Functionalized nanoparticles to deliver nucleic acids to the brain for the treatment of Alzheimer's disease.

Brain-targeted gene delivery across the blood-brain barrier (BBB) is a significant challenge in the 21st century for the healthcare sector, particularly in developing an effective treatment strategy against Alzheimer's disease (AD). The Internal architecture of the brain capillary endothelium restricts bio-actives entry into the brain. Additionally, therapy with nucleic acids faces challenges like vulnerability to degradation by nucleases and potential immune responses. Functionalized nanocarrier-based gene delivery approaches have resulted in safe and effective platforms. These nanoparticles (NPs) have demonstrated efficacy in protecting nucleic acids from degradation, enhancing transport across the BBB, increasing bioavailability, prolonging circulation time, and regulating gene expression of key proteins involved in AD pathology. We provided a detailed review of several nanocarriers and targeting ligands such as cell-penetrating peptides (CPPs), endogenous proteins, and antibodies. The utilization of functionalized NPs extends beyond a singular system, serving as a versatile platform for customization in related neurodegenerative diseases. Only a few numbers of bioactive regimens can go through the BBB. Thus, exploring functionalized NPs for brain-targeted gene delivery is of utmost necessity. Currently, genes are considered high therapeutic potential molecules for altering any disease-causing gene. Through surface modification, nanoparticulate systems can be tailored to address various diseases by replacing the target-specific molecule on their surface. This review article presents several nanoparticulate delivery systems, such as lipid NPs, polymeric micelles, exosomes, and polymeric NPs, for nucleic acids delivery to the brain and the functionalization strategies explored in AD research.

Non-Invasive Intranasal Delivery of pApoE2: Effect of Multiple Dosing on the ApoE2 Expression in Mice Brain.

Chitosan-based polymeric micelles are promising non-viral nanocarriers for safe and targeted gene delivery. Multi-functionalized chitosan polymeric micelles were prepared by grafting fatty acid, cell-penetrating peptide, and mannose on the chitosan backbone. The polymeric micelles were subjected to surface morphology and surface topography using scanning electron microscopy and atomic force microscopy, respectively. The hemotoxic profile of the prepared polymeric micelles was established against erythrocytes and was found to be <5% hemotoxic up to the concentration of 600 µg/mL. In vitro ApoE2 expression in primary astrocytes and neurons was analyzed. Multi-functionalized polymeric micelles produced greater (p < 0.05) transfection in astrocytes and neurons in comparison to mono-functionalized micelles. Intranasal administration of polymeric micelles/pApoE2 polyplex led to significantly higher (p < 0.05) in vivo pApoE2 expression than chitosan and unfunctionalized polymeric micelles-treated mice groups. The outcomes of this study predict that the developed multi-functionalized polymeric micelles could be an effective and safe gene delivery platform to the brain through the intranasal route.

Multifunctionalized Cationic Chitosan Polymeric Micelles Polyplexed with pVGF for Noninvasive Delivery to the Mouse Brain through the Intranasal Route for Developing Therapeutics for Alzheimer's Disease.

Multifunctionalized Chitosan-based polymeric micelles were used to deliver pVGF to the brain. VGF (non-acronymic) plays significant roles in neurogenesis and learning as well as synaptic and cognitive functions. Therefore, VGF gene therapy could be a better approach in developing effective therapeutics against Alzheimer's disease. Multifunctionalized chitosan polymeric micelles were developed by grafting oleic acid (OA) on the chitosan (CS) skeleton followed by penetratin (PEN) and mannose (MAN) conjugation. The OA-g-CS-PEN-MAN graft polymer formed cationic nanomicelles in an aqueous medium and polyplexed with pVGF. The polymeric micelles were nontoxic and cationic in charge and had an average hydrodynamic diameter of 199.8 ± 15.73 nm. Qualitative in vitro transfection efficiency of OA-g-CS-PEN-MAN/pGFP polyplex was investigated in bEnd.3, primary neurons, and astrocyte cells. In vivo transfection efficiency of OA-g-CS-PEN-MAN/pVGF polyplexes was analyzed in C57BL6/J mice after intranasal administration for 7 days. The VGF expression levels in primary astrocytes and neurons after OA-g-CS-PEN-MAN/pVGF treatment were 2.4 ± 0.24 and 1.49 ± 0.02 pg/µg of protein, respectively. The VGF expression in the OA-g-CS-PEN-MAN/pVGF polyplex-treated animal group was 64.9 ± 12.7 pg/mg of protein, significantly higher (p < 0.01) than that of the unmodified polymeric micelles. The in vivo transfection outcomes revealed that the developed multifunctionalized OA-g-CS-PEN-MAN polymeric micelles could effectively deliver pVGF to the brain, transfect brain cells, and express VGF in the brain after noninvasive intranasal administration.

