Potential applications of alginate oligosaccharides for biomedicine - A mini review.

Extensive research on marine algae, especially on their health-promoting properties, has been conducted. Various ingredients with potential biomedical applications have been discovered and extracted from marine algae. Alginate oligosaccharides are low molecular weight alginate polysaccharides present in cell walls of brown algae. They exhibit various health benefits such as anti-inflammatory, anti-microbial, anti-oxidant, anti-tumor and immunomodulation. Their low-toxicity, non-immunogenicity, and biodegradability make them an excellent material in biomedicine. Alginate oligosaccharides can be chemically or biochemically modified to enhance their biological activity and potential in pharmaceutical applications. This paper provides a brief overview on alginate oligosaccharides characteristics, modification patterns and highlights their vital health promoting properties.

3D printed double-network alginate hydrogels containing polyphosphate for bioenergetics and bone regeneration.

Low mechanical strength, poor processability, and low bioactivity of hydrogels limit their application in bone tissue engineering severely. Herein, a new 3D-printable, osteoinductive, and bioenergetic-active double-network (DN) hydrogel containing sodium alginate (SA), poly (ethylene glycol) diacrylate (PEGDA), and sodium polyphosphate (PolyP) was developed via a two-step method. The synergy of the covalent cross-linking network and the ionic cross-linking network improves the mechanical properties of the hydrogel. And the pre-gel with Ca2+ has better 3D printing performance to print complex tissue engineering scaffolds than common hydrogels. In addition, the incorporation of PolyP into DN hydrogel matrix significantly improves the bioactivity of hydrogels. The bioenergetic effect of PolyP improves adenosine triphosphate content of cells significantly to promote cell activities such as migration. The in vitro osseointegration investigation suggests that the orthophosphate monomer units, which are degradation fragments of PolyP, provide enough phosphoric acid units for the formation of calcium phosphate and accelerate the osteogenic differentiation of cells greatly. Therefore, the proposed printable, bioenergetic-active, osteoinductive DN hydrogel is potential to solve the problems of complex tissue engineering scaffolds and be applied in energy-crucial bone tissue regeneration.

Copper-Free Azide-Alkyne Cycloaddition for Peptide Modification of Alginate Hydrogels.

Alginate, a biocompatible polymer naturally derived from algae, is widely used as a synthetic analogue of the extracellular matrix in tissue engineering. Integrin-binding peptide motifs, including RGD, a derivative of fibronectin, are typically grafted to the alginate polymer through carbodiimide reactions between peptide amines and alginate uronic acids. However, lack of chemo-selectivity of carbodiimide reactions can lead to side reactions that lower peptide bioactivity. To overcome these limitations, we developed an approach for copper-free, strain-promoted azide-alkyne cycloaddition (SPAAC)-mediated conjugation of azide-modified adhesive peptides (azido-cyclo-RGD, Az-cRGD) onto alginate. Successful conjugation of azide-reactive cyclooctynes onto alginates using a heterobifunctional crosslinker was confirmed by azido-coumarin fluorescent assay, NMR, and through click reactions with azide-modified fluorescent probes. Compared to cyclo-RGD peptides directly conjugated to alginate polymers with standard carbodiimide chemistry, Az-cyclo-RGD peptides exhibited higher bioactivity, as demonstrated by cell adhesion and proliferation assays. Finally, Az-cRGD peptides enhanced the effects of recombinant bone morphogenetic proteins on inducing osteogenesis of osteoblasts and bone marrow stromal stem cells in 3D alginate gels. SPAAC-mediated click approaches for peptide-alginate bioconjugation overcome the limitations of previous alginate bioconjugation approaches and potentially expand the range of ligands that can be grafted to alginate polymers for tissue engineering applications.

Construction and research on size and phase 'fixed-point remodelling' intelligent drug delivery system.

It is important to enhance penetration depth of nanomedicine and realise rapid drug release simultaneously at targeted tumour for improving anti-tumour efficiency of chemotherapeutic drugs. This project employed sodium alginate (Alg) as matrix material, to establish tumour-responsive nanogels with particle size conversion and drug controlled release functions. Specifically, tumour-targeting peptide CRGDK was conjugated with Alg first (CRGDK-Alg). Then, doxorubicin (DOX) was efficiently encapsulated in CRGDK-FeAlg nanogel during the cross-linking process (CRGDK-FeAlg/DOX). This system was closed during circulation. Once reaching tumour, the particle size of nanogels was reduced to ∼25 nm, which facilitated deep penetration of DOX in tumour tissues. After entering tumour cells, the size of nanogels was further reduced to ∼10 nm and DOX was released simultaneously. Meanwhile, FeAlg efficiently catalysed H2O2 to produce •OH by Fenton reaction, achieving local chemodynamic therapy without O2 mediation. Results showed CRGDK-FeAlg/DOX significantly inhibited tumour proliferation in vivo with V/V0 of 1.13 after treatment, significantly lower than that of control group with V/V0 of 4.79.

