Hydrogels For Drug Delivery Research Articles

Therapeutic efficacy of thermosensitive Pluronic hydrogel for codelivery of resveratrol microspheres and cisplatin in the treatment of liver cancer ascites.

Ascites constitutes the most frequent decompensating event in patients with advanced liver cancer and is associated with poor quality of life and high mortality. Intraperitoneal chemotherapy appears to be a reliable treatment strategy for advanced liver cancer ascites. However, the rapid metabolism of drugs and ascites dilution limits the efficacy of chemotherapeutics. Therefore, the present study aimed to develop a novel thermosensitive hydrogel drug system for targeted therapy of advanced hepatocellular carcinoma (HCC) ascites through intraperitoneal administration. The system was prepared by blending resveratrol (RES) microspheres and cisplatin (DDP) into thermosensitive Pluronic F127 hydrogel. The in vitro anti-tumor activity against H22 cells indicated that the prepared drug system could initiate apoptosis and induce cell cycle arrest at the G1 phase. The mice model of ascites with advanced HCC was established to validate the therapeutic potential of the F127 hydrogel drug system in vivo. The results revealed that intraperitoneal administration of F127 hydrogel drug could significantly inhibit the number of ascites, the proliferation of tumor cells, micro-angiogenesis, and prolong the survival of mice, thus, augmenting the efficacy of intraperitoneal chemotherapy. Moreover, immunohistochemical staining revealed that the F127 hydrogel drug system was safe and presented low toxicity to major vital organs. Collectively, this study highlights the clinical application potential of the F127 hydrogel drug delivery system.

Hydrogel Biomaterials for Application in Ocular Drug Delivery.

There are many challenges involved in ocular drug delivery. These are a result of the many tissue barriers and defense mechanisms that are present with the eye; such as the cornea, conjunctiva, the blinking reflex, and nasolacrimal drainage system. This leads to many of the conventional ophthalmic preparations, such as eye drops, having low bioavailability profiles, rapid removal from the administration site, and thus ineffective delivery of drugs. Hydrogels have been investigated as a delivery system which is able to overcome some of these challenges. These have been formulated as standalone systems or with the incorporation of other technologies such as nanoparticles. Hydrogels are able to be formulated in such a way that they are able to change from a liquid to gel as a response to a stimulus; known as “smart” or stimuli-responsive biotechnology platforms. Various different stimuli-responsive hydrogel systems are discussed in this article. Hydrogel drug delivery systems are able to be formulated from both synthetic and natural polymers, known as biopolymers. This review focuses on the formulations which incorporate biopolymers. These polymers have a number of benefits such as the fact that they are biodegradable, biocompatible, and non-cytotoxic. The biocompatibility of the polymers is essential for ocular drug delivery systems because the eye is an extremely sensitive organ which is known as an immune privileged site.

Role of active nanoliposomes in the surface and bulk mechanical properties of hybrid hydrogels.

Nanoliposomes are widely used as delivery vehicles for active compounds. Nanoliposomes from rapeseed phospholipids were incorporated into interpenetrating polymer network hydrogels of gelatin methacryloyl and alginate. The multiscale physicochemical properties of the hydrogels are studied both on the surface and through the thickness of the 3D network. The obtained composite hydrogels exhibited strong mechanical properties and a highly porous surface. The blend ratio, as well as the concentration of nanoliposomes, affects the properties of the hydrogels. Nanofunctionalized hydrogels induced keratinocyte ​growth. These advantageous characteristics may open up many applications of the developed hydrogels in drug delivery and tissue engineering.

