Nanovehicles For Drug Delivery Research Articles

Effect of the DnaK chaperone on the conformational quality of JCV VP1 virus‐like particles produced in Escherichia coli

Protein nanoparticles such as virus-like particles (VLPs) can be obtained by recombinant protein production of viral capsid proteins and spontaneous self-assembling in cell factories. Contrarily to infective viral particles, VLPs lack infective viral genome while retaining important viral properties like cellular tropism and intracellular delivery of internalized molecules. These properties make VLPs promising and fully biocompatible nanovehicles for drug delivery. VLPs of human JC virus (hJCV) VP1 capsid protein produced in Escherichia coli elicit variable hemagglutination properties when incubated at different NaCl concentrations and pH conditions, being optimal at 200 mM NaCl and at pH range between 5.8 and 7.5. In addition, the presence or absence of chaperone DnaK in E. coli cells influence the solubility of recombinant VP1 and the conformational quality of this protein in the VLPs. The hemagglutination ability of hJCV VP1 VLPs contained in E. coli cell extracts can be modulated by buffer composition in the hemagglutination assay. It has been also determined that the production of recombinant hJCV VP1 in E. coli is favored by the absence of chaperone DnaK as observed by Western Blot analysis in different E. coli genetic backgrounds, indicating a proteolysis targeting role for DnaK. However, solubility is highly compromised in a DnaK(-) E. coli strain suggesting an important role of this chaperone in reduction of protein aggregates. Finally, hemagglutination efficiency of recombinant VP1 is directly related to the presence of DnaK in the producing cells.

Noncovalent interaction-assisted polymeric micelles for controlled drug delivery.

Polymeric micelles are one of the most promising nanovehicles for drug delivery. In addition to amphiphilicity, various individual or synergistic noncovalent interplays including strong hydrophobic, electrostatic, host-guest, hydrogen bonding, stereocomplex and coordination interactions have been recently employed to improve the physical stability of micelles, and even provide them with certain intelligences or bioactivities. Through the ingenious designs and precise preparations, many noncovalent-mediated micelles display great prospects in the realm of controlled drug delivery, and certain species have been promoted to clinical trials. The current review presents the diverse noncovalent interactions that are applied to enhance polymeric micelles as drug nanocarriers, and preliminarily discusses the future directions and perspectives of this field.

Facile Solvothermal Synthesis of Mesostructured Fe3O4/Chitosan Nanoparticles as Delivery Vehicles for pH‐Responsive Drug Delivery and Magnetic Resonance Imaging Contrast Agents

We report a facile fabrication of a host-metal-guest coordination-bonding system in a mesostructured Fe3O4/chitosan nanoparticle that can act as a pH-responsive drug-delivery system. The mesostructured Fe3O4/chitosan was synthesized by a solvothermal approach with iron(III) chloride hexahydrate as a precursor, ethylene glycol as a reducing agent, ammonium acetate as a porogen, and chitosan as a surface-modification agent. Subsequently, doxorubicin (DOX), acting as a model drug (guest), was loaded onto the mesostructured Fe3O4/chitosan nanoparticles, with chitosan acting as a host molecule to form the NH2-Zn(II)-DOX coordination architecture. The release of DOX can be achieved through the cleavage of coordination bonds that are sensitive to variations in external pH under weakly acidic conditions. The pH-responsive nature of the nanoparticles was confirmed by in vitro releases and cell assay tests. Furthermore, the relaxation efficiency of the nanoparticles as high-performance magnetic resonance imaging contrast agents was also investigated. Experimental results confirm that the synthesized mesostructured Fe3O4/chitosan is a smart nanovehicle for drug delivery owing to both its pH-responsive nature and relaxation efficiency.