Coumarin-grafted blue-emitting fluorescent alginate as a potentially valuable tool for biomedical applications.

A novel blue-emitting fluorescent alginate derivative has been successfully synthesised in a simple two-reaction step procedure, using an aqueous conjugation strategy that involved carbodiimide coupling followed by an alkyne-azide "click" reaction. The modified alginate maintained the characteristic ability to form mechanically stable hydrogels by ionic crosslinking. The fluorescent properties of the developed biomaterial were investigated both in solution and hydrogel states, revealing that grafting of the coumarin fluorophore to alginate greatly enhanced its fluorescent properties. Importantly, hydrogels maintained around 80% of their initial fluorescence upon long periods of incubation under physiologic conditions. The fluorescent alginate hydrogels showed to be biocompatible in vitro, supporting the viability, metabolic activity and proliferation of mammary epithelial cells and, more importantly, their morphogenesis into spheroids and polarized acini-like structures. These hydrogels were further applied in the establishment of cell-in-gel microarrays for high-throughput screening of cell behaviour in three-dimensional (3D) matrices, being essential for spotting optimization and analysis. Collectively, our results highlight the potential of coumarin-grafted blue-emitting fluorescent alginate as a valuable tool for biomedical applications where hydrogel tracing is required.

Tyrosinase-mediated dopamine polymerization modified magnetic alginate beads for dual-enzymes encapsulation: Preparation, performance and application.

In this study, a simple and efficient method to obtain entrapment of mixtures of double enzymes is developed. As a proof of principle, double enzymes (tyrosinase (TYR) and ß-glucosidase (ß-Glu)) were co-immobilized in magnetic alginate-polydopamine (PDA) beads using in situ TYR-mediated dopamine polymerization and internal setting strategy-mediated magnetic alginate-PDA gelation. The leakage of enzymes from the magnetic alginate beads was significantly reduced by exploiting the double network cross-linking of alginate and PDA, which was induced by the d-(+)-Gluconic acid δ-lactone (GDL) and TYR, respectively. The physicochemical properties of the prepared magnetic alginate beads were characterized by Fourier transform infrared spectroscopy (FT-IR), X-ray diffraction (XRD) and scanning electron microscopy (SEM) analysis. After that, the enzymatic reaction conditions and the performance of the entrapped TYR and ß-Glu, such as enzyme kinetics and inhibition kinetics, were investigated. The Michaelis-Menten constants (Km) of the entrapped TYR and ß-Glu were determined as 2.72 and 3.45 mM, respectively. The half-maximal inhibitory concentrations (IC50) of kojic acid and castanospermine for the entrapped TYR and ß-Glu were determined as 13.04 and 56.23 µM, respectively. Finally, the entrapped double enzymes magnetic alginate beads were successfully applied to evaluate the inhibitory potency of six kinds of tea polyphenols extracts. Black tea and white tea showed high inhibition activity against TYR were (36.14 ± 1.43)% and (36.76 ± 2.35)%, respectively, while the black tea and dark tea showed high inhibition activity against ß-Glu were (37.89 ± 6.70)% and (21.28 ± 4.68)%, respectively.

Synthesis and assessment of sodium alginate-modified silk fibroin microspheres as potential hepatic arterial embolization agent.

Transcatheter arterial chemoembolization (TACE) is well known as an effective treatment for hepatocellular carcinoma (HCC). In the present study, a novel embolic agent of sodium alginate (SA)-modified silk fibroin (SF) microspheres was successfully prepared by emulsifying cross-linking method. The SA-modified SF microspheres were evaluated for the ability of embolization by investigating the morphology, particle size, swelling ratio, degradation, cytotoxicity, blood compatibility, and in vivo embolization. The results found that SA-modified SF microspheres had smooth surfaces and good sphericity. Swelling ratio of the microspheres can meet the requirements of arterial embolic agent and have pH and temperature sensitivity. Furthermore, hemolytic and anticoagulant studies have proved that the microspheres have good blood compatibility. Cytotoxicity tests indicated that the microspheres could promote the proliferation of fibroblasts and HUVEC. In vivo embolization evaluation of microspheres revealed that the arteries could be embolized by SA-modified SF microspheres in 3 weeks. The ability of drug loading and releasing of microspheres was proved by the controlled release profile of Adriamycin hydrochloride. The findings indicated that the SA-modified SF microspheres can be used as a potentially biodegradable arterial embolic agent for liver cancer therapy.