Safety and Biocompatibility of Aflibercept-Loaded Microsphere Thermo-Responsive Hydrogel Drug Delivery System in a Nonhuman Primate Model

PurposeTo evaluate the safety and tolerability of a microsphere thermo-responsive hydrogel drug delivery system (DDS) loaded with aflibercept in a nonhuman primate model.MethodsA sterile 50 µL of aflibercept-loaded microsphere thermo-responsive hydrogel-DDS (aflibercept-DDS) was injected intravitreally into the right eye of 10 healthy rhesus macaques. A complete ophthalmic examination, intraocular pressure (IOP) measurement, fundus photography, spectral-domain optical coherence tomography (SD-OCT), and electroretinogram were performed monthly for 6 months. One macaque was euthanized monthly, and the enucleated eyes were submitted for measurement of bioactive aflibercept concentrations. Four eyes were submitted for histopathology.ResultsInjected aflibercept-DDS was visualized in the vitreous until 6 months postinjection. No abnormalities were observed in the anterior segment, and IOP remained within normal range during the study period. A small number of cells were observed in the vitreous of some macaques, but otherwise the remainder of the posterior segment examination was normal. No significant changes in retinal architecture or function as assessed by SD-OCT and histology or full-field electroretinography, respectively, were observed. A mild, focal foreign body reaction around the injectate was observed with histology at 6 months postinjection. A mean of 2.1 ng/µL of aflibercept was measured in the vitreous.ConclusionsIntravitreally injected aflibercept-DDS achieved controlled, sustained release of aflibercept with no adverse effects for up to 6 months in the eyes of healthy rhesus macaques.Translational RelevanceAflibercept-DDS may be a more effective method to deliver bioactive antivascular endothelial growth factor agents than current practice by reducing the frequency of intravitreal injections and providing controlled drug release.

Drug delivery system of dual-responsive PF127 hydrogel with polysaccharide-based nano-conjugate for textile-based transdermal therapy

Pluronic F-127 based dual-responsive (pH/temperature) hydrogel drug delivery system was developed involving polysaccharide-based nano-conjugate of hyaluronic acid and chitosan oligosaccharide lactate and applied for loading of gallic acid which is the principal component of traditional Chinese medicine Cortex Moutan recommended in the treatment of atopic dermatitis. The polysaccharide-based nano-conjugate was used as pH-responsive compound in the formulation and its amphiphilic character was determined colorimetrically. Microstructure analysis by SEM and TEM indicated highly porous hydrogel network and well-dispersed micellar structures, respectively, after modification with the nano-conjugate, and so, release property of the hydrogel for drug was significantly improved. Different pH-conditions were applied here to see pH-responsiveness of the formulation and increase in acidity of external environment gradually diminished mechanical stability of the hydrogel and that was reflected on the drug release property. Rheology was performed to observe sol-gel transition of the formulation and showed better rheological properties after modification with nano-conjugate. In this study, the cytotoxicity results of PF127 based formulations loaded with/without gallic acid showed cell viability of > 80.0 % for human HaCaT keratinocytes in the concentration range of 0.0–20.0 μg/ml.

Design, Synthesis and Characterization of a Novel Type of Thermo-Responsible Phospholipid Microcapsule-Alginate Composite Hydrogel for Drug Delivery.

Liposomes are extensively used in drug delivery, while alginates are widely used in tissue engineering. However, liposomes are usually thermally unstable and drug-leaking when in liquids, while the drug carriers made of alginates show low loading capacities when used for drug delivery. Herein, we developed a type of thermo-responsible liposome–alginate composite hydrogel (TSPMAH) by grafting thermo-responsive liposomes onto alginates by using Ca2+ mediated bonding between the phosphatidic serine (PS) in the liposome membrane and the alginate. The temperature-sensitivity of the liposomes was actualized by using phospholipids comprising dipalmitoylphosphatidylcholine (DPPC) and PS and the liposomes were prepared by a thin-film dispersion method. The TSPMAH was then successfully prepared by bridge-linking the microcapsules onto the alginate hydrogel via PS-Ca2+-Carboxyl-alginate interaction. Characterizations of the TSPMAH were carried out using scanning electron microscopy, transform infrared spectroscopy, and laser scanning confocal microscopy, respectively. Their rheological property was also characterized by using a rheometer. Cytotoxicity evaluations of the TSPMAH showed that the composite hydrogel was biocompatible, safe, and non-toxic. Further, loading and thermos-inducible release of model drugs encapsulated by the TSPMAH as a drug carrier system was also studied by making protamine–siRNA complex-carrying TSPMAH drug carriers. Our results indicated that the TSPMAH described herein has great potentials to be further developed into an intelligent drug delivery system.