Applications of Mesoporous Materials as Excipients for Innovative Drug Delivery and Formulation

Due to uniquely ordered nanoporous structure and high surface area as well as large pore volume, mesoporous materials have exhibited excellent performance in both controlled drug delivery with sustained release profiles and formulation of poorly aqueoussoluble drugs with enhanced bioavailability. Compared with other bulk excipients, mesoporous materials could achieve a higher loading of active ingredients and a tunable drug release profile, as the high surface density of surface hydroxyl groups offered versatility to be functionalized. With drug molecules stored in nano sized channels, the pore openings could be modified using functional polymers or nano-valves performing as stimuli-responsive release devices and the drug release could be triggered by environmental changes or other external effects. In particular, mesoporous silica nanoparticles (MSN) have attracted much attention for application in functional target drug delivery to the cancer cell. The smart nano-vehicles for drug delivery have showed obvious improvements in the therapeutic efficacy for tumor suppression as compared with conventional sustained release systems, although further progress is still needed for eventual clinical applications. Alternatively, unmodified mesoporous silica also exhibited feasible application for direct formulation of poorly water-soluble drugs to enhance dissolution rate, solubility and thus increase the bioavailability after administration. In summary, mesoporous materials offer great versatility that can be used both for on-demand oral and local drug delivery, and scientists are making great efforts to design and fabricate innovative drug delivery systems based on mesoporous drug carriers.

Graphene-Based Biosensors for Nano and Pico Applications: The Future is here!

Nanotechnology and smaller scale technologies represent golden eggs for medicine and sciences [1,2]. In the recent years, graphene (G)-based biosensors, including functional graphene oxide (GO) and G hybrid nanocomposites, are increasingly explored for real-time imaging and quantification of biomolecules or cells [3]. The remarkable intrinsic and tunable properties of G and derivatives (e.g. planar structure, high surface-volume ratio, high electrical conductivity, good chemical stability and strong mechanical strength) are quite attracting to manufacture reliable, highly sensitive and ultra-fast biosensing platforms (e.g. label-free or fluorochrome-based nano-optical/ biophotonic detection systems such as FRET or CRET) [3]. A number of emerging studies have reported a combination of functional, green, cost-effective and scalable approaches to constantly improve the overall properties (e.g. sensitivity, specificity/selectivity, stability, rapidity, reproducibility) of the G component for real-time and multiplexed imaging of biomolecules (e.g. biomarkers of disease, nucleic acid alterations) or cells (e.g. cancer cells, stem cells, bacteria or viruses) [3]. G and derivatives-based biosensors, which besides can be used as nano-vehicles for drug delivery [2], are revolutionizing the disease prognosis, diagnosis and therapy [3]. The possibility to detect and characterize a single cell or very lowly expressed biomolecules makes G-derived biosensors among the most promising tools for efficient translational, integrative, regenerative and personalized medicine

Magnetic Anisotropy Effects on the Behavior of a Carbon Nanotube Functionalized by Magnetic Nanoparticles Under External Magnetic Fields

The behavior of a multiwalled carbon nanotube functionalized by magnetic nanoparticles through triethylene glycol chains is studied using molecular dynamics simulations. Particular attention is paid to the effect of magnetic anisotropy of nanoparticles which significantly affects the behavior of the system under an external magnetic field. The magnetization reversal process is coupled with the standard atomistic molecular dynamics equations of motion by utilizing the Neel–Brown model and the overdamped Langevin dynamics for description of the inertless magnetization displacements. The key results obtained in this study concern: an energetic profile of the system accompanying transition of a magnetic nanoparticle from the vicinity of the nanotube tip to its sidewall, that is from the capped configuration to the uncapped one; range of the magnetic anisotropy constant in which the system performs structural rearrangements under the external magnetic fields; range of the magnetic field strengths necessary for triggering the structural rearrangements; and other effects like magnetic heating observed during the interaction of the system with the magnetic field. The determined properties of the studied system strongly suggest its application in the area of nanomedicine as a drug targeting and delivery nanovehicle.