Investigation Of Vitamin B12-Modified Amphiphilic Sodium Alginate Derivatives For Enhancing The Oral Delivery Efficacy Of Peptide Drugs.

PURPOSE: Peptide drugs have been used in therapy various diseases. However, the poor bioavailability of peptide drugs for oral administration has limited their clinical applications, on account of the acidic environment and digestive enzymes inside the human gastrointestinal tract. To enhance stability in the human gastrointestinal tract, bioavailability, and targeted drug delivery of peptide drugs through oral administration, a vitamin B12-modified amphiphilic sodium alginate derivative (CSAD-VB12) was synthesized. MATERIALS AND METHODS: A vitamin B12-modified amphiphilic sodium alginate derivative (CSAD-VB12) was synthesized via the N,N'-dicyclohexylcarbodiimide active method at room temperature, and then characterized using FTIR and 1H NMR spectroscopy. Insulin was used as a model peptide drug and the insulin-loaded CSAD-VB12 (CSAD-VB12/insulin) nanoparticles with negative zeta potentials were prepared in PBS (pH=7.4). Scanning electron microscopy was used to observe CSAD-VB12/insulin as spherical nanoparticles. The CSAD-VB12 derivatives and CSAD-VB12/insulin nanoparticles displayed nontoxicity towards the human colon adenocarcinoma (Caco-2) cells by CCK-8 test. Caco-2 cell model was used to measure the apparent permeability (Papp) of insulin, CSAD/insulin and CSAD-VB12/insulin. Furthermore, confocal was used to confirm the endocytosis of intestinal enterocytes. Type 1 diabetes mice were used to evaluate the intestinal absorption and retention effect of test nanoparticles. RESULTS: They were observed as spherical nanoparticles in the size of 30-50 nm. The CSAD-VB12 derivatives and CSAD-VB12/insulin nanoparticles displayed nontoxicity towards the human colon adenocarcinoma (Caco-2) cells. Comparing with insulin and the CSAD/insulin nanoparticles, the CSAD-VB12/insulin nanoparticles exhibited higher permeation ability through intestinal enterocytes in the Caco-2 cell model. Oral administration of the CSAD-VB12/insulin nanoparticles to Type 1 diabetic mice yields higher intestinal retention effect, targeted absorption, and outstanding efficacy. CONCLUSION: CSAD-VB12 derivatives enhance the small intestinal absorption efficacy and retention of peptide by oral administration, which indicated that it could be a promising candidate for oral peptide delivery in the prospective clinical application.

Silk fibroin-alginate based beads for human mesenchymal stem cell differentiation in 3D.

Lately silk fibroin has gained a lot of popularity as a tissue engineering scaffold due to its exceptional mechanical properties, negligible inflammatory reactions, remarkable biocompatibility, and tunable biodegradability. Nonetheless, 3 dimensional (3D) silk fibroin based scaffolds, which allow simultaneous formation of scaffolds and cell encapsulation with minimal damage to the cells, are unavailable, as most of the methods involve the use of some cell destructive techniques. Thus, cells have to be loaded after the scaffold formation and the study has to rely upon the ability of the cells to penetrate the scaffold to obtain a 3D microenvironment. Hence, these platforms do not allow for a true 3D system replicating the in vivo environment. Here silk fibroin-alginate based beads have been developed, and retain silk fibroin for a longer period of time and allow for simultaneous cell encapsulation as the crosslinking method is cell-compatible. It is demonstrated for the first time that these silk fibroin-alginate beads can be used to encapsulate the cells at varying cell densities depending on the desired application. These beads were further used to study the effect of functional groups on human mesenchymal stem cell (hMSC) differentiation in 3D, by utilizing carboxylic groups naturally present in alginate as well as introducing phosphate groups. The results showed that these beads were able to support the growth and proliferation of hMSCs and induced differentiation solely due to functional groups within 14 days. These beads were better in directing hMSC differentiation into osteogenic and chondrogenic lineages compared to 2D surfaces and differentiation media.