Injectable in Situ Forming Hydrogels of Thermosensitive Polypyrrole Nanoplatforms for Precisely Synergistic Photothermo-Chemotherapy.

The combination of photothermal therapy (PTT) with chemotherapy has great potential to maximize the synergistic effect of thermo-induced chemosensitization and improve treatment performance. To achieve high drug-loading capacity as well as precise synchronization between the controllable release of chemotherapeutics and the duration of near-infrared PTT, in this work, a facile one-step method was first developed to fabricate a novel injectable in situ forming photothermal modulated hydrogel drug delivery platform (D-PPy@PNAs), in which a PNIPAM-based temperature-sensitive acidic triblock polymer [poly(acrylic acid-b-N-isopropylamide-b-acrylic acid (PNA)] was utilized as the stabilizing agent in the polymerization of polypyrrole (PPy). The in situ forming hydrogels showed a sensitive temperature-responsive sol-gel phase-transition behavior, as well as an excellent photothermal property. The strong interaction of ionic bonds together with π-π stacking interactions resulted in high doxorubicin (DOX) loading capacity and controlled/sustained drug release behavior. In addition, D-PPy@PNAs also displayed enhanced cellular uptake and promoted intratumoral penetration of DOX upon NIR laser irradiation. The synergistic photothermal therapy-chemotherapy of D-PPy@PNA hydrogels greatly improved the antitumor efficacy in vivo. Therefore, thermosensitive polypyrrole-based D-PPy@PNA hydrogels may be powerful drug delivery nanoplatforms for precisely synergistic photothermo-chemotherapy of tumors.

Injectable hydrogel enables local and sustained co-delivery to the brain: Two clinically approved biomolecules, cyclosporine and erythropoietin, accelerate functional recovery in rat model of stroke

Therapeutic delivery to the brain is limited by the blood-brain barrier and is exacerbated by off-target effects associated with systemic delivery, thereby precluding many potential therapies from even being tested. Given the systemic side effects of cyclosporine and erythropoietin, systemic administration would be precluded in the context of stroke, leaving only the possibility of local delivery. We wondered if direct delivery to the brain would allow new reparative therapeutics, such as these, to be identified for stroke. Using a rodent model of stroke, we employed an injectable drug delivery hydrogel strategy to circumvent the blood-brain barrier and thereby achieved, for the first time, local and sustained co-release to the brain of cyclosporine and erythropoietin. Both drugs diffused to the sub-cortical neural stem and progenitor cell (NSPC) niche and were present in the brain for at least 32 days post-stroke. Each drug had a different outcome on brain tissue: cyclosporine increased plasticity in the striatum while erythropoietin stimulated endogenous NSPCs. Only their co-delivery, but not either drug alone, accelerated functional recovery and improved tissue repair. This platform opens avenues for hitherto untested therapeutic combinations to promote regeneration and repair after stroke.

Particle diffusion in extracellular hydrogels.

