PEGylated anti-MUC1 aptamer-doxorubicin complex for targeted drug delivery to MCF7 breast cancer cells

Targeted drug delivery is especially important in cancer treatment as many anti-cancer drugs are non-specific and highly toxic to both cancer and normal cells. The targeted drug delivery of DOX to the MUC1-expressing breast cancer cell line (MCF7) was obtained using APT as a carrier. Modification of the APT-DOX complex by PEG increases the survivability of the macrophage control (RAW 264.7) by about six-fold as compared to free DOX treatment without significantly affecting the cytotoxicity toward the target cell line. Thus, PEG-APT-DOX is potentially a new therapeutic agent for targeted drug delivery to MUC1-expressing cell lines.     

Generic, anthracene-based hydrogel crosslinkers for photo-controllable drug delivery

Light‐responsive polymers with controllable, reversible crosslink mechanisms have the potential to create unique biomaterials with stimulus‐controlled swelling, degradation and diffusion properties useful in tissue engineering and drug delivery applications. Generic photodimerizing polyethylene glycol–anthracene macromolecules that may be grafted to various polymers to effectively control their crosslinking via a photodimerization mechanism have been developed. These generic crosslinkers were shown to effectively introduce photoresponsive properties into hyaluronate and alginate as model hydrophilic polymers. In vitro testing using human corneal epithelial cells was used to demonstrate cytocompatibility of the resulting photogels. The effective crosslinking density of the photogels could be increased resulting in a decrease in the release rate of small and large molecules from the photogels following exposure to 365 nm light. This tuneable crosslinking has the potential to manipulate the delivery rates of therapeutics resulting in control over treatment profiles and may lend itself to various applications, which may benefit from light induced changes in crosslinking.

     

UV-photocrosslinking of inulin derivatives to produce hydrogels for drug delivery application

In this work, INU, a natural polysaccharide, has been chemically modified in order to obtain new photocrosslinkable derivatives. To reach this goal, INU has been derivatized with MA thus obtaining four samples (INU-MA derivatives) as a function of the temperature and time of reaction. An aqueous solution of the derivative INU-MA1 was irradiated by using a UV lamp with an emission range from 250 to 364 nm and without using photoinitiators. The obtained hydrogel showed a remarkable water affinity but it underwent a partial degradation in simulated gastric fluid. To overcome this drawback, INU-MA1 was derivatized with SA thus obtaining the INU-MA1-SA derivative designed to produce a hydrogel showing a low swelling and an increased chemical stability in acidic medium. Ibuprofen, as a model drug, was loaded by soaking into INU-MA1 and INU-MA1-SA hydrogels and its release from these matrices was evaluated in simulated gastrointestinal fluids. INU-MA1 hydrogel showed the ability to quickly release the entrapped drug thus indicating its potential as a matrix for an oral formulation. INU-MA1-SA hydrogel showed a pH-responsive drug delivery. Therefore it is a promising candidate for controlled drug release in the intestinal tract.     

Co‐delivery of 10‐Hydroxycamptothecin with Doxorubicin Conjugated Prodrugs for Enhanced Anticancer Efficacy

Well‐defined amphiphilic linear‐dendritic prodrugs (MPEG‐b‐PAMAM‐DOX) are synthesized by conjugating doxorubicin (DOX), to MPEG‐b‐PAMAM through the acid‐labile hydrazone bond. The amphiphilic prodrugs form self‐assembled nanoparticles in deionized water and encapsulate the hydrophobic anticancer drug 10‐hydroxycamptothecin (HCPT) with a high drug loading efficiency. Studies on drug release and cellular uptake of the co‐delivery system reveal that both drugs are released in a pH‐dependent manner and effectively taken up by MCF‐7 cells. In vitro methyl thiazolyl tetrazolium (MTT) assays and drug‐induced apoptosis tests demonstrate the HCPT‐loaded nanoparticles suppress cancer cell growth more efficiently than the MPEG‐b‐PAMAM‐DOX prodrugs, free HCPT, and physical mixtures of MPEG‐b‐PAMAM‐DOX and HCPT at equivalent DOX or HCPT doses.