Experimental Models of In Vitro Blood-Brain Barrier for CNS Drug Delivery: An Evolutionary Perspective.

Central nervous system (CNS) disorders represent one of the leading causes of global health burden. Nonetheless, new therapies approved against these disorders are among the lowest compared to their counterparts. The absence of reliable and efficient in vitro blood-brain barrier (BBB) models resembling in vivo barrier properties stands out as a significant roadblock in developing successful therapy for CNS disorders. Therefore, advancement in the creation of robust and sensitive in vitro BBB models for drug screening might allow us to expedite neurological drug development. This review discusses the major in vitro BBB models developed as of now for exploring the barrier properties of the cerebral vasculature. Our main focus is describing existing in vitro models, including the 2D transwell models covering both single-layer and co-culture models, 3D organoid models, and microfluidic models with their construction, permeability measurement, applications, and limitations. Although microfluidic models are better at recapitulating the in vivo properties of BBB than other models, significant gaps still exist for their use in predicting the performance of neurotherapeutics. However, this comprehensive account of in vitro BBB models can be useful for researchers to create improved models in the future.

Synthesis and Characterization of Fatty Acid Grafted Chitosan Polymeric Micelles for Improved Gene Delivery of VGF to the Brain through Intranasal Route.

Multifunctional fatty acid grafted polymeric micelles are an effective and promising approach for drug and gene delivery to the brain. An alternative approach to bypass the blood-brain barrier is administration through intranasal route. Multifunctional fatty acid grafted polymeric micelles were prepared and characterized for pVGF delivery to the brain. In vitro pVGF expression was analyzed in bEnd.3 cells, primary astrocytes, and neurons. Comparative in-vivo pVGF expression was analyzed to evaluate the effective route of administration between intranasal and intravenous. Biocompatible, multifunctional polymeric micelles were prepared, having an average size of 200 nm, and cationic zeta potential. Modified polymers were found to be hemo- and cyto-compatible. When transfected with the different modified chitosan formulations, significantly (p < 0.05) higher VGF expression was observed in primary astrocytes and neurons using the mannose, Tat peptide, and oleic acid grafted chitosan polymer. Compared to intravenous administration, intranasal administration of pVGF in polyplex formulation led to significantly (p < 0.05) higher pVGF expression. Developed multifunctional polymeric micelles were an effective pVGF delivery platform to the brain. Mannose and Tat ligand tagging improved the pVGF delivery to the brain.

A Review of the Common Neurodegenerative Disorders: Current Therapeutic Approaches and the Potential Role of Nanotherapeutics.

Neurodegenerative disorders are primarily characterized by neuron loss. The most common neurodegenerative disorders include Alzheimer's and Parkinson's disease. Although there are several medicines currently approved for managing neurodegenerative disorders, a large majority of them only help with associated symptoms. This lack of pathogenesis-targeting therapies is primarily due to the restrictive effects of the blood-brain barrier (BBB), which keeps close to 99% of all "foreign substances" out of the brain. Since their discovery, nanoparticles have been successfully used for targeted delivery into many organs, including the brain. This review briefly describes the pathophysiology of Alzheimer's, Parkinson's disease, and amyotrophic lateral sclerosis, and their current management approaches. We then highlight the major challenges of brain-drug delivery, followed by the role of nanotherapeutics for the diagnosis and treatment of various neurological disorders.

