Aseem Bhatnagar

Development and evaluation of thymoquinone-encapsulated chitosan nanoparticles for nose-to-brain targeting: a pharmacoscintigraphic study

Chitosan (CS) nanoparticles of thymoquinone (TQ) were prepared by the ionic gelation method and are characterized on the basis of surface morphology, in vitro or ex vivo release, dynamic light scattering, and X-ray diffractometry (XRD) studies. Dynamic laser light scattering and transmission electron microscopy confirmed the particle diameter was between 150 to 200 nm. The results showed that the particle size of the formulation was significantly affected by the drug:CS ratio, whereas it was least significantly affected by the tripolyphosphate:CS ratio. The entrapment efficiency and loading capacity of TQ was found to be 63.3% ± 3.5% and 31.23% ± 3.14%, respectively. The drug-entrapment efficiency and drug-loading capacity of the nanoparticles appears to be inversely proportional to the drug:CS ratio. An XRD study proves that TQ dispersed in the nanoparticles changes its form from crystalline to amorphous. This was further confirmed by differential scanning calorimetry thermography. The flat thermogram of the nanoparticle data indicated that TQ formed a molecular dispersion within the nanoparticles. Optimized nanoparticles were evaluated further with the help of scintigraphy imaging, which ascertains the uptake of drug into the brain. Based on maximum concentration, time-to-maximum concentration, area-under-curve over 24 hours, and elimination rate constant, intranasal TQ-loaded nanoparticles (TQ-NP1) proved more effective in brain targeting compared to intravenous and intranasal TQ solution. The high drug-targeting potential and efficiency demonstrates the significant role of the mucoadhesive properties of TQ-NP1.

Nano-salbutamol dry powder inhalation: a new approach for treating broncho-constrictive conditions.

Nanoparticle DPI is known to have deeper lung penetration but its clinical utility as a potentially better treatment option needs to be evaluated in the light of higher expected mucociliary movement of the nanoparticles compared to micronized DPI. The objective of this study was to make nano-salbutamol sulphate (SBS) DPI, radiolabel it with Tc-99m using a novel surface labeling methodology, characterize the formulation and assess its in vitro and in vivo deposition in healthy human volunteers to estimate its bioavailability in the target area. Nano-SBS with a mean particle of 60.71+/-35.99 nm was produced using liquid anti-solvent precipitation method. The drug particles were spherical, pure and crystalline. Anderson cascade impaction showed that blend formulations of Nano-SBS exhibited significantly higher respirable fraction of 45.2% compared to the known behavior of micronized salbutamol sulphate blends. Though the particle size tended to increase due to solid phase interaction after blending with lactose, there was definitive correlation between the radiolabeled and non-radiolabeled forms. In 10 healthy volunteers, lower oropharyngeal depositions (25.3+/-4.5%) were observed with nano-SBS formulation compared to micronized SBS formulation (58.4+/-6.1%). Furthermore, Nano-SBS formulations showed nearly 2.3-fold increase in total lung deposition compared to micronized SBS. The in vivo deposition data and the ratio of peripheral to central lung deposition (P/C) of 1.12+/-0.4 indicate that Nano-SBS is evenly distributed within different lung regions. As demonstrated for SBS, nano-sizing may enhance regional deposition and thus provide an attractive particle engineering option for the development of blend formulations for inhalation delivery.

Preparation, characterization, in vivo biodistribution and pharmacokinetic studies of donepezil-loaded PLGA nanoparticles for brain targeting

Abstract Objective: Alzheimer’s disease (AD) is a progressive neurodegenerative disorder manifested by cognitive, memory deterioration and variety of neuropsychiatric symptoms. Donepezil is a reversible cholinesterase inhibitor used for the treatment of AD. The purpose of this work is to prepare a nanoparticulate drug delivery system of donepezil using poly(lactic-co-glycolic acid) (PLGA) for sustained release and efficient brain targeting. Materials and methods: PLGA nanoparticles (NPs) were prepared by the solvent emulsification diffusion–evaporation technique and characterized for particle size, particle-size distribution, zeta potential, entrapment efficiency, drug loading and interaction studies and in vivo studies using gamma scintigraphy techniques. Results and discussion: The size of drug-loaded NPs (drug polymer ratio 1:1) was found to be 89.67 ± 6.43 nm. The TEM and SEM images of the formulation suggested that particle size was within 20–100 nm and spherical in shape, smooth morphology and coating of Tween-80 on the NPs was clearly observed. The release behavior of donepezil exhibited a biphasic pattern characterized by an initial burst release followed by a slower and continuous sustained release. The biodistribution studies of donepezil-loaded PLGA NPs and drug solution via intravenous route revealed higher percentage of radioactivity per gram in the brain for the nanoparticulate formulation as compared with the drug solution (p < 0.05). Conclusion: The high concentrations of donepezil uptake in brain due to coated NPs may help in a significant improvement for treating AD. But further, more extensive clinical studies are needed to check and confirm the efficacy of the prepared drug delivery system.

