this research study was to develop, optimize, and characterize dasatinib loaded polyethylene glycol (PEG) stabilized chitosan capped gold nanoparticles (DSB-PEG-Ch-GNPs). METHODS: Gold (III) chloride hydrate was reduced with chitosan and the resulting nanoparticles were coated with thiol-terminated PEG and loaded with dasatinib (DSB). Plackett-Burman design (PBD) followed by Box-Behnken experimental design (BBD) were employed to optimize the process parameters. Polynomial equations, contour, and 3D response surface plots were generated to relate the factors and responses. The optimized DSB-PEG-Ch-GNPs were characterized by FTIR, XRD, HR-SEM, EDX, TEM, SAED, AFM, DLS, and ZP. RESULTS: The results of the optimized DSB-PEG-Ch-GNPs showed particle size (PS) of 24.39 ± 1.82 nm, apparent drug content (ADC) of 72.06 ± 0.86%, and zeta potential (ZP) of -13.91 ± 1.21 mV. The responses observed and the predicted values of the optimized process were found to be close. The shape and surface morphology studies showed that the resulting DSB-PEG-Ch-GNPs were spherical and smooth. The stability and in vitro drug release studies confirmed that the optimized formulation was stable at different conditions of storage and exhibited a sustained drug release of the drug of up to 76% in 48 h and followed Korsmeyer-Peppas release kinetic model. CONCLUSIONS: A process for preparing gold nanoparticles using chitosan, anchoring PEG to the particle surface, and entrapping dasatinib in the chitosan-PEG surface corona was optimized.

Development and optimization of locust bean gum and sodium alginate interpenetrating polymeric network of capecitabine.

OBJECTIVE: The objective of the study was to develop interpenetrating polymeric network (IPN) of capecitabine (CAP) using natural polymers locust bean gum (LBG) and sodium alginate (NaAlg). SIGNIFICANCE: The IPN microbeads were optimized by Box-Behnken Design (BBD) to provide anticipated particle size with good drug entrapment efficiency. The comparative dissolution profile of IPN microbeads of CAP with the marketed preparation proved an excellent sustained drug delivery vehicle. METHODS: Ionotropic gelation method utilizing metal ion calcium (Ca2+) as a cross-linker was used to prepare IPN microbeads. The optimization study was done by response surface methodology based Box-Behnken Design. The effect of the factors on the responses of optimized batch was exhibited through response surface and contour plots. The optimized batch was analyzed for particle size, % drug entrapment, pharmacokinetic study, in vitro drug release study and further characterized by FTIR, XRD, and SEM. To study the water uptake capacity and hydrodynamic activity of the polymers, swelling studies and viscosity measurement were performed, respectively. RESULTS: The particle size and % drug entrapment of the optimized batch was 494.37 ± 1.4 µm and 81.39 ± 2.9%, respectively, closer to the value predicted by Minitab 17 software. The in vitro drug release study showed sustained release of 92% for 12 h and followed anomalous drug release pattern. The derived pharmacokinetic parameters of optimized batch showed improved results than pure CAP. CONCLUSION: Thus, the formed IPN microbeads of CAP proved to be an effective extended drug delivery vehicle for the water soluble antineoplastic drug.

Myricetin encapsulated chitosan nanoformulation for management of type 2 diabetes: Preparation, optimization, characterization and in vivo activity.

Type 2 diabetes mellitus (T2DM) is a serious and alarming disease attracting widespread attention. It is not a single metabolic disease; over time, it leads to serious disorders, namely, diabetic nephropathy, neuropathy, retinopathy and several cardiovascular, hepatocellular complications. The increase in T2DM cases in recent times has attracted significant attention. Currently, the medications available have side effects, and injectables are painful, causing trauma to the patients. Therefore, it is imperative to come up with oral delivery. In this background we report here a nanoformulation carrying natural small molecule Myricetin (MYR) encapsulated within Chitosan nanoparticles (CHT-NPs). MYR-CHT-NPs were prepared by ionic gelation method and evaluated using different characterization techniques. The in vitro release of MYR from CHT NPs in different physiological media showed pH dependence. in vivo pharmacodynamic study followed by oral administration in Albino Wistar rats showed better glycaemic control than existing drug. Further, the optimized nanoparticles also exhibited controlled increase in weight as compared to Metformin. The biochemistry profile of rats treated with nanoformulation reduced the levels of several pathological biomarkers, indicating additional benefits of MYR. Histopathological images exhibited no toxicity or changes in the major organs section in contrast to normal control, suggesting safe oral administration of the encapsulated MYR. Thus, we conclude that MYR-CHT-NPs represent an attractive delivery vehicle in improving the blood glucose level with controlled weight and have the potential to be safely administered orally for the management of T2DM.

A novel method for the chaperone aided and efficient production of human proinsulin in the prokaryotic system.