     

Hybrid alginate beads with thermal‐responsive gates for smart drug delivery

Polysaccharide‐based thermo‐responsive material was prepared by grafting PNIPAAm onto hybrid alginate beads, in which a biomineralized polyelectrolyte layer was constructed aiming to enhance the mechanical strength and ensure higher graft efficiency. XPS results demonstrated that the incorporation of PNIPAAm to the hybrid beads was successful, and the PNIPAAm‐grafted beads were more hydrophilic than the ungrafted ones as indicated by their swelling behavior. The drug release behaviors revealed that the grafted beads were both thermo‐ and pH‐sensitive, and the PNIPAAm existed in the pores of the alginate beads acted as the “on–off” gates: the pores of the beads were covered by the stretched PNIPAAm to delay the drug release at 25°C and opened to accelerate the drug release at 37°C because of the shrinking of PNIPAAm molecules. This paper would be a useful example of grafting thermo‐responsive polymers onto biodegradable natural polymer substrate. The obtained beads provide a new mode of behavior for thermo‐responsive “smart” polysaccharide materials, which is highly attractive for targeting drug delivery system and chemical separation. Copyright © 2010 John Wiley & Sons, Ltd.     

Designing responsive microgels for drug delivery applications

Microgels based on thermally responsive polymers have been widely investigated in the context of controlled release applications, with increasing recent interest on developing a clearer understanding of what physical, chemical, and biological parameters must be considered to rationally design a microgel to deliver a specific drug at a specific rate in a specific physiological context. In this contribution, we outline these key design parameters associated with engineering responsive microgels for drug delivery and discuss several recent examples of how these principles have been applied to the synthesis of microgels or microgel-based composites. Overall, we suggest that in vivo assessment of these materials is essential to bridge the existing gap between the fascinating properties observed in the lab and the practical use of microgels in the clinic. © 2013 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2013, 51, 3027–3043     

Thermosensitive and photocleavable polyaspartamide derivatives for drug delivery

The development of novel thermo‐ and photo‐dual‐responsive biodegradable polymeric micelles based on amphiphilic polyaspartamide derivatives (NB‐g‐PHPA‐g‐mPEG) for anticancer drug delivery is reported. The obtained polymers containing hydrophobic photocleavable o‐nitrobenzyl groups exhibit thermo‐ and photosensitivity. The micelles and paclitaxel‐loaded micelles based on the thermo‐ and photo‐dual‐sensitive polymers were prepared by a quick heating method without using toxic organic solvent. The paclitaxel release from the drug‐loaded micelles can be triggered under photoirradiation. Enhancement of the anticancer activity against HeLa cells was observed for paclitaxel‐loaded NB‐g‐PHPA‐g‐mPEG micelles after light irradiation, while the empty NB‐g‐PHPA‐g‐mPEG micelles with or without irradiation did not show any toxicity. Therefore, the thermo‐ and photo‐dual‐responsive NB‐g‐PHPA‐g‐mPEG micelles have a promising future applied as a light controlled drug delivery system for anticancer drugs. © 2016 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2016 , 54, 2855–2863     

Inorganic–organic hybrid alginate beads with LCST near human body temperature for sustained dual‐sensitive drug delivery

In order to obtain dual‐stimuli‐responsive (temperature/pH) alginate beads that exhibit LCST close to human body temperature for sustained drug release applications, poly (NIPAAm‐co‐AAm) hydrogel (with LCST 37.5°C) were selected and associated with calcium alginate to prepare inorganic–organic hybrid biomineralized polysaccharide alginate beads via a one‐step method in this paper. Scanning electron microscopy (SEM) and energy dispersive X‐ray spectrometer (EDS) results demonstrated that calcium phosphate could not only be found in the surface but also in the cross‐section of biomineralized polysaccharide beads. Both equilibrium swelling and indomethacin release behavior were found to be pH‐ and thermo‐responsive. In addition, indomethacin release profile could be sustained with a inorganic–organic hybrid membrane: the release amount reached 96% within 4 hr for the unmineralized beads, while a drug release of only 64% obtained after subjecting the biomineralized polysaccharide beads to the same treatment. These results indicate that the biomineralized polysaccharide membrane could prevent the permeability of the encapsulated drug and reduce the drug release rate effectively. The studied system has the potential to be used as an effective smart sustainable delivery system for biomedical applications. Copyright © 2008 John Wiley & Sons, Ltd.     