Hyaluronic acid is an abundant polyelectrolyte in the human body that forms extracellular hydrogels in connective tissues. It is essential for regulating tissue biomechanics and cell-cell communication, yet hyaluronan overexpression is associated with pathological situations such as cancer and multiple sclerosis. Due to its enormous molecular weight (in the range of millions of Daltons), accumulation of hyaluronan hinders transport of macromolecules including nutrients and growth factors through tissues and also hampers drug delivery. However, the exact contribution of hyaluronan to tissue penetrability is poorly understood due to the complex structure and molecular composition of tissues. Here we reconstitute biomimetic hyaluronan gels and systematically investigate the effects of gel composition and crosslinking on the diffusion of microscopic tracer particles. We combine ensemble-averaged measurements via differential dynamic microscopy with single-particle tracking. We show that the particle diffusivity depends on the particle size relative to the network pore size and also on the stress relaxation dynamics of the network. We furthermore show that addition of collagen, the other major biopolymer in tissues, causes the emergence of caged particle dynamics. Our findings are useful for understanding macromolecular transport in tissues and for designing biomimetic extracellular matrix hydrogels for drug delivery and tissue regeneration.

Chemical and physical chitosan hydrogels as prospective carriers for drug delivery: a review.

With the advancement of medical research, the source and preparation of biological materials have gradually attracted attention. Hydrogels prepared from natural polysaccharides have been extensively applied in the medical field. The biocompatibility, excellent degradability and low toxicity of chitosan have favored the use of chitosan hydrogels as prospective carriers for drug delivery. Special chitosan hydrogels that effectively release target drugs based on different environmental stimuli have also been developed. This article reviews recent research progress in the development of chemical and physical chitosan hydrogels for drug delivery. In particular, preparation methods together with the chemical and physical properties of chitosan hydrogels are summarized. We also discuss multiple mechanisms of drug release from chitosan hydrogels. Finally, we highlight the future prospects of chitosan hydrogels in medical research.

Versatile composite hydrogels for drug delivery and beyond.

Hydrogels have extended applications across multiple fields. A novel hydrogel material is often evaluated for its properties and applications in either a wet or dry state, but not both. In this study, we investigated a protein-based, composite hydrogel system in both its wet and dry states. Bovine serum albumin (BSA) was used as the hydrogel base. With the assistance of organosilanes, BSA solutions became hydrogels under facile reaction conditions. In the first part, the wet gel was prepared in situ in a syringe; upon injecting through a needle, the gel retained its structure. The use of the nascent gel system as an injectable drug-delivery vehicle is of particular interest. We therefore developed a microplate platform that allows a "one-plate" study-i.e. gel preparation, payload loading and release-all being performed in a single plate. This one-plate method further enables a systematic study of various controlling parameters for drug release. For example, we can tune the release rate by simply adjusting the phosphate content in the hydrogel formulation. Besides, for low-releasing compounds, the release profile was also tunable while using the one-plate method. In the second part, we further demonstrate the versatility of our composite hydrogels. By simply varying the feed ratio of two organosilanes, (3-mercaptopropyl)methyldimethoxysilane and (3-mercaptopropyl)trimethoxysilane, and phosphate concentrations, dry gels exhibiting various absorption capacities towards water, organic solvents, and oil can be prepared. Further characterizations using SEM and 29Si NMR spectroscopy revealed porous structures and hybrid siloxane bridges within the composite material.

Improving the Anti-Ovarian Cancer Activity of Docetaxel by Self-Assemble Micelles and Thermosensitive Hydrogel Drug Delivery System.

In recent decades, a large number of research studies have been conducted to improve the treatment strategy against epithelial ovarian cancer, but women in advanced stage still have poor outcomes. The development of advanced treatments must be continued to overcome the limitation. Docetaxel, a semi-synthetic product derived from the Pacific Taxus extract, has been studied for many years for its potent anticancer applications. Aiming to solve the problems of its highly lipophilicity, insolubility and adverse side effects, nanocarriers were applied. Relying on the integration of nanoparticles which had optimized sizes, shapes, and surface properties, the effect of docetaxel was enhanced. In this study, we designed a novel drug loaded gel-forming nanoparticle system (Doc-NMs-hydrogel composites), which acted as a sustained drug depot for docetaxel. Docetaxel was encapsulated into MPEG-PCL and then into blank thermosensitive hydrogel Pluronic F-127. Characterization showed that the prepared Doc-NMs had high drug loading (7%), minor particle size (37 nm), relatively good water solubility. Moreover, the cytotoxicity, apoptosis induction and the antitumor effects of Doc-NMs-hydrogel composites on mice abdominal SKOV-3 ovarian cancer model were investigated in vivo. Compared with other groups, at the same dosage, Doc-NMs-hydrogel composites show better apoptosis induction and cell growth inhibition. In conclusion, the prepared Doc-NMs-hydrogel composites enhanced anti-tumor activity by increasing local docetaxel concentration, maintaining stable and sustained drug release, prolonging drug retention time in tumors, and reducing toxicity to normal tissues. Doc-NMs-hydrogel composites might have great potential clinical application in anti-ovarian cancer activity.