PEGylated Dendrimer Mediated Delivery of Bortezomib: Drug Conjugation versus Encapsulation.

Poor aqueous solubility of anticancer drug bortezomib (BTZ) still remains a major challenge in the development of a successful formulation. The dendrimeric platform can provide a better opportunity to deliver BTZ with improved solubility. BTZ encapsulated in PEGylated PAMAM dendrimers (BTZ-PEG-PAMAM) was characterized and evaluated comparatively with encapsulated and conjugated dendritic formulations. The particle size of BTZ-PEG-PAMAM was 188.6 ± 4.17 nm, with entrapment efficiency of 78.61 ± 2.91% and drug loading of 39.30 ± 1.98%. The aqueous solubility of BTZ in PAMAM-PEG conjugate was enhanced by 68.11 folds in comparison to pure drug. In vitro drug release profile was found to be sustained up to 72 h. A comparative colorimetric MTT assay against A549 and MCF-7 cancer cells resulted in maximum efficacy from BTZ-PEG-PAMAM with IC50 value 333.14 ± 15.42 and 152.60 ± 24.56 nM, respectively. Significantly higher cellular internalization was observed in FITC tagged BTZ-PEG-PAMAM. In vivo pharmacokinetic study performed on Sprague Dawley rats resulted in 8.63 folds increase in bioavailability for BTZ-PEG-PAMAM than pure drug. Pharmacokinetic parameters of BTZ-PEG-PAMAM were better and improved over BTZ and other dendritic formulations. In conclusion, the prepared formulation of BTZ-PEG-PAMAM has given significant outcome and this strategy may be further explored for better delivery of BTZ in future.

Lactoferrin Coupled Lower Generation PAMAM Dendrimers for Brain Targeted Delivery of Memantine in Aluminum-Chloride-Induced Alzheimer's Disease in Mice.

Lower generation PAMAM dendrimers have an immense potential for drug delivery with lower toxicity, but these dendrimers yet need certain basic ameliorations. In this study, the brain delivery potential of the synthesized PAMAM-Lf (lower generation PAMAM and lactoferrin conjugate) loaded with memantine (MEM) was explored and evaluated in vitro and in vivo in the disease-induced mouse model. The developed nanoscaffolds were characterized for size, zeta potential and in vitro release. Increase in the average size from 11.54 ± 0.91 to 131.72 ± 4.73 nm, respectively, was observed for drug-loaded PAMAM (i.e., PAMAM-MEM) and PAMAM-Lf (i.e., MEM-PAMAM-Lf).  Release profile of MEM from MEM-PAMAM-Lf was slow and sustained up to 48 h. In vivo biodistribution in the Sprague-Dawley rat model revealed that the brain uptake of MEM-PAMAM-Lf was significantly higher than that of MEM alone. The behavioral response study in the healthy rats did not result in any significant changes. The in vivo study in an AlCl3-induced Alzheimer's (AD) mice model showed a significant improvement in behavioral responses. Optical density, which reflects the acetylcholinesterase (AChE) activity, was highest in the AL group 0.16 ± 0.01 (higher than the CON group, 0.09 ± 0.02; p < 0.05). No significant suppression of AChE activity was recorded in all the other treated groups. Similarly, the DOPAmine and 3,4 dihydroxyphenylacetic acid (DOPAC) levels were unaffected by the developed formulations. The study reported improved brain bioavailability of MEM in AlCl3-induced Alzheimer's mice leading to improved memory, with the resultant mechanism behind in a descriptive manner. This study is among the preliminary studies reporting the memory improvement aspect of PAMAM-Lf conjugates for MEM in AlCl3-AD induced mice. The formulation developed was beneficial in AD-induced mice and had a significant impact on the memory aspects.

Behavioral and Biochemical Implications of Dendrimeric Rivastigmine in Memory-Deficit and Alzheimer's Induced Rodents.