Hydrolyzable p(DMAPEMA) polymers for gene delivery

The efficiency of cationic polymers as transfectants is thought to be closely related to their DNA association/dissociation properties. An incomplete polymer-DNA dissociation could explain the relatively low gene expression obtained with p(DMAEMA) polymers. Our approach was to synthesize a p(DMAEMA) analogue, p(DMAPEMA), bearing an hydrolyzable cationic group incorporated into the pendant chain with a view to improving transfection. The complexation of DNA with both polymers was studied by agarose gel electrophoresis, size and zeta potential measurements, as well as the dissociation of the polyplexes, after treatment by an anionic polymer, sodium hydroxide or heat. The transfection efficiencies of the polyplexes were evaluated with 293T and BHK21 cells in comparison with Exgen 500. P(DMAPEMA) polymers were able to complex DNA and to release it in a free intact form after an alkaline treatment or storage at 37 degrees C. Poly(aspartic acid) was unable to dissociate p(DMAPEMA) based polyplexes, in contrast to p(DMAEMA) ones. No transfection was obtained with p(DMAPEMA) with both cell lines. A slow hydrolysis under physiological conditions resulting in the absence of DNA unpacking or endosomal entrapment could explain these results. Better transfection results were obtained with polyplexes which were able to be dissociated by electrostatic interactions rather than ones which required the hydrolysis mechanism to release free DNA into cells. Scheme of hydrolyzable p(DMAPEMA) polymer.     

Responsive Materials for Self‐Regulated Insulin Delivery

With diabetes mellitus becoming an important public health concern, insulin‐delivery systems are attracting increasing interest from both scientific and technological researchers. This feature article covers the present state‐of‐the‐art glucose‐responsive insulin‐delivery system (denoted as GRIDS), based on responsive polymer materials, a promising system for self‐regulated insulin delivery. Three types of GRIDS are discussed, based on different fundamental mechanisms of glucose‐recognition, with: a) glucose enzyme, b) glucose binding protein, and c) synthetic boronic acid as the glucose‐sensitive component. At the end, a personal perspective on the major issues yet to be worked out in future research is provided.     

PNVCL‐PEGMA nanohydrogels with tailored transition temperature for controlled delivery of 5‐fluorouracil

Sensitive nanohydrogels were prepared via surfactant free emulsion copolymerization of N‐vinylcaprolactam and poly(ethylene glycol) methyl ether methacrylate, and either N‐vinylpyrrolidone (VP) or 2‐methacryloyloxybenzoic acid (2MBA) to adjust the transition temperature (T_tr). The crosslinker ethylene glycol dimethacrylate was used for the polymer network construction. The resulting nanohydrogel sizes are between 120 and 300 nm. ρ‐Parameter, obtained from light scattering studies, suggests that core‐sell nanogels of flexible chains were obtained. T_tr increases with increasing comonomer content (VP or 2MBA) and decreases with decreasing pH for 2MBA containing nanohydrogels. Nanohydrogels containing 15.5% of 2MBA exhibit T_tr close to 38 °C. Nanogels are able to control the release of the loaded antineoplastic drug 5‐fluorouracil. For the prepared T/pH‐sensitive nanogels, the release is slower at pH 7.4 and 37 °C than at tumor conditions: pH 6 and 40 °C. Mathematical models were applied to evaluate the kinetics of drug release; Peppas model fitted best indicating a Fickian diffusion trough a sphere. © 2015 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2015 , 53, 2662–2672     