With the rapid spread of diabetes in human society, the demand for insulin and its precursor (proinsulin) continues to rise. Therefore, the introduction of new methods for their production is essential. In the present study, human proinsulin, while ligated to αB-crystallin chaperone, was effectively expressed in the prokaryotic host system and then purified by the ion-exchange chromatography at high purity (>97%). In the next step, human proinsulin with relatively high efficiency was released chemically from the hybrid protein (αB-pIns) and then purified using an appropriate gel filtration column. The SDS-PAGE and HPLC analyses confirmed the high purity, while mass spectroscopy assessment verified the exact molecular mass of the human proinsulin. Using a well-established protocol, the protein was folded in a one-step folding process with a yield of about 70%. The assessment of the secondary structures of the human proinsulin by Raman and FTIR spectroscopy suggested that this protein is rich in α-helix. Also, the conformation of disulfide bonds in the folded proinsulin was confirmed by Raman spectroscopy. The recombinant human proinsulin also demonstrated hypoglycemic activity and mitogenic action (induction of cell proliferation). The method proposed in this work for the production of human proinsulin is easy to run and does not depend on expensive and complex equipment. Thus, it can be used in the industrial production of human proinsulin.

Developing a novel exenatide-based incretin mimic (αB-Ex): Expression, purification and structural-functional characterization.

Among the various treatments, GLP-1 receptor agonists (incretin mimics) such as liraglutide and exenatide have been well received in treating type 2 diabetes mellitus (T2DM) and obesity. In this study, an exenatide analogue, in which methionine at position 14 substituted with leucine, was ligated to human αB-crystallin (αB-Cry) and then expressed in the bacterial host cells. In the next step, the exenatide analogue was effectively released from the hybrid protein (αB-Ex) and subsequently purified using gel filtration chromatography. The HPLC and electrospray ionization mass spectrometry (ESI-MS) analyses respectively suggested a high purity (more than 97%) and an accurate molecular mass for the exenatide analogue (4168.22 Da and 835.01, z = 5). Also, the molecular mass of the αB-Ex hybrid protein based on the MALDI-TOF analysis was 24,702.162 Da. The secondary structure assessment by the three spectroscopic methods revealed that exenatide analogue and αB-Ex hybrid protein have an α-helix and a ß-sheet rich structure, respectively. Also, according to the results of the DLS analysis, the αB-Ex hybrid protein indicated a high tendency to form large oligomeric structures. The NMR assessment suggested that the hybrid protein exists in its folding state. Both exenatide analogue and the αB-Ex hybrid protein revealed a crucial ability to reduce the blood sugar levels in healthy and diabetic mice. They were also capable of inducing insulin secretion to the bloodstream. Overall, our study introduces the αB-Ex hybrid protein as a novel incretin mimic, exerting its biological activity for a longer period of time. It might also be considered a potential drug candidate in the treatment of T2DM.

Gold nanoparticles for sustained antileukemia drug release: development, optimization and evaluation by quality-by-design approach.

AIM: To design, develop, optimize and evaluate sustained-release dasatinib-loaded gold nanoparticles (DSB-GNPs) to treat chronic myeloid leukemia (CML) by using quality by design. MATERIALS & METHODS: In this study, we performed risk assessment, optimization, in vitro characterizations, stability study, drug release studies, cytotoxicity study and in vivo pharmacokinetic evaluation. RESULTS: DSB-GNPs of desired size, entrapment, smooth, spherical, stable and sustained drug release for 48 h were achieved. DSB-GNPs exhibited significantly more percentage growth inhibition and enhanced systemic bioavailability compared with pure DSB. CONCLUSION: The in vitro and in vivo evaluation exhibited that the DSB-GNPs have a potential cytotoxic effect, systemic bioavailability and sustained release making them a promising system of DSB delivery in the treatment of chronic myeloid leukemia.

Locust bean gum and sodium alginate based interpenetrating polymeric network microbeads encapsulating Capecitabine: Improved pharmacokinetics, cytotoxicity &in vivo antitumor activity.

A combination of biopolymers sodium alginate and locust bean gum has been used to prepare an interpenetrating polymeric network of an anticancer drug Capecitabine by ionotropic gelation method. For the optimization 32 levels, a full factorial design was employed to examine the influence of independent factors, i.e. polymer ratio and cross-linker concentration on responses particle size and drug entrapment. The obtained optimized formulation was examined for solid-state characterization, swelling study, in vitro drug release, SRB study, oral toxicity study, in vivo pharmacokinetic and in vivo antitumor study. The results of all the studies performed were found suitable in extending the release of a short elimination half-life drug with improved bioavailability and suggesting it to be safe and effective for oral drug delivery in treating colon cancer.

Development of biopolymers based interpenetrating polymeric network of capecitabine: A drug delivery vehicle to extend the release of the model drug.