Exploration of dendrimers for effective drug delivery is giving promising results. The present study was designed and performed to explore the dendrimeric (polyamidoamine-lactoferrin; PAMAM-Lf) formulations for the effective rivastigmine (RIV) delivery against the Alzheimer's induced animal model using lactoferrin as the targeting ligand. RIV delivery through PAMAM-Lf conjugates was highly efficient in the Alzheimer's induced animal model. PAMAM-Lf conjugates also efficiently improved behavioral responses against the chemical memory deficit animal model as well as the Alzheimer's induced animal model, separately. Behavioral responses revealed that motor and spatial memories were significantly improved (p < 0.005) over those from RIV alone. The latency time of PAMAM-Lf-RIV was 1.3 times higher over that of the pure RIV in the rotarod protocol, while it was 2.1-fold reduced in the Morris water maze test. The study also attempted to explore the mechanistic aspect of improved efficacy through biochemical evaluation (AChE histo-enzymology), which reveals that levels of dopamine and its metabolite 3,4-dihydroxyphenylacetic acid were unaffected, but AChE activity was improved for all forms of RIV. Conclusively, PAMAM-Lf conjugates were able to deliver RIV effectively against the Alzheimer's induced animal model. This was further strengthened with the positive results obtained with the behavioral studies of memory-deficit animals and disease-induced animals. The study is among the first studies which report RIV delivery against the Alzheimer's induced animal model using PAMAM dendrimers.

HPMA-PLGA Based Nanoparticles for Effective In Vitro Delivery of Rifampicin.

PURPOSE: Tuberculosis (TB) chemotherapy witnesses some major challenges such as poor water-solubility and bioavailability of drugs that frequently delay the treatment. In the present study, an attempt to enhance the aqueous solubility of rifampicin (RMP) was made via co-polymeric nanoparticles approach. HPMA (N-2-hydroxypropylmethacrylamide)-PLGA based polymeric nanoparticulate system were prepared and evaluated against Mycobacterium tuberculosis (MTB) for sustained release and bioavailability of RMP to achieve better delivery. METHODOLOGY: HPMA-PLGA nanoparticles (HP-NPs) were prepared by modified nanoprecipitation technique, RMP was loaded in the prepared NPs. Characterization for particle size, zeta potential, and drug-loading capacity was performed. Release was studied using membrane dialysis method. RESULTS: The average particles size, zeta potential, polydispersity index of RMP loaded HPMA-PLGA-NPs (HPR-NPs) were 260.3 ± 2.21 nm, -6.63 ± 1.28 mV, and 0.303 ± 0.22, respectively. TEM images showed spherical shaped NPs with uniform distribution without any cluster formation. Entrapment efficiency and drug loading efficiency of HPR-NPs were found to be 76.25 ± 1.28%, and 26.19 ± 2.24%, respectively. Kinetic models of drug release including Higuchi and Korsmeyer-peppas demonstrated sustained release pattern. Interaction studies with human RBCs confirmed that RMP loaded HP-NPs are less toxic in this model than pure RMP with (p < 0.05). CONCLUSIONS: The pathogen inhibition studies revealed that developed HPR-NPs were approximately four times more effective with (p < 0.05) than pure drug against sensitive Mycobacterium tuberculosis (MTB) stain. It may be concluded that HPR-NPs holds promising potential for increasing solubility and bioavailability of RMP.

Correction to: Radiolabeled PLGA Nanoparticles for Effective Targeting of Bendamustine in Tumor Bearing Mice.

The typesetter did not use the Fig. 6 provided by the author with his proof corrections, and instead duplicated Fig. 7 by the Fig. 6 caption. The original article has been corrected.

Radiolabeled PLGA Nanoparticles for Effective Targeting of Bendamustine in Tumor Bearing Mice.