Role of Polymeric Biomaterials as Wound Healing Agents

In uncontrolled hemorrhage, the main cause of death on the battlefield and in accidents, half of the deaths are caused by severe blood loss. Polymeric biomaterials have great potential in the control of severe hemorrhage from trauma, which is the second leading cause of death in the civilian community following central nervous system injuries. The intent of this article is to provide a review on currently available biopolymers used as wound dressing agents and to describe their best use as it relates to the condition and type of the wound (acute, chronic, superficial, and full thickness) and the phases of the wound healing process. These biopolymers are beneficial in tissue engineering as scaffolds, hydrogels, and films. Different types of wound dressings based on biopolymers are available in the market, with various physical, chemical, and biological properties. The use of biopolymers as a hemostatic agent depends on its biocompatibility, biodegradability, nonimmunogenicity, and optimal mechanical property. This review summarizes different biopolymers, their physiological characters, and their use as wound healing agents along with biomedical applications.

Donepezil nanosuspension intended for nose to brain targeting: In vitro and in vivo safety evaluation

The present study was to develop donepezil loaded nanosuspension for direct olfactory administration which reaches the brain and determining safety profile in Sprague-Dawley rats. Nanosuspension was prepared by ionic-crosslinking method. The developed nanosuspension was intranasally instilled into the nostrils of rats with the help of cannula (size 18/20) so that drug reached into the brain directly via nose to brain pathway. The nanosuspension had an average size of 150-200nm with a polydispersity index of 0.341. The donepezil concentration was estimated in the brain homogenate using HPLC method. The Cmax showed concentration of donepezil in brain and plasma as 7.2±0.86 and 82.8±5.42ng/ml, respectively, for drug suspension and concentration of donepezil in brain and plasma as 147.54±25.08 and 183.451±13.45ng/ml, respectively, for nanosuspension at same dose of 0.5mg/ml when administered intranasally (p<0.05). The in vivo safety evaluation studies showed that no mortality, hematological changes, body weight variations and toxicity in animals was observed, when nanosuspension was administered in different doses as compared to control group (normal saline). Donepezil loaded chitosan nanosuspension is a potential new delivery system for treatment of Alzheimers disease, when transported via olfactory nasal pathway to the brain.

Development and clinical trial of nano-atropine sulfate dry powder inhaler as a novel organophosphorous poisoning antidote

The aim of the work was to develop, characterize, and carry out a clinical trial with nano-atropine sulfate (nano-AS) dry powder inhaler (DPI), because this route may offer several advantages over the conventional intramuscular route as an emergency treatment, including ease of administration and more rapid bioavailability. Different batches of nanoparticles of AS were produced using variants of nanoprecipitation method. The influence of the process parameters, such as the types and quantity of solvent and nonsolvent, the stirring speed, the solvent-to-nonsolvent volume ratio, and the drug concentration, was investigated. The methodology resulted in optimally sized particles. Bulk properties of the particles made by the chosen methodology were evaluated. A clinical trial was conducted in six healthy individuals using a single DPI capsule containing 6 mg nano-AS DPI in lactose. Early blood bioavailability and atropinization pattern confirmed its value as a potential replacement to parenteral atropine in field conditions. The formulation seems to have the advantage of early therapeutic drug concentration in blood due to absorption through the lungs as well as sustained action due to absorption from the gut of the remaining portion of the drug.

Chitosan nanoparticles amplify the ocular hypotensive effect of cateolol in rabbits.