A self-assembled RNA-triple helix hydrogel drug delivery system targeting triple-negative breast cancer.

The major drawbacks of traditional RNA cancer therapies include low cellular uptake in vitro or in vivo, instability of in vivo circulation, nonspecific bio-distribution, and lack of targeting ability, which result in poor silencing efficiency. Herein, we developed a novel RNA-triple-helix hydrogel for the treatment of triple negative breast cancers (TNBCs) by incorporating RNA-triple-helix and siRNA duplexes of CXCR4 into the same RNA nanoparticles with no synthetic polycationic reagents added. The RNA-triple-helix consists of one tumour suppressor miRNA (miRNA-205) and one oncomiR inhibitor (miRNA-221), both of which showed an outstanding effect in synergistically abrogating tumours. The siRNA duplexes of CXCR4 were embedded into the RNA hydrogel to block breast cancer metastasis and conjugation of the LXL-DNA aptamer (apt-DNA-Chol) is an effective target DNA sequence for MDA-MB-231 cells. The self-assembly of the RNA-triple-helix hydrogel exhibited high selectivity of in vitro and in vivo absorption and controlling miRNA expression when compared to free miRNA and RNA transcripts. The well-developed gene delivery system provided a potential treatment with high specificity and selectivity toward TNBCs. This strategy can be implemented in triplex-helix hydrogel design to form novel miRNA combinations to treat various human cancers.

Application of a mechanically responsive, inflammatory macrophage-targeted dual-sensitive hydrogel drug carrier for atherosclerosis

Atherosclerotic lesions create obvious vascular stenosis due to the presence of plaque, and a large number of inflammatory macrophages are enriched in the thrombus. In this study, we develop a composite hydrogel drug delivery system that is capable of both mechanically-sensitive drug release and of targeting inflammatory macrophages at the thrombus. The hydrogel is a high molecular weight hyaluronic acid (HA) modified with glycidyl methacrylate as a hydrogel precursor; a cross-linkable block copolymer (CBC) is used as the drug coating material and a microscopic cross-linking agent. The difference in drug release rate of the composite hydrogel (HACBC) in simulated blood vessels with 0 % and 75 % occlusion was as high as 49.3 %. Under long-term cycling conditions in stenotic vessels, dynamic shear rheometry revealed that the HACBC still maintained the hydrogel properties. However, the micelles were deformed and recombined to produce smaller sized micelles. An in vitro cell culture demonstrated precise targeting of the HACBC to inflammatory macrophages, and our rabbit experiments with simvastatin-coated HACBC confirmed the effective release of simvastatin in the plaque of the drug carrier. Moreover, we demonstrated the precise targeting of HACBC in vivo in apoE-/- mice by using HACBC coated with cy7. The mechanical stress-sensitive and CD44 receptor-targeted dual-response drug delivery system prepared by micellar composite hydrogel is the first application in the field of atherosclerosis, which provides a new method for diagnosing and treating atherosclerosis.