PURPOSE: Bendamustine is an important drug for the treatment of chronic lymphatic leukaemia (CLL), non-Hodgkin lymphoma (NHL). However, its delivery is challenging due to its instability. Current approach reports the development and characterization of bendamustine encapsulated PLGA nanoparticles for the effective targeting to leukemic cells. METHODS: The prepared, bendamustine loaded PLGA nanoparticles (BLPNP) were developed and characterized for particle size, zeta potential and polydispersity index. The formed nanoparticles were further characterized with the help of electron microscopy for surface morphology. The formed nanoparticles were evaluated for cytotoxicity, cell uptake, ROS and cell apoptosis against THP-1 leukemic cells as a part of in vitro evaluation. In vivo organ bio-distribution and tumor regression studies were performed to track in vivo behaviour of BLPNP. RESULTS: The average particle size was 138.52 ± 3.25 nm, with 0.192 ± 0.036 PDI and - 25.4 ± 1.38 mV zeta potential. TEM images revealed the homogeneous particle size distribution with uniform shape. In vitro release exhibited a sustained drug-release behaviour up to 24 h. Cytotoxicity against THP-1 cells through MTT assay observed IC50 value of 27.8 ± 2.1 µM for BLPNP compared to pure drug, which was 50.42 ± 3.4 µM. Moreover, in vitro studies like cell-uptake and cell apoptosis studies further confirmed the higher accumulation of BLPNP in comparison to the pure drug. Organ distribution and tumor regression studies were performed to track in vivo behaviour of bendamustine loaded nanoparticles. CONCLUSION: The overall study described a promising approach in terms of safety, least erythrocytic toxicity, better IC50 value with enhance tumor targeting and regression.

Smartly Engineered PEGylated Di-Block Nanopolymeric Micelles: Duo Delivery of Isoniazid and Rifampicin Against Mycobacterium tuberculosis.

In an attempt to deliver multiple drugs through a nanoparticulate platform, the present study was designed to deliver isoniazid (INH) and rifampicin (RMP) together through conjugation/encapsulation approaches using PEG-PLA (polyethylene glycol-poly-L-lactic acid) polymeric micelles. The objective of this study is to identify the preparation and evaluation of PEGylated polymeric micelles with dual drug delivery of INH and RMP for the effective treatment of tuberculosis (TB). Synthesized PEG-PLA di-block-copolymer was further conjugated to INH-forming PEG-PLA-INH (PPI) conjugate. Separately, these conjugates were loaded with RMP building the rifampicin-loaded PEG-PLA-INH polymeric micelles (PMC). The critical micelle concentration (CMC) for the PEG-PLA copolymer was found to be 8.9 ± 0.96 mg/L, and the size and zeta potential were observed to be 187.9 ± 2.68 nm and - 8.15 ± 1.24 mV (0.251 ± 0.042 pdi), respectively. Percent drug loading of PMC was 16.66 ± 1.52 and 23.07 ± 1.05 with entrapment efficiency of 72.30 ± 3.49 and 78.60 ± 2.67% for RMP and INH, respectively. RBC hemolysis capacity of PMC was significantly less than pure RMP and INH. Microplate Alamar blue assay (MABA) along with microscopy showed that the nanoconstructed PMC were more effective than the drugs, and approximately 8-fold reduction in overall minimum inhibitory concentration (MIC) was observed. The prepared duo drug-loaded nano-engineered polymeric micelles were highly effective against sensitive Mycobacterium tuberculosis strains and found to be less hemolytic in nature. The micelles could be further explored (in the future) for in vivo anti-TB studies to establish further to achieve better treatment for TB.

Boosted Memory and Improved Brain Bioavailability of Rivastigmine: Targeting Effort to the Brain Using Covalently Tethered Lower Generation PAMAM Dendrimers with Lactoferrin.