Synthesis and characterization of biodegradable pH and reduction dual‐sensitive polymeric micelles for doxorubicin delivery

Novel pH and reduction dual‐sensitive biodegradable polymeric micelles for efficient intracellular delivery of anticancer drugs were prepared based on a block copolymer of methyloxy‐poly(ethylene glycol)‐b‐poly[(benzyl‐l ‐aspartate)‐co‐(N‐(3‐aminopropyl) imidazole‐l ‐aspartamide)] [mPEG‐SS‐P(BLA‐co‐APILA), MPBA] synthesized by a combination of ring‐opening polymerization and side‐chain reaction. The pH/reduction‐responsive behavior of MPBA was observed by both dynamic light scattering and UV–vis experiments. The polymeric micelles and DOX‐loaded micelles could be prepared simply by adjusting the pH of the polymer solution without the use of any organic solvents. The drug release study indicated that the DOX‐loaded micelles showed retarded drug release in phosphate‐buffered saline at pH 7.4 and a rapid release after exposure to weakly acidic or reductive environment. The empty micelles were nontoxic and the DOX‐loaded micelles displayed obvious anticancer activity similar to free DOX against HeLa cells. Confocal microscopy observation demonstrated that the DOX‐loaded MPBA micelles can be quickly internalized into the cells, and effectively deliver the drugs into nuclei. Thus, the pH and reduction dual‐responsive MPBA polymeric micelles are an attractive platform to achieve the fast intracellular release of anticancer drugs. © 2014 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2014 , 52, 1771–1780     

Microgels for the encapsulation and stimulus-responsive release of molecules with distinct polarities

A microfluidic strategy for the encapsulation and stimulus-responsive release of molecules with distinct polarities from the interior of microgels is reported. The approach relies on (i) the generation of a primary O/W emulsion by the ultrasonication method, (ii) MF emulsification of the primary emulsion, and (iii) photopolymerization of the monomer present in the aqueous phase of the droplets, thereby transforming them into microgels. Non-polar molecules are dissolved in oil droplets embedded in the microgels. Polar molecules are physically associated with the hydrogel network. Upon heating, the microgels contract and release polar and non-polar cargo molecules. The approach paves the way for stimuli-responsive vehicles for multiple drug delivery.     

Polymer Micro‐ and Nanocapsules as Biological Carriers with Multifunctional Properties

The design and development of multifunctional polymer capsules with controlled chemical composition and physical properties has been the focus of academic and industrial research in recent years. Especially in the biomedical field, the formulation of novel polymer‐based encapsulation systems for the early‐stage disease diagnostic and effective delivery of bioactive agents represent one of the most rapidly advancing areas of science. The stimuli‐responsive release of cargo molecules from the carrier gains remarkable attention for in vitro and in vivo delivery of contrast agents, genes, and pharmaceutics. In this Review, the current status and the challenges of different polymer‐based micro‐ and nanocapsule formulations are considered, emphasizing on their potential biological application as carriers for specific drug targeting and controlled release upon applying of external stimulus.     

3‐D Interdigitated electrodes for uniform stimulation of electro‐responsive hydrogels for biomedical applications

Stimuli‐responsive hydrogels are continuing to increase in demand in biomedical applications. Occluding a blood vessel is one possible application which is ideal for a hydrogel because of their ability to expand in a fluid environment. However, typically stimuli‐responsive hydrogels focus on bending instead of radial uniform expansion, which is required for an occlusion application. This article focuses on using an interdigitated electrode device to stimulate an electro‐responsive hydrogel in order to demonstrate a uniform swelling/deswelling of the hydrogel. A Pluronic‐bismethacrylate (PF127‐BMA) hydrogel modified with hydrolyzed methacrylic acid, in order to make it electrically responsive, is used in this article. An interdigitated electrode device was manufactured containing Platinum electrodes. The results in this paper show that the electrically biased hydrogels deswelled 230% more than the non‐biased samples on average. The hydrogels deswelled uniformly and showed no visual deformations due to the electrical bias. © 2013 Wiley Periodicals, Inc. J. Polym. Sci., Part B: Polym. Phys. 2013 , 51, 1523–1528     