Computational design as a green approach for facile preparation of molecularly imprinted polyarginine-sodium alginate-multiwalled carbon nanotubes composite film on glassy carbon electrode for theophylline sensing.

This paper reports on the synthesis of a novel molecularly imprinted composite film using the mathematical modeling. This composite was then used in the electrode modification for the determination of theophylline. The ratio of monomer to template in optimum condition was obtained to be 4. The modification of electrode was performed in the presence of theophylline through the electropolymerization of arginine on the composite of sodium alginate/multiwalled carbon nanotubes (SA-MWCNTs), which had been coated on glassy carbon electrode (GCE). The SA-MWCNTs composite with netlike morphology demonstrated high conductivity and electrocatalytic activity. Cyclic voltammogram of modified electrode (MIP/SA-MWCNTs/GCE) in the presence of theophylline showed a sensitive anodic peak in 1170 mV in buffer solution of phosphate (pH 7.0). The investigation and optimization of the effective factors on the response and electrochemical behavior of target theophylline were accurately done on the surface of the modified electrode. Theophylline response was linearly within the range of 0.01-60.0 µM with detection limit of 3.2 nM. Regarding the added standards, the recoveries were values between 93.4-105%. The function of this electrode was satisfactory in the determination of theophylline in real samples like theophylline tablet, theophylline oral solution and human plasma samples.

VAOS, a novel vanadyl complexes of alginate saccharides, inducing apoptosis via activation of AKT-dependent ROS production in NSCLC.

Previous studies have confirmed that protein tyrosine phosphatase 1B (PTP1B) can promote tumour progression in non-small cell lung cancer (NSCLC). Vanadyl alginate oligosaccharides (VAOS) is a new coordination compounds that possesses a good PTP1B inhibitory activity. However, the potent anticancer efficacy of VAOS in human NSCLC requires further study. In this study, VAOS exhibited effective inhibitory effects in NSCLC both in cultured cells and in a xenograft mouse model. VAOS was further identified to induce NSCLC cell apoptosis through activating protein kinase B (AKT) to elevate intracellular reactive oxygen species (ROS) levels by increasing in oxygen consumption and impairing the ROS-scavenging system. Neither silencing of PTP1B by siRNA nor transient overexpression of PTP1B had an effect on the AKT phosphorylation triggered by VAOS, indicating that PTP1B inhibition was not involved in VAOS-induced apoptosis. Through phosphorus colorimetric assay, we demonstrated that VAOS notably inhibited phosphatase and tensin homologue deleted on chromosome 10 (PTEN) dephosphorylation activity, another member of the protein tyrosine phosphatases (PTPases)-upstream factor of AKT. Interestingly, PTEN knockdown sensitized cells to VAOS, whereas ectopic expression of PTEN markedly rescued VAOS-mediated lethality. In vivo, VAOS treatment markedly reduced PTEN activity and tumour cell burden with low systemic toxicity. Thus, our data not only provided a new therapeutic drug candidate for NSCLC, but presented new understanding into the pharmacological research of VAOS.

Cell Adhesion Activity of Peptides Conjugated to Polysaccharides.

Many cell-adhesive peptides have been identified from extracellular matrix (ECM) proteins, such as collagen, fibronectin, laminin, and vitronectin. ECM proteins have various cell-adhesive sequences. Most peptides demonstrate cell-adhesive activity when simply coated on a tissue culture plate, but solubility, conformation, and coating efficiency of the peptides can significantly alter their biological function. Evaluation of peptide cell-adhesive activity using peptide-conjugated polysaccharide constructs is a useful strategy for overcoming peptide solubility and conformation problems. After a simple modification of the polysaccharides, various polysaccharides (chitosan, alginate, and hyaluronate) can fix the peptides on the tissue culture plate quantitatively. The peptide-polysaccharide strategy can be used to fix different active peptides to the polysaccharide at same time, thus, mimicking the biological functions of the ECM. This paper describes the modification of polysaccharides that are suitable for covalently coupling the peptides and evaluation of the cell-adhesive activity of peptide as a peptide-polysaccharide matrix. © 2018 by John Wiley & Sons, Inc.

Biocompatible silk/calcium silicate/sodium alginate composite scaffolds for bone tissue engineering.