Halloysite Nanotubes, a Multifunctional Nanovehicle for Anticancer Drug Delivery

AbstractTargeted drug delivery systems have attracted a great deal of interest by virtue of their potential use in chemotherapy. In this study, multicomponent halloysite nanotubes (HNTs) have been evaluated as a platform to assist and direct the delivery of anticancer drug doxorubicin (DOX) into cancer cells. Folic acid (FA) and magnetite nanoparticles were successfully grafted onto HNTs via amide reaction whereas the drug has been introduced by capitalizing electrostatic interaction between cationic drug and anionic exterior of HNTs, which eventually leads to pH responsive release. The resultant DOX loaded FA‐Fe3O4@HNTs were well characterized by transmission electron microscopy (TEM), scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FTIR) and XRD. The clinical efficacy of the system was validated by confocal microscopy and cell cytotoxicity assay (MTT assay). MTT assay results revealed a high biocompatibility up to a concentration of 200 µg/mL of HNTs, while, DOX loaded FA‐Fe3O4@HNTs were markedly cytotoxic to HeLa cells. This multifunctional nanovehicle has a great potential for cancer diagnosis and therapy, and could further advance the clinical use of nanomedicine.

Supramolecular Core–Shell Nanosilica@Liposome Nanocapsules for Drug Delivery

The fabrication of core-shell structural nanosilica@liposome nanocapsules as a drug delivery vehicle is reported. SiO(2) nanoparticles are encapsulated within liposomes by a W/O/W emulsion approach to form supramolecular assemblies with a core of colloidal particles enveloped by a lipid bilayer shell. A nanosilica core provides charge compensation and architectural support for the lipid bilayer, which significantly improves their physical stability. A preliminary application of these core-shell nanocapsules for hemoglobin (Hb) delivery is described. Through the H-bonding interaction between the hydroxyl groups on nanosilicas and the amino nitrogens of Hb, Hb-SiO(2) nanocomplexes in which the saturated adsorption amount of Hb on SiO(2) is 0.47 g g(-1) are coated with lipids to generate core-shell Hb-SiO(2)@liposome nanocapsules with mean diameters of 60-500 nm and Hb encapsulation efficiency of 48.4-87.9%. Hb-SiO(2)@liposome supramolecular nanovehicles create a mode of delivery that stabilizes the encapsulated Hb and achieves long-lasting release, thereby improving the efficacy of the drug. Compared with liposome-encapsulated Hb and Hb-loaded SiO(2) particles, such core-shell nanovehicles show substantially enhanced release performance of Hb in vitro. This finding opens up a new window of liposome-based formulations as drug delivery nanovehicles for widespread pharmaceutical applications.

Effect of crude and carboxyl-functionalized carbon nanotubes on protein–protein interaction