Currently, there is no treatment strategy which can reverse the process of neuro-degeneration in progression of Alzheimer's disease (AD). Practically, it is desired to achieve and maintain high therapeutic doses in the brain, but it is hard due to selective permeability of the blood-brain barrier (BBB). In the present study, lactoferrin (Lf) was conjugated to polyamidoamine generation 3.0 (PAMAM G3.0) dendrimers for the effective delivery of rivastigmine (RIV) to the brain. Conjugation of PAMAM G3.0 with lactoferrin was confirmed by FT-IR, 1H NMR, and 2D-NMR spectroscopy as well as AFM techniques. Further, RIV was loaded into PAMAM G3.0 and PAMAM-Lf conjugates. RP-HPLC was used to quantify the drug loading and release as well. Spectroscopic analysis confirmed PAMAM-Lf conjugation, the size of the conjugate was 100.04 ± 3.1 nm, and after RIV loading, the size was increased up to 216.13 ± 2.3 nm. Atomic force microscopic results revealed that the root-mean-square roughness ( Rq) and surface roughness ( Ra) were 6.31 and 5.27 nm, respectively, along with other parameters, Skewness and Kurtosis, which were 0.522 and 2.50, respectively. In vitro drug release from the PAMAM-Lf-RIV conjugate was sustained up to more than 100 h, and that of naive RIV was quite rapid (approxmately 99% release was observed in 8 h). Ex vivo hemotoxicity of the PAMAM-Lf-RIV conjugate was almost 9.8-fold lesser than the PAMAM G3.0 ( p < 0.0001), 7.77 times that of PAMAM-enc-RIV and 5 times that of naïve RIV ( p < 0.0001), respectively. The in vivo targeting potency of the conjugate was investigated in a rat model. Bioavailability of the RIV was enhanced 7.87 times compared to RIV along with improved pharmacokinetic parameters. Brain uptake of the drug was improved when treated with PAMAM-Lf-RIV over the RIV and PAMAM-enc-RIV, almost 8 and 4.2 times, respectively, after 4 h of the administration. Additionally, the behavioral studies revealed that PAMAM-Lf-RIV significantly enhanced the overall locomotor activity with higher ambulations over the pure drug and PAMAM-enc-RIV formulation. The outcome of the novel object recognition test was an indirect evidence of memory improvement. Conclusively, the development and characterization of PAMAM-Lf-RIV resulted in improved brain uptake and brain bioavailability with boosted memory, which can be beneficial in the treatment of Alzheimer's.

Bendamustine-PAMAM Conjugates for Improved Apoptosis, Efficacy, and in Vivo Pharmacokinetics: A Sustainable Delivery Tactic.

Successful delivery of a chemotherapeutic agent like bendamustine still remains a challenge in clinical conditions like chronic lymphatic leukemia (CLL), non-Hodgkin lymphoma (NHL), and multiple myeloma. We have conjugated bendamustine to polyamidoamine (PAMAM) dendrimers after conjugating with N-(hydroxyethyl)maleimide (spacer) via an ester bond. The particle size of PAMAM-bendamustine conjugate was 49.8 ± 2.5 nm. In vitro drug release resulted in sustained release with improved solution stability of drug up to 72 h. In a 24 h cytotoxicity study by MTT assay against human monoblastic leukemia cells (THP-1), the IC50 value for PAMAM-bendamustine was 32.1 ± 4.8 µM compared to 50.42 ± 3.4 µM and 2303 ± 106.5 µM for bendamustine and PAMAM dendrimer, respectively. Significantly higher cell uptake and apoptosis were observed in THP-1 cells by PAMAM-bendamustine conjugate which was confirmed by flow cytometry and confocal laser scanning microscopy. Preliminary in vivo studies undertaken included pharmacokinetics studies, organ distribution studies, and tumor inhibition studies. In healthy Wistar rat model (1CBM IV push model), the pharmacokinetic studies revealed that bioavailability and t1/2 increased significantly, i.e., almost 8.5-fold (193.8 ± 1.116 vs 22.8 ± 0.158 µg mL-1/h) and 5.1-fold (0.75 ± 0.005 vs 3.85 ± 0.015 h), respectively, for PAMAM-bendamustine conjugate compared to pure bendamustine ( p < 0.05), however, clearance and volume of distribution were found to be decreased compared to those of free drug. The study suggests that PAMAM-bendamustine conjugate was not only stable for the longer period but also least toxic and highly taken up by THP-1 cells to exert an anticancer effect at the reduced dose. Tumor inhibition and biodistribution studies in tumor-bearing BALB/c mice revealed that PAMAM-bendamustine conjugate was more effective than the pure drug and showed higher accumulation in the tumor.