Scaffolds are crucial for bone tissue engineering since their compositions and properties could significantly affect the seeded cells' behavior. In this study, we developed an interpenetrating network hydrogel by utilizing Ca2+ from calcium silicate (CS) to simultaneously crosslink silk fibroin (SF) and sodium alginate (SA). Afterwards, the hydrogels were lyophilized to obtain scaffolds and systematically evaluated by physical characterizations, in vitro cytocompatibility and alkaline phosphatase (ALP) assay. We found that CS inside the porous structure of SF/CS/SA scaffolds could remarkably enhance hydrophilicity, degradation, compression resistance, bioactivity and pH of SF/CS/SA scaffolds. Scaffolds with CS concentrations of 25% and 12% (25/CS and 12/CS) could dominantly stimulate proliferation of bone marrow stromal cells (BMSCs). Besides, BMSCs cultured with 25/CS and 12/CS scaffolds showed high ALP activity, respectively. Consequently, this study suggested SF/CS/SA scaffolds possess potential in non-loading bone tissue engineering application.

The feasibility study of an in situ marine polysaccharide-based hydrogel as the vitreous substitute.

Although various biopolymers and synthetic compounds have been proposed and tested as the vitreous substitutes, no ideal material has been identified yet. In the present study, we developed an in situ-formed hydrogel by crosslinking hydroxypropyl chitosan with alginate dialdehyde. Physical properties of the hydrogel were studied and the cytotoxicity was evaluated using L929 fibroblasts, rabbit corneal endothelial cells and retinal pigment epithelial cells. In a preliminary in vivo study, the hydrogel was employed as vitreous substitute after vitrectomy surgery on rabbits and multiple parameters indicating biosafety and biocompatibility were measured and analyzed postoperatively. Our results showed that the refractive index, transmittance, pH value and density of the hydrogel were similar to those of human vitreous. Cytotoxicity tests demonstrated the hydrogel to be nontoxic to all of the three cell lines selected. Using the rabbit model, we showed that the hydrogel could form in situ and postoperative analysis of slit-lamp observation, intraocular pressure, corneal endothelium examination, B-scan ultrasound and fundus photography showed no significant adverse reactions in the operated eyes during the 90-day follow-up. However, electroretinogram and histopathological examinations indicated minor vision decline and decrease of the densities of cones and rods in the operated rabbit eyes. Collectively, our study suggested that the in situ-formed hydrogel could potentially be used as a vitreous substitute, with its long-term safety and efficacy to be further assessed. © 2018 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 106A: 1997-2006, 2018.

Enhanced bioadhesivity of dopamine-functionalized polysaccharidic membranes for general surgery applications.

UNLABELLED: An emerging strategy to improve adhesiveness of biomaterials in wet conditions takes inspiration from the adhesive features of marine mussel, which reside in the chemical reactivity of catechols. In this work, a catechol-bearing molecule (dopamine) was chemically grafted onto alginate to develop a polysaccharide-based membrane with improved adhesive properties. The dopamine-modified alginates were characterized by NMR, UV spectroscopy and in vitro biocompatibility. Mechanical tests and in vitro adhesion studies pointed out the effects of the grafted dopamine within the membranes. The release of HA from these resorbable membranes was shown to stimulate fibroblasts activities (in vitro). Finally, a preliminary in vivo test was performed to evaluate the adhesiveness of the membrane on porcine intestine (serosa). Overall, this functionalized membrane was shown to be biocompatible and to possess considerable adhesive properties owing to the presence of dopamine residues grafted on the alginate backbone. STATEMENT OF SIGNIFICANCE: This article describes the development of a mussels-inspired strategy for the development of an adhesive polysaccharide-based membrane for wound healing applications. Bioadhesion was achieved by grafting dopamine moieties on the structural component on the membrane (alginate): this novel biomaterial showed improved adhesiveness to the intestinal tissue, which was demonstrated by both in vitro and in vivo studies. Overall, this study points out how this nature-inspired strategy may be successfully exploited for the development of novel engineered biomaterials with enhanced bioadhesion, thus opening for novel applications in the field of general surgery.

In situ thiolated alginate hydrogel: Instant formation and its application in hemostasis.

An in situ formed hydrogel was synthesized by sodium alginate and cysteine methyl ester, which turned the sodium alginate into thiolated alginate (SA-SH). SA-SH can in situ formed into hydrogel (SA-SS-SA) with a large amount of water through covalent bond in less than 20 s. The structure characterization showed that the mechanism of SA-SH gelation was thiol-disulfide transformation. The rheology and cytotoxicity experiments of SA-SS-SA hydrogel were also investigated, which indicated that SA-SS-SA hydrogel had an appropriate mechanical strength as well as an excellent biocompatibility. The SA-SS-SA hydrogel would degrade under certain conditions after a few days and its mechanism was disulfide alkaline reduction. Finally, the hemostatic property of SA-SH was tested by rat tail amputation experiment. The time to hemostasis of rat reduced from 8.26 min to 3.24 min, which proved that SA-SH had an excellent hemostatic property.