Carbon nanotubes (CNTs) could serve as nanovehicle for drug delivery. It is proposed that this class of emerging materials is capable to penetrate into cells without causing cell death. However, relatively little is known about the potential biological risks from CNTs. Nanoparticles present enormous surface areas and are found to enhance the rate of protein fibrillation by decreasing the lag time for nucleation. Protein fibrillation is associated with protein misfolding diseases including Type II Diabetes, Alzheimer’s, Parkinson's, Creutzfeld-Jacob disease and Dialysis-related amyloidosis. In the present study, via Congo red binding assay and circular dichroism (CD) spectroscopy we investigated the amyloidogenic effects of crude and carboxylated-CNT on the in-vitro fibrillogenesis of hen-egg wight lysozyme at acidic condition. Our results showed that the formation of lysozyme amyloid fibrils at pH 2.0 and 55°C was remarkably increased by the addition of crude unmodified CNTs, whereas carboxylated CNTs did not enhance the probability of appearance of a critical nucleus for nucleation of protein fibrils. Introduction: Recently, considerable effort has been generated to characterize intermediate structures accumulated during protein folding and unfolding (1). Interestingly growth of toxic amyloid structures, is supposed to be associated with various late-onset neurodegenerative disorders, initiated from intermediate structures interaction (2, 3). The potential of nanoparticles to promote protein fibrillation is demonstrated (4). Previous investigations by different research groups showed that exposure of mammalian cells to CNTs caused inhibition of cell proliferation (5), activation of nuclear transcription factor-κB (6) and also increase in oxidative stress and accumulation of peroxidative products (7). Our previous results showed no significant decrease in viability of cells exposed to different concentrations of carboxylated-CNTs (8). Additionally; no significant increase in ROS was seen at CNT concentrations ranging from 1 to 15μgml−1 (8). Also, our finding confirmed that carboxylated-CNTs probably have no interaction with the expression of the iNOS protein (8). In the present study, acidic fibrillation of hen-egg wight lysozyme (HEWL) was analyzed in the presence of prepared crude and carboxylfunctionalized nanotubes. Materials & Methods: Preparation of carbon nanotubes: As-received multi-walled CNTs (10 mg) were suspended in concentrated H2SO4:HNO3 solution (3:1 v/v) and sonicated in a sonication bath for 4 h at 40°C. The CNT suspension was diluted with distilled water and a CNT mat was obtained after filtration through a 0.45 μm polycarbonate membrane. The CNT mat was washed until no acid was detected and then was suspended in 25 ml deionized water (di-H2O) by sonication. IR-spectroscopy was used to verify the CNT functionalization. Amyloid fibril formation condition: A sample solution of 2 mg/ml HEWL in di-H2O (pH 2.0) with salts (136 mM NaCl, 2.7 mM KCl) was prepared. Nanotubes at two final concentrations (2.5 and 10 μg/ml) were added to HEWL solution. HEWL sample solutions were incubated at 55°C for different times. Congo red binding assay: Increase in the absorbance intensity combined with a red shift in the absorbance spectrum of Congo red, is a method of choice to characterize amyloid fibrillation (9). The absorbance spectrum was acquired on Shimadzu UV-visible Spectrophotometer (Kyoto, Japan) in the 400to 600-nm region. Far UV-Circular Dichroism (CD): Far-UV CD spectra were acquired on Aviv 215 spectropolarimeter (Aviv Associates, Lakewood, NJ). A quartz cell with 0.1 mm light path and a protein concentration of 0.6 mg/ml was used to record CD spectrum from 190 to 260 nm. Results and Discussion: The IR spectrum of the acid-treated multi-walled CNTs showed peaks at 3424, 1719 and 1626cm attributed to the hydroxyl, carboxyl and carbonyl functional groups, respectively. Nanoparticles present enormous surface areas and are found to enhance the rate of protein fibrillation by decreasing the lag time for nucleation (4). In this study, effect of nano tubes with polar and non-polar surfaces on the process of amyloid fibrillation was investigated. Results from Congo red absorption spectroscopy demonstrated the formation of fibrillar amyloid structures at 72 hours after the initiation of HEWL incubation in amyloidogenic condition. In addition, CD spectra of HEWL exhibited a characteristic pattern of β-sheet conformation (Fig. 1). In exploring if CNT exerted a stimulatory action on the formation of HEWL fibrils, we monitored the changes of Congo red binding and CD spectra in amyloidogenic conditions. Our observations indicated that crude CNT could outstandingly enhance amyloid fibril formation while CNT in carboxylated form had no significant effect on fibrillation process. It is concluded, introduction of polar groups on the hydrophobic surfaces may play an important inhibitory role on surface-assisted nucleation.

Curcumin nanodisk-induced apoptosis in mantle cell lymphoma

Mantle cell lymphoma (MCL) is a pre-germinal center neoplasm characterized by cyclin D1 overexpression resulting from t(11;14)(q13;q32). Since MCL is incurable with standard lymphoma therapies, new treatment approaches are needed that target specific biologic pathways. In the present study, we investigated a novel drug delivery nanovehicle enriched with the bioactive polyphenol, curcumin (curcumin nanodisks; curcumin-ND). Cells treated with curcumin-ND showed a dose-dependent increase in apoptosis. This was accompanied by enhanced generation of reactive oxygen species (ROS). The antioxidant, N-acetylcysteine, inhibited curcumin-ND induced apoptosis, suggesting that ROS generation plays a role in curcumin action on MCL cells. Curcumin-ND decreased cyclin D1, pAkt, pIκBα, and Bcl2 protein. In addition, enhanced FoxO3a and p27 expression as well as caspase-9, -3, and poly(ADP-ribose) polymerase (PARP) cleavage were observed. Curcumin-ND treatment led to enhanced G1 arrest in two cultured cell models of MCL.