Recent advances of injectable hydrogels for drug delivery and tissue engineering applications

Injectable hydrogel is a kind of in situ gelling system but has its specificity on the process procedure, which requires a better control of gelation kinetics. Hydrogels with injectability under mild condition are preferred in the field of biomedicine, especially for drug delivery and tissue engineering, because of the favorable carrier property in three-dimension, biocompatibility, low invasive and adaptable shape for administration. Despite the advantages, the development of injectable hydrogels may also face some challenges to meet the various clinical requirements. In this review, we provide a brief summary on the recent progresses on the design, synthesis and evaluation of injectable hydrogels towards biomedical applications.

The preparation of dexamethasone sodium phosphate multivesicular liposomes thermosensative hydrogel and its impact on noise-induced hearing loss in the Guinea pigs

ObjectiveThe aim of this study is to establish the dexamethasone sodium phosphate multivesicular liposomes thermosensative hydrogel (DEX-MVLs-Gel) drug delivery system and to analyze the pharmacodynamics, pharmacokinetics and safety of DEX-MVLs-Gel as well as to explore whether the prepared DEX-MVLs-Gel can protect the hearing in the guinea pigs following noise exposure. MethodsDEX-MVLs formulations were constructed by double emulsion method, and the DEX-MVLs-Gel was prepared after adding P407 and P188 into the DEX-MVLs. A total of 20 adult albino guinea pigs were chosen to establish the animal models with noise-induced hearing loss. After animals were treated with DEX-MVLs-Gel at concentrations of 20, 6 and 2 mg/mL, and 5 mg/mL Dexamethasone Sodium Phosphate (DEX-P) solution, respectively, the hearing function, drug concentration in the peripheral lymph fluid, and hair cell morphology were assessed. ResultsThe ABR threshold of the 20 mg/mL DEX-MVLs-Gel treated group at the frequencies of 4, 8, 16 and 24 kHz were measured as 47.5 ± 5.2, 48.3 ± 4.1, 55.8 ± 3.8 and 57.5 5 ± 5.2 dB SPL, respectively. Statistical significances were noted between the 20 mg/mL DEX-MVLs-Gel treated group and control group at each frequency (all P < 0.05), between the 2 mg/mL and 6 mg/mL DEX-MVLs-Gel treated groups at the frequencies of 4 and 8 kHz (both P < 0.05). High Performance Liquid Chromatography (HPLC) demonstrated that the drug concentrations in the peripheral lymph in all groups were gradually decreased on the 1st, 3rd and 7th d after intratympanic injection. Scattered hair cell loss could be observed mainly in the basal and middle turn in the saline administrated group and the 20 mg/mL DEX-MVLs-Gel administration group, and the hair cell loss was not identified in the apical turn. ConclusionsA high concentration (20 mg/mL) of DEX-MVLs-Gel exerts significant protective effects upon the guinea pigs with noise-induced hearing loss. The prepared DEX-MVLs-Gel can be effectively maintained in the peripheral lymph fluid of guinea pigs for 3–7 d and MVLs-Gel causes no obvious ototoxicity.

Dialdehyde-β-cyclodextrin-crosslinked carboxymethyl chitosan hydrogel for drug release

A simple method was proposed for preparing the dialdehyde-β-cyclodextrin (DA-β-CD) cross-linked carboxymethyl chitosan (CMCS) hydrogels for drug delivery. DA-β-CD was yielded from the sodium periodate oxidation of β-CD. Phenolphthalein (PhP) was adopted as a model drug to study the drug loading and releasing properties of the obtained hydrogels. The results show that the ability of the hydrogel to load drug is affected by the aldehyde content of DA-β-CD. The inclusion constant of DA-β-CD toward PhP is lower than that of the original β-CD and decreased with the rising of the aldehyde content. An increased cross-linking degree between DA-β-CD and CMCS slows the PhP release to some extent. In comparison with glyoxal/CMCS, DA-β-CD/CMCS presents better PhP release properties. Only 19.2 % of PhP loaded in glyoxal/CMCS was released within 24 h. Half of PhP loaded in DA-β-CD/CMCS was released in 2 h and about 90 % was released within 12 h.