Synthesis and characterization of chitosan-alginate scaffolds for seeding human umbilical cord derived mesenchymal stem cells.

BACKGROUND: Chitosan and alginate are two natural and accessible polymers that are known to be biocompatible, biodegradable and possesses good antimicrobial activity. When combined, they exhibit desirable characteristics and can be created into a scaffold for cell culture. OBJECTIVE: In this study interaction of chitosan-alginate scaffolds with mesenchymal stem cells are studied. METHODS: Mesenchymal stem cells were derived from human umbilical cord tissues, characterized by flow cytometry and other growth parameters studied as well. Proliferation and viability of cultured cells were studied by MTT Assay and Trypan Blue dye exclusion assay. RESULTS: Besides chitosan-alginate scaffold was prepared by freeze-drying method and characterized by FTIR, SEM and Rheological properties. The obtained 3D porous structure allowed very efficient seeding of hUMSCs that are able to inhabit the whole volume of the scaffold, showing good adhesion and proliferation. These materials showed desirable rheological properties for facile injection as tissue scaffolds. CONCLUSION: The results of this study demonstrated that chitosan-alginate scaffold may be promising biomaterial in the field of tissue engineering, which is currently under a great deal of examination for the development and/or restoration of tissue and organs. It combines the stem cell therapy and biomaterials.

Rapid 3D Extrusion of Synthetic Tumor Microenvironments.

The spatial positioning of 3D tumor-mimetic microenvironments, containing multiple cell types, is controlled with a simple concentric flow device in a single step. A range of geometric architectures are demonstrated, and the migration of segregated tumor cells and macrophages is explored using drugs that inhibit heterotypic interactions.

Synthesis and in vitro characterization of a novel S-protected thiolated alginate.

The object of this study was to synthesize and characterize a novel S-protected thiolated polymer with a high degree of modification. In this regard, an alginate-cysteine and an alginate-cysteine-2-mercaptonicotinic acid conjugate were synthesized. To achieve a high coupling rate of the thiol group bearing ligand cysteine to the polymer, the carbohydrate was activated by an oxidative ring opening with sodium periodate followed by a reductive amination to bind the primary amino group of cysteine to resulting reactive aldehyde groups. The obtained thiolated polymer displayed 1561±130µmol thiol groups per gram polymer. About one third of these thiol groups were S-protected by the implementation of a thiol bearing aromatic protection group via disulfide bond formation. Test tablets of both modified polymers showed improved stability against oxidation in aqueous environment compared to the unmodified alginate and exhibit higher water-uptake capacity. Rheological investigations revealed an increased viscosity of the S-protected thiolated polymer whereat the thiolated non S-protected polymer showed gelling properties after the addition of hydrogen peroxide. The mucoadhesive properties could be improved significantly for both derivatives and no alteration in biocompatibility tested on Caco-2 cell monolayer employing an MTT assay could be detected after modification. According to these results, both new derivatives seem promising for various applications.

Multifunctional interpenetrating polymer network hydrogels based on methacrylated alginate for the delivery of small molecule drugs and sustained release of protein.

Multifunctional injectable thermo-/pH-responsive hydrogels as release systems for the oral delivery of small molecule drugs and the local delivery of protein are presented. The injectable interpenetrating polymer network (IPN) hydrogels based on poly(ethylene glycol) methacrylate, N-isopropylacrylamide, and methacrylated alginate were prepared by using ammonium persulfate (APS) and N,N,N',N'-tetramethylethylenediamine (TEMED) as a redox initiator system at body temperature, and the obtained hydrogels overcame the instability of calcium cross-linked alginate hydrogels under physiological conditions. The hydrogels showed good mechanical strength by rheometer and exhibited temperature and pH sensitivity by a swelling test. Diclofenac sodium (DCS) as a model for small molecule water-soluble anti-inflammatory drugs and bovine serum albumin (BSA) as a model for protein drugs were encapsulated in situ in the hydrogel. The DCS and BSA release results indicated that these hydrogels, as carriers, have great potential for use in the oral delivery of small molecule drugs and for long-term localized protein release. Furthermore, the cytotoxicity of these hydrogels was studied via live/dead viability and alamarBlue assays using adipose tissue-derived mesenchymal stem cells.