Biocompatible, biodegradable and thermo-sensitive chitosan- g-poly ( N-isopropylacrylamide) nanocarrier for curcumin drug delivery

A nano formulation of curcumin loaded biodegradable thermoresponsive chitosan- g-poly ( N-isopropylacrylamide) co-polymeric nanoparticles (TRC-NPs) (150 nm) were prepared by ionic cross-linking method and characterized. The in vitro drug release was prominent at above LCST. Cytocompatibility of TRC-NPs (100–1000 μg/ml) on an array of cell line is proved by MTT assay. The drug loaded TRC-NPs showed specific toxicity on cancer cells. The cell uptake studies were confirmed by fluorescent microscopy. Flowcytometric analysis of curcumin loaded TRC-NPs showed increased apoptosis on PC3 cells. These results indicated that TRC-NPs could be a potential nanovehicle for curcumin drug delivery.

Biophysical chemistry of macrocycles for drug delivery: a theoretical study

Ab initio (RHF/STO-3G) quantum chemical calculations using the self-consistent reaction field (SCRF) model were carried out to analyze the effect of solvent polarity on the relative Gibbs free energies, the dipole moments, and the structural stability of peptide macrocycles based on unsubstituted cyclo[Gly6] and its trisubstituted derivatives containing Me, NH2, or OH groups at the Cα atom. The macrocycles studied are stable in water at both room temperature and at body fever temperature, which is important for the design of a stable nanovehicle for drug delivery in water.

Hydrophobic pharmaceuticals mediated self-assembly of β-cyclodextrin containing hydrophilic copolymers: Novel chemical responsive nano-vehicles for drug delivery

Double hydrophilic copolymers with one polyethylene glycol (PEG) block and one β-cyclodextrin (β-CD) flanking block (PEG-b-PCDs) were synthesized through the post-modification of macromolecules. The self-assembly of PEG-b-PCDs in aqueous solutions was initially studied by a fluorescence technique. This measurement together with AFM and TEM characterizations demonstrated the formation of nanoparticles in the presence of lipophilic small molecules. The host–guest interaction between the β-CD unit of a host copolymer and the hydrophobic group of a guest molecule was found to be the driving force for the observed self-assembly. This spontaneous assembly upon loading of guest molecules was also observed for hydrophobic drugs with various chemical structures. Relatively high drug loading was achieved by this approach. Desirable encapsulation was also achieved for the hydrophobic drugs that cannot efficiently interact with free β-CD. In vitro release studies suggested that the payload in nano-assemblies could be released in a sustained manner. In addition, both the fluorescence measurement and the in vitro drug release studies suggested that these nano-assemblies mediated by the inclusion complexation exhibited a chemical sensitivity. The release of payload can be accelerated upon the triggering by hydrophobic guest molecules or free β-CD molecules. These results support the potential applications of the synthesized copolymers for the delivery of hydrophobic drugs.

β-casein–based nanovehicles for oral delivery of chemotherapeutic drugs: drug-protein interactions and mitoxantrone loading capacity

β-casein (β-CN), a major milk protein, is amphiphilic and self-associates into micelles in aqueous solutions. We have recently introduced a novel oral drug delivery system based on β-CN nanoparticles. The current research builds on and complements this work by studying the interactions of mitoxantrone (MX) and β-CN as they co-assemble into nanoparticles, using absorption and emission spectra, static and dynamic light scattering, and fluorescent emission of both MX and tryptophan 143 (Trp143) of β-CN. The optimal loading molar ratio was 3.3 MX/β-CN at 1 mg/mL β-CN, and the association constant was (2.45 ± 1.76) × 10 5 M –1 based on β-CN Trp143 fluorescence; independent MX fluorescence results provided supporting values. In these conditions a bimodal particle distribution was obtained (174.4 nm, 45.9%; 485.1 nm, 54.1%). The gastric digestibility of β-CN suggests possible targeting to stomach tumors. Hence, β-CN nanoparticles have potential to serve as effective vehicles of hydrophobic drugs for oral delivery preparations. From the Clinical Editor Beta-casein (b-CN) is an amphiphilic milk protein that self-associates into micelles in aqueous solutions and can be utilized as a novel oral drug delivery system. This study investigates the basic properties of a mitoxantrone delivery system based on the above principles.