Bioinspired pH-sensitive riboflavin controlled-release alkaline hydrogels based on blue crab chitosan: Study of the effect of polymer characteristics

Recently, the application of natural biocompatible polymeric hydrogels for the conception of drug delivery matrices has attracted widespread interest. Thus, in the present study, riboflavin pH-sensitive drug delivery hydrogels were developed based on blue crab chitosan (Cs), via direct dissolution in alkali/urea aqueous solution at low temperatures. First, the effect of Cs characteristics in terms of acetylation degree (AD) and molecular weight (Mw) on the structural, mechanical, thermal, swelling and in vitro biodegradation of Cs-based hydrogels were studied. Data from overall analysis revealed that Cs with low AD and high Mw exhibited improved mechanical properties, as evidenced by the compressive and rheological behaviors tests, thermal resistance, swelling behavior and in vitro degradation kinetics. However, hydrogels pore sizes were reduced with the AD decrease and Mw increase. Additionally, hydrogels in PBS (pH 5.5) underwent quicker degradation, compared to those immersed in PBS (pH 7.4). In the drug delivery model, the kinetics of Riboflavin release, through the Cs-based hydrogels were monitored. The Riboflavin release exhibited typical deliverance patterns, with significantly higher released amounts in more acidic systems. Therefore, drug encapsulation within the conceived pH-sensitive Cs-based hydrogels could provide suitable and promoting microenvironment for drugs delivery.

A novel folic acid hydrogel loading β-cyclodextrin/camptothecin inclusion complex with effective antitumor activity

Folic acid, as a significant vitamin, is essential for human bodies, especially for pregnant women. However, folic acid hydrogel for drug delivery has not been reported until now. Herein, folic acid hydrogel was prepared by ion inducing method firstly. Then β-cyclodextrin/camptothecin inclusion complex was loaded into folic acid hydrogel successfully by co-assembly. Camptothecin loading folic acid hydrogel has good rheological mechanical property and thermodynamic stability. Moreover, the possible mechanism of hydrogel formation was proposed by energy dispersive spectrometer and small-angle X-ray scattering. Besides, compared to camptothecin itself, camptothecin release rate from camptothecin loaded hydrogel was prolongated remarkably through dialysis experiment. Finally, the cell inhibitory rate of camptothecin loading folic acid hydrogel was increased observably compared to camptothecin itself. Hence, as a green drug delivery system, our folic acid hydrogel has important potential application in medical engineering material. Herein, a novel β-cyclodextrin/camptothecin inclusion complex loaded folic acid hydrogel was constructed by elaborate design and preparation, which can load camptothecin into folic acid hydrogel effectively. Moreover, compared to camptothecin itself, camptothecin release rate from camptothecin loaded hydrogel was prolongated remarkably through dialysis experiment. Finally, the cell inhibitory rate of camptothecin loading folic acid hydrogel was increased observably compared to camptothecin itself. Hence, as a green drug delivery system, our folic acid hydrogel has important potential application in medical engineering material.

Preparation of printable double-network hydrogels with rapid self-healing and high elasticity based on hyaluronic acid for controlled drug release

On account of the features about computer-accurate control, the technology of 3D printing has a broad future for developing customized ergonomic biomedical materials. Herein, a printable dual-network hydrogel for drug delivery was designed. The acrylamide-modified hyaluronic acid was mixed with folic acid and Fe3+ at first. With the formation of metal-carboxylate coordination bonds, the first layer of physical crosslinking network (HFF) was formed, followed by performing the spectral analysis and rheology measurements to verify the bonding. The second layer of PAM network was then polymerized by ultraviolet radiation, with high elasticity and fatigue resistance to satisfy its application as a wound dressing. Furthermore, acetylsalicylic acid (Asa) was used as a drug model resulted in a pH responsiveness of the prepared hydrogels with the sustained drug releasing behavior over 300 h. These results signified the potential application of this self-healing hydrogel with good mechanical properties in regenerative medicine.