The research aims the development and optimization of capecitabine loaded interpenetrating polymeric network by ionotropic gelation method using polymers locust bean gum and sodium alginate by QbD approach. FMEA was performed to recognize the risks influencing CQAs. BBD was applied to study the effect of factors (polymer ratio, amount of cross-linker and curing time) on responses (particle size, % drug entrapment and % drug release). Polynomial equations and 3-D graphs were plotted to relate between factors and responses. The results of the optimized batch viz. particle size (457.92 ±â€¯1.6 µm), % drug entrapment (74.11 ±â€¯3.1%) and % drug release (90.23 ±â€¯2.1%) were close to the predicted values generated by Minitab® 17. Characterization techniques SEM, EDX, FTIR, DSC and XRD were also performed for the optimized batch. To study the water transport inside IPN microbeads, swelling study was done. In vitro drug release of optimized batch showed controlled drug release for 12 h. Pharmacokinetic study carried out following oral administration in Albino Wistar rats exhibited that optimized microbeads had better PK parameters than free drug. In vitro cytotoxicity against HT-29 cells revealed significant reduction of the cell growth when treated with optimized formulation indicating IPN microbeads as effective dosage form for treating colon cancer.

Process optimization and in vivo performance of docetaxel loaded PHBV-TPGS therapeutic vesicles: A synergistic approach.

This research was motivated due to substantial requirement of improved treatment for breast cancer which accounts for over 0.52 million deaths annually worldwide. Utilizing nanoparticles carrying active medicaments as targeted delivery carrier is emerging as a promising approach. For a drug to be clinically effective, it needs to be suitably protected in the biological fluid till it is delivered to the targeted site. Keeping above in mind, we prepared and optimized polymeric nanoparticles by polyhydroxybutyrate-co-hydroxyvalerate (PHBV) a biodegradable polymer utilizing modified emulsification solvent evaporation method. The optimized formulation had particle size of 349±3.51nm with entrapment efficiency of 69±1.28%. Nanoparticle formation and its surface morphology were confirmed by various electron microscopes. The in vitro and pharmacokinetic studies demonstrated a sustained release of drug in a non-biological system and into rat's bloodstream respectively. Also, the in vitro cytotoxicity and in vivo toxicological evaluation at the therapeutic dose demonstrated the safety and antitumor efficacy of the formulation. Due to formulation characteristic properties, it was found to be effective in enveloping and chaperoning the drug to the suitable site of action. The PHBV-TPGS combination causes the drug to be released in controlled and sustained modes, thereby reducing drug dose and toxicity.

Multiparticulate based thermosensitive intra-pocket forming implants for better treatment of bacterial infections in periodontitis.

Considering alarming projections in the prevalence of periodontitis, following study was undertaken to develop chitosan-vanillin crosslinked microspheres loaded in-situ gel (MLIG) implants containing ornidazole and doxycycline hyclate for the treatment of pocket infections. Firstly, microspheres were formulated and optimized using response surface methodology for particle size <50 µm, entrapment efficiency >80%, in-vitro drug release (T80%) >7 days and acceptable mucoadhesion. Further, MLIG were optimized for gelation temperature of 34-37 °C and viscosity <1000 cps respectively. FTIR, DSC and XRD graphs disclosed compatibility and alterations in crystallinity of drugs. In-vitro dissolution study demonstrated non-Fickian type of drug release mechanism for twelve days. Stability studies ascertained MLIG implants were sterilizable and stable for about 11.29 months on refrigeration. The formulations exhibited significant (p < 0.001) antimicrobial activity against Staphylococcus aureus, Escherichia coli, and Enterococcus faecalis, and were found biocompatible and biodegradable during preclinical studies. Ligature-induced periodontal rat model, corroborated significant growth (p < 0.05) of gingival tissue after two weeks. Clinical trials revealed, intra-pocket administration of MLIG along with SRP provided significant reduction in clinical parameters as compared to SRP alone. Conclusively, antimicrobials incorporated thermosensitive, biodegradable, mucoadhesive and syringeable MLIG implants appeared as better option for the treatment of periodontitis.

Development of long-circulating docetaxel loaded poly (3-hydroxybutyrate-co-3-hydroxyvalerate) nanoparticles: Optimization, pharmacokinetic, cytotoxicity and in vivo assessments.

Long-circulating nanoparticles (NPs) are promising drug delivery vehicles which target solid tumors via enhanced permeation and retention effect. Plackett-Burman (PBD) and Box-Behnken (BBD) designs were adopted to study the effects of factors viz. polymer concentration, surfactant concentration, homogenizer speed, homogenization time and ultrasonication time on responses. A graphical and numerical optimization technique was used to obtain predicted value of the response. The drug entrapment efficiency was approximately 39±0.85%. The particle size of the nanoparticles was found to be 260±2.85nm, while the zeta potential was -18±2.12mV, indicating more stable particles. SEM, TEM, and AFM were used for characterization of surface morphology and the physicochemical characters of NPs. A pharmacokinetic evaluation carried out intravenous administration in healthy Charles Foster rats displayed enhanced systemic bioavailability and plasma drug concentration. The in vivo-in silico assessment by GastroPlus™ showed good prediction accuracy and presented best-fit model. Nanoparticles were also studied for stability testing and were found to be stable concerning their drug content and physical characters. In vitro cytotoxicity was assessed using MCF-7 for percentage inhibition of human breast cancer cell line. Anticancer studies of optimized NPs showed a significant increase in efficacy as observed by relative tumor volume up to 30 days.