Facile Fabrication of Thermo‐Responsive and Reduction‐Sensitive Polymeric Micelles for Anticancer Drug Delivery

The development of thermo‐responsive and reduction‐sensitive polymeric micelles based on an amphiphilic block copolymer poly[(PEG‐MEMA)‐co‐(Boc‐Cyst‐MMAm)]‐block‐PEG (denoted PEG‐P‐SS‐HP) for the intracellular delivery of anticancer drugs is reported. PTX, as model drug, was loaded into the PEG‐P‐SS‐HP micelles with an encapsulation efficiency >90%, resulting in a high drug loading content (up to 35 wt%). The PTX‐loaded PEG‐P‐SS‐HP micelles show slow drug release in PBS and rapid release after incubation with DTT. The PTX‐loaded micelles display a better cytotoxic effect than the free drug, whereas empty micelles are found to be non‐toxic. The thermo‐responsive and reduction‐sensitive polymeric micelles described may serve as promising carriers for cytostatic drugs.

     

Dual Thermo‐ and pH‐Responsive Zwitterionic Sulfobataine Copolymers for Oral Delivery System

A novel oral delivery system consisting of thermoresponsive zwitterionic poly(sulfobetaine methacrylate) (PSBMA) and pH‐responsive poly(2‐(diisopropylamino)ethyl methacrylate) (PDPA) is synthesized via free radical polymerization. This copolymer can self‐aggregate into nanoparticles via electrostatic attraction between ammonium cation and sulfo‐anion of PSBMA and successfully encapsulate anticancer drug, curcumin (CUR), with highest loading content of 2.6% in the P(SBMA‐co‐DPA) nanoparticles. The stimuli‐responsive phase transition behaviors of P(SBMA‐co‐DPA) copolymers at different pH buffer solution show pH‐dependent upper critical solution temperature (UCST) attributed to the influence of protonation/deprotonation of the pH‐responsive DPA segments. Through the delicate adjustment of the PSBMA/PDPA molar ratios, the stimuli‐responsive phase transition could be suitable for physiological environment. The kinetic drug release profiles demonstrate that P(SBMA‐co‐DPA) nanoparticles have the potential as oral delivery carriers due to their effective release of entrapped drugs in the stimulated intestinal fluid and preventing the deterioration of drug in stimulated gastric fluid.

     

Novel hyaluronan-based nanocarriers for transmucosal delivery of macromolecules

The goal of this work was to design a new nanocarrier composed of the glycosaminoglycan hyaluronan and the polysaccharide chitosan, intended for the transmucosal delivery of macromolecules. The nanoparticles were characterized for their size and superficial charge. The incorporation of hyaluronan was verified by agarose gel electrophoresis and Fourier transform infrared (FT-IR) spectroscopy. The ability of the nanosystems to encapsulate macromolecules was studied taking the hydrophilic protein bovine serum albumin (BSA) and the hydrophobic polypeptide Cyclosporine A (CyA) as models. Results showed that the experimental conditions could be conveniently adjusted in order to modulate the physicochemical properties of the carriers and their composition. Moreover, the nanoparticles provided high association efficiencies of the selected macromolecules.     

Redox‐ and pH‐Responsive Cysteamine‐Modified Poly(aspartic acid) Showing a Reversible Sol–Gel Transition

Synthesis and characterization of a pH‐ and redox‐sensitive hydrogel of poly(aspartic acid) are reported. Reversible gelation and dissolution are achieved both in dimethylformamide and in aqueous medium via a thiol‐disulphide interconversion in the side chain of the polymers. Structural changes are confirmed by Raman microscopy and rheological measurements. Injectable aqueous solutions of thiolated poly(aspartic acid) can be converted into mechanically stable gels by oxidation, which can be useful for drug encapsulation and targeted delivery. Reduction‐facilitated release of an entrapped drug from disulphide cross‐linked hydrogels is studied.