PURPOSE To assess the potential of chitosan (CS) nanoparticles for ocular drug delivery by investigating their intraocular retention by γ-scintigraphy and intraocular pressure reduction. METHODS Carteolol (CRT) loaded CS-NPs were prepared by ionotropic gelation method. A four-factor three-level Box-Behnken design was employed to investigate the influence of independent variables on particle size, loading capacity and entrapment efficiency. Characterization was done for particle size, encapsulation efficiency, loading capacity and in vitro drug release and transcorneal permeation, histopathology and confocal microscopy, in vitro ocular tolerance. Intraocular retention was assessed by γ-scintigraphy, and intraocular pressure was measured by tonometer betamethasone induced glaucoma rabbits. RESULTS AND DISCUSSION The optimized nanoparticles showed a particle size of 243 nm (PDI - 0.304±0.04) and drug loading 49.21±2.73% with entrapment efficiency of 69.57±3.54%. In vitro release studies showed a sustained release for 24h as compared to drug solution. Ex vivo studies showed good permeation with non-significant changes in cornea anatomy indicating its safe nature. γ-Scintigraphy study showed good spread and retention (<0.05) in precorneal area as compared to the aqueous CRT solution and prolonged reduction in intraocular pressure (P<0.001). CONCLUSION These results indicate that CS nanoparticles are promising vehicles of CRT for ocular drug delivery.

Design, characterization, and evaluation of intranasal delivery of ropinirole-loaded mucoadhesive nanoparticles for brain targeting

Abstract Context: Parkinson disease (PD) is a common, progressive neurodegenerative disorder, characterized by marked depletion of striatal dopamine and degeneration of dopaminergic neurons in the substantia nigra. Objective: The purpose of the present study was to investigate the possibility of targeting an anti-Parkinson’s drug ropinirole (RH) to the brain using polymeric nanoparticles. Materials and methods: Ropinirole hydrochloride (RH)-loaded chitosan nanoparticles (CSNPs) were prepared by an ionic gelation method. The RH-CSNPs were characterized for particle size, polydispersity index (PDI), zeta potential, loading capacity, entrapment efficiency in vitro release study, and in vivo distribution after intranasal administration. Results and discussion: The RH-CSNPs showed sustained release profiles for up to 18 h. The RH concentrations (% Radioactivity/g) in the brain following intranasal administration (i.n.) of RH-CSNPs were found to be significantly higher at all the time points compared with RH solution. The concentration of RH was highest in the liver (7.210 ± 0.52), followed by kidneys (6.862 ± 0.62), intestine (4.862 ± 0.45), and lungs (4.640 ± 0.92) in rats following i.n. administration of RH-CSNPs. Gamma scintigraphy imaging in rats was performed to ascertain the localization of drug in the brain following intranasal administration of formulations. The brain/blood ratios obtained (0.251 ± 0.09 and 0.386 ± 0.57 of RH (i.n.) and RH-CSNPs (i.n.), respectively) at 0.5 h are indicative of direct nose to brain transport, bypassing the blood–brain barrier (BBB). Conclusion: The novel formulation showed the superiority of nose to brain delivery of RH using mucoadhesive nanoparticles compared with other delivery routes reported earlier.

Lipid based nanocarrier system for the potential oral delivery of decitabine: formulation design, characterization, ex vivo, and in vivo assessment.

The aim of this study was to design and fabricate nanostructured lipid carrier (NLC) for the potential oral delivery of decitabine (DCB). NLC was prepared by cold homogenization technique and optimized by the Box-Behnken experimental design. It was further characterized by particle size, zeta potential, transmission electron microscopy (TEM), atomic force microscopy (AFM), differential scanning calorimetry (DSC), X-ray diffraction (XRD), in vitro release study, and stability study. Moreover, ex vivo and in vivo efficacy of the NLC was assessed by gut permeation study, γ scintigraphy imaging, and MTT assay. NLC was found to have particle size (116.64 ± 6.67 nm), zeta potential (-31.8 ± 0.96 mV) and sustained drug release (80.23 ± 4.67%) up to 24h. TEM and AFM proved that the particles were spherical in shape and smooth surface. DSC and XRD studies had demonstrated the reduced crystallinity and stability enhancing effect of the NLC. Stability studies revealed the changes in the observed parameters up to 45 days were not significantly differences (p>0.05). Ex vivo gut permeation study showed 4-folds increment in the permeation of drug compared with the plain drug solution. γ Scintigraphy imaging and MTT assay results inferred that DCB loaded NLC possesses excellent cytotoxic activity against cancer cells. Thus, NLC holds high potential for the oral delivery of DCB to treat cancer cells and future prospects for the industrial purpose.

Scintigraphic diagnosis of protein losing enteropathy using Tc-99m dextran.

The authors performed abdominal scintigraphy using intravenously administered Tc-99m dextran in a patient with protein losing enteropathy. The study revealed abnormal leakage of the radiotracer in the left lumber area that moved over time in a pattern suggestive of small intestinal transit. Besides being a nonprotein and having long stay in intravascular compartment, the macromolecule may have many advantages over Tc-99m human serum albumin, the current radiotracer of choice for imaging intestinal protein loss.