Dendrimer nanohybrid carrier systems: an expanding horizon for targeted drug and gene delivery.

Highly controllable dendritic structural design means dendrimers are a leading carrier in drug delivery applications. Dendrimer- and other nanocarrier-based hybrid systems are an emerging platform in the field of drug delivery. This review is a compilation of increasing reports of dendrimer interactions, such as dendrimer-liposome, dendrimer-carbon-nanotube, among others, known as hybrid carriers. This should prompt entirely new research with promising results for these hybrid carriers. It is assumed that such emerging hybrid nanosystems - from combining two already-established drug delivery platforms - could lead the way for the development of newer delivery systems with multiple applicability for latent theranostic applications in the future.

Polymeric Nanocarriers: A New Horizon for the Effective Management of Breast Cancer.

BACKGROUND: Delivery of chemotherapeutic drugs for the diagnosis and treatment of cancer is becoming advanced day by day. However, the challenge of the effective delivery system still does exist. In various types of cancers, breast cancer is the most commonly diagnosed cancer among women. Breast cancer is a combination of different diseases. It cannot be considered as only one entity because there are many specific patient factors, which are involved in the development of this disease. Nanotechnology has opened a new area in the effective treatment of breast cancer due to the several benefits offered by this technology. METHODS: Polymeric nanocarriers are among one of the effective delivery systems, which has given promising results in the treatment of breast cancers. Nanocarriers does exert their anticancer effect either through active or passive targeting mode. RESULTS: The use of nanocarriers has been resolute about the adverse effects of chemotherapeutic drugs such as poor solubility and less penetrability in tumor cells. CONCLUSION: The present review is focused on recent developments regarding polymeric nanocarriers, such as polymeric micelles, polymeric nanoparticles, dendrimers, liposomes, nanoshells, fullerenes, carbon nanotubes (CNT) and quantum dots, etc. for their recent advancements in breast cancer therapy.

Galactose-Anchored Gelatin Nanoparticles for Primaquine Delivery and Improved Pharmacokinetics: A Biodegradable and Safe Approach for Effective Antiplasmodial Activity against P. falciparum 3D7 and in Vivo Hepatocyte Targeting.

Primaquine phosphate (PQ) is mainly used as a radical cure therapy to eradicate relapse of malaria at the liver stage, which is particularly caused by P. falciparum and P. vivax. In the present study, PQ-loaded galactosylated gelatin nanoparticles (Gel-LA-PQ-NPs) were formulated using a one-step desolvation technique. The mean particle size of Gel-LA-PQ-NPs was found to be 93.48 ± 6.36 nm with a zeta potential of 4.80 ± 0.20 mV having 69.90 ± 1.53% encapsulation efficiency. Electron microscopy demonstrated that the NPs were spherical in shape and uniformly distributed without any cluster formation. The in vitro release of PQ from Gel-LA-PQ-NPs has been facilitated in sustained manner, and the release was three times slower than the naïve drug. The prepared nanoparticles (Gel-LA-PQ-NPs) were significantly (p < 0.0001) less hemolytic than the pure drug PQ. The hematological ex vivo study further supported that the developed Gel-LA-PQ-NPs were safer than PQ. The in vitro antiplasmodium assay revealed that the IC50 value against the blood stage of asexual P. falciparum 3D7 strains was significantly (p < 0.01) less (2.862 ± 0.103 µM) for Gel-LA-PQ-NPs than naïve PQ (3.879 ± 0.655 µM). In vivo pharmacokinetic parameters of Gel-LA-PQ-NPs such as half-life and AUC were significantly higher for Gel-LA-PQ-NPs, i.e., with higher bioavailability. Galactosylation of the NPs led to liver targeting of the PQ in animal studies. Approximately eight-fold higher accumulation of PQ was observed in liver compared to pure drug (i.e., PQ). Conclusively, the prepared galactosylated gelatin nanocarrier holds the promising potential and hepatic targetability of an antimalarial, maintaining its safety and biocompatibility.