Beta-casein nanovehicles for oral delivery of chemotherapeutic drugs

Bovine β-casein (β-CN) is an abundant milk protein that is highly amphiphilic and self-assembles into stable micellar structures in aqueous solutions. Here we introduce a drug-delivery system comprising a model hydrophobic anticancer drug, mitoxantrone (MX), entrapped within β-CN–based nanoparticles. This novel drug-delivery system allows hydrophobic drugs to be thermodynamically stable in aqueous solutions for oral-delivery applications aimed at treatment of various disorders. The gastric digestibility of β-CN suggests possible targeting to stomach tumors. Dimethyl sulfoxide (DMSO)-dissolved MX was entrapped in β-CN nanoparticles by stirring this solution into phosphate-buffered β-CN solution. High-affinity MX–β-CN association was found ( K a = [2.15 ± 0.30] × 10 6 M -1). The optimal nanovehicle formation conditions were 1 mg/mL β-CN, ≤6% (vol/vol) DMSO in phosphate-buffer solution, 10 mM MX in DMSO, and a MX:β-CN molar-ratio of ∼4:1. Under these conditions, particles of 100 to 300-nm diameter were formed. β-CN nanoparticles may serve as effective oral-delivery nanovehicles for solubilization and stabilization of hydrophobic drugs. From the Clinical Editor Bovine β-casein (β-CN) is an abundant milk-protein that is highly amphiphilic and self-assembles into stable micellar-structures in aqueous solutions. β-CN nanoparticles may serve as effective oral-delivery nanovehicles for solubilization and stabilization of hydrophobic drugs, as demonstrated in this study utilizing methotrexate.

Inorganic Metal Hydroxide Nanoparticles for Targeted Cellular Uptake Through Clathrin‐Mediated Endocytosis

Layered double hydroxides (LDHs) are biocompatible materials which can be used as drug-delivery nanovehicles. In order to define the optimum size of LDH nanoparticles for efficient cellular uptake and drug-delivery pathway, we prepared different sized LDH nanoparticles with narrow size distribution by modulating the crystal growth rate, and labelled each LDH particle with a fluorophore using a silane coupling reaction. The cellular uptake rate of LDHs was found to be highly dependent on particle size (50 > 200 > or = 100 > 350 nm), whose range of 50 to 200 nm was selectively internalized into cells through clathrin-mediated endocytosis with enhanced permeability and retention. Our study clearly shows that not only the particle size plays an important role in the endocytic pathway and processing, but also the size control of LDH nanoparticles results in their targeted uptake to site-specific clathrin-mediated endocytosis. This result provides a new perspective for the design of LDH nanoparticles with maximum ability towards targeted drug delivery.

Dynamic control of nanofluidic channels in protein drug delivery vehicles

Abstract Proteocubosomic nanocarriers are three-dimensional (3D) self-assembly periodic nanofluidic structures that have a surface topology of open nanochannels, which is apparent also in natural and self-assembled viral capsids. Here, proteins are nanoconfined in a hydrated self-assembly mixture of amphiphilic monoolein (MO) and octylglucoside (OG) forming cubosomic nanostructures. The generated periodic 3D nanochannel network architectures are investigated by means of synchrotron X-ray diffraction. The structural behavior of the ternary MO/OG/transferrin and MO/OG/immunoglobulin systems as well as the binary MO/OG mixture is studied in excess aqueous environment in the temperature range from 1 to 99 °C. The results indicate that 5% OG molar fraction in protein-containing monoolein systems favors the formation of a swollen bicontinuous cubic liquid crystalline structure with large water channels (D large ). Thus, it is feasible to dynamically adjust the diameters of the nanofluidic aqueous channels in the proteocubosomic carrier via the incorporation of a suitable amphiphilic additive. The obtained results may inspire the development of novel stimuli-responsive protein drug delivery nanovehicles and biocompatible self-regulating nanofluidic devices.