Conjugated and Entrapped HPMA-PLA Nano-Polymeric Micelles Based Dual Delivery of First Line Anti TB Drugs: Improved and Safe Drug Delivery against Sensitive and Resistant Mycobacterium Tuberculosis.

PURPOSE: First line antiTB drugs have several physical and toxic manifestations which limit their applications. RIF is a hydrophobic drug and has low water solubility and INH is hepatotoxic. The main objective of the study was to synthesize, characterize HPMA-PLA co-polymeric micelles for the effective dual delivery of INH and RIF. METHODS: HPMA-PLA co-polymer and HPMA-PLA-INH (HPI) conjugates were synthesized and characterized by FT-IR and 1H-NMR spectroscopy. Later on RIF loaded HPMA-PLA-INH co-polymeric micelles (PMRI) were formulated and characterized for size, zeta potential and surface morphology (SEM, TEM) as well as critical micellar concentration. The safety was assessed through RBC's interaction study. The prepared PMRI were evaluated through MABA assay against sensitive and resistant strains of M. Tuberculosis. RESULTS: Size, zeta and entrapment efficiency for RIF loaded HPMA-PLA-INH polymeric micelles (PMRI) was 87.64 ± 1.98 nm, -19 ± 1.93 mV and 97.2 ± 1.56%, respectively. In vitro release followed controlled and sustained delivery pattern. Sustained release was also supported by release kinetics. Haemolytic toxicity of HPI and PMRI was 8.57 and 7.05% (p < 0.01, INH Vs PMRI; p < 0.0001, RIF Vs PMRI), respectively. MABA assay (cytotoxicity) based MIC values of PMRI formulation was observed as ≥0.0625 and ≥0.50 µg/mL (for sensitive and resistant strain). The microscopic analysis further confirmed that the delivery approach was effective than pure drugs. CONCLUSIONS: RIF loaded and INH conjugated HPMA-PLA polymeric micelles (PMRI) were more effective against sensitive and resistant M tuberculosis. The developed approach can lead to improved patient compliance and reduced dosing in future, offering improved treatment of tuberculosis.

Intranasal Drug Delivery: A Non-Invasive Approach for the Better Delivery of Neurotherapeutics.

BACKGROUND: The convoluted pathophysiology of brain disorders along with penetration issue of drugs to brain represents major hurdle that requires some novel therapies. The blood-brain barrier (BBB) denotes a rigid barrier for delivery of therapeutics in vivo; to overcome this barrier, intranasal delivery is an excellent strategy to deliver the drug directly to brain via olfactory and trigeminal nerve pathways that originate as olfactory neuro-epithelium in the nasal cavity and terminate in brain. METHOD: Kind of therapeutics like low molecular weight drugs can be delivered to the CNS via this route. In this review, we have outlined the anatomy and physiological aspect of nasal mucosa, certain hurdles, various strategies including importance of muco-adhesive polymers to increase the drug delivery and possible clinical prospects that partly contribute in intranasal drug delivery. RESULTS: Exhaustive literature survey related to intranasal drug delivery system revealed the new strategy that circumvents the BBB, based on non-invasive concept for treating various CNS disorders. Numerous advantages like prompt effects, self-medication through wide-ranging devices, and the frequent as well protracted dosing are associated with this novel route. CONCLUSION: Recently few reports have proven that nasal to brain drug delivery system bypasses the BBB. This novel route is associated with targeting efficiency and less exposure of therapeutic substances to non-target site. Nevertheless, this route desires much more research into the safe transferring of therapeutics to the brain. Role of muco-adhesive polymer and surface modification with specific ligands are area of interest of researcher to explore more about this.