Thiol-Click Based Polyglycerol Hydrogels as Biosensing Platform with In Situ Encapsulated Streptavidin Probes

An in situ streptavidin-encapsulated hydrogel based on dendritic polyglycerol (dPG) which is functionalized with either an acrylate, allyl or acrylamide group and dithiolated polyethylene glycol (PEG) is constructed via a thiol-click chemistry approach and is investigated for biosensing applications. The hydrogel platform is screened for the encapsulation and release efficiencies of the model protein streptavidin under varying physicochemical conditions, for example, crosslinking chemistry reactions, the molar ratio between the two gel components, macromonomer concentrations or pH-values. By that, tailor-made hydrogels can be developed, which are able to encapsulate or release the model protein for several days based on its modality. Furthermore, the accessible binding site of encapsulated streptavidin or in other words, the biotin-binding performance is quantified, and the stability of the various hydrogel types is studied by rheology measurements, ¹H NMR, gel permeation chromatography (GPC), and mass loss experiments.     

New hydrophilic polyesters and related polymers as bioerodible polymeric matrices

A survey is reported on our activity performed in the last few years on the preparation of new synthetic and semisynthetic polymeric materials endowed with bioerodible-biodegradable characteristics and designed for applications in the practice of controlled release of active principles of pharmaceutical and agrochemical significance. The presentation of the results will be arranged into the following sections: (1) hydroxyl containing polyesters, that comprise polymerization products based on racemic and optically active glyceric acid, or attained by polyaddition reactions among cyclic anhydrides, including also carbon dioxide, with monoglycidyl ethers of reversibly protected polyols. In this class are also presented the related polyhydroxylated systems obtained by selective grafting functional epoxides on cyclodextrins. (2) Bioerodible carboxyl containing plolymeric systems as derived from the alternating copolymerization of maleic anhydride with alkyl vinyl ethers followed by partial esterification of maleic anhydride groups. (3) Linear and cross-linked functional polymers of synthetic and semisynthetic origin with hydrogel forming capability. Typical examples of their applications in the release of drugs and phytodrugs are also presented.     

Solute transport analysis in pH-responsive,complexing hydrogels of poly(methacrylic acid-g-ethylene glycol)

We report on the preparation and properties of hydrogels of poly(methacrylic acid-g-ethylene glycol) that exhibit pH-responsive swelling behavior due to the reversible formation/dissociation of interpolymer complexes. Because of their nature, these materials may be useful in drug delivery applications. In this work, we studied the diffusional behavior of three solutes of varying molecular size in the complexing hydrogels as a function of solution pH. The ability of these gels to control the solute diffusion rates was strongly dependent on the molecular size of the solute and the environmental pH. The diffusion coefficients for solutes were calculated as a function of pH and were lower in acidic than neutral or basic media due to the formation of interpolymer complexes in the gels. However, the ratio of the solute radius to the network mesh size also was a significant factor in the overall behavior of these gels. The diffusion coefficient of the smallest solute, proxyphylline, studied only changed by a factor of five between the complexed and uncomplexed state. However, for the largest solute, FITC-dextran, which has a molecular radius ten times greater than proxyphylline, the diffusion coefficients of the drugs in complexed and uncomplexed gels varied by almost two orders of magnitude. These results are explained in terms of mesh size characteristics of the gels.     

Energy Consumption for the Desalination of Salt Water Using Polyelectrolyte Hydrogels as the Separation Agent

The energy consumption for a novel desalination approach using charged hydrogels under externally applied pressure is experimentally measured and calculated. The salt separation is based on a partial rejection of mobile salt ions caused by the fixed charges inside the polyelectrolyte network. Self‐synthesized and commercial poly(acrylic acid) hydrogels are used to study the desalination performance in reference to sodium chloride solutions within the concentration range of 0.1–35 g L⁻¹. The influence of various synthetic parameters, such as the degree of crosslinking (DC) and the size and shape of the particles, is investigated. Furthermore, the effect of process parameters including the amount of the feed solution, the applied pressure profile, and the swelling time of the hydrogel is discussed. The best energy estimation found so far, is 8.9 kWh m⁻³ fresh water if a poly(acrylic acid) with a DC of 5 mol% is used in an infinite large salt bath.     

地西他滨温敏聚乙二醇化脂质体处方优化及性质表征

 目的 制备地西他滨温度敏感聚乙二醇化脂质体,对处方进行筛选及优化,并且对制剂进行初步评价。方法 选用逆相蒸发法制备地西他滨温度敏感长循环聚乙二醇化脂质体,采用微柱离心-HPLC测定包封率,以包封率为评价指标,考察磷脂浓度、磷脂胆固醇质量比、药脂比、水化介质等因素对脂质体的影响,在此基础上运用正交设计对处方进行优化。 结果 正交设计结果表明,磷脂质量浓度为5 g·L^-1,磷脂与胆固醇的质量比为4∶1,药物磷脂质量比为40∶1,水相pH7.0为最佳处方,制得的脂质体包封率为（44.50±1.08）%,Zeta电位为-8.34 mV,平均粒径为（140.25±2.40）nm,药物在42~43 ℃有突释。结论 优选出最佳处方,制得到地西他滨温度敏感聚乙二醇化脂质体,在相变温度时,体外释药明显。     

Therapeutic angiogenesis by a myoblast layer harvested by tissue transfer printing from cell-adhesive,thermosensitive hydrogels

Peripheral arterial disease (PAD) is characterized by the altered structure and function of arteries caused by accumulated plaque. There have been many studies on treating this disease by the direct injection of various types of therapeutic cells, however, the low cell engraftment efficiency and diffusion of the transplanted cells have been major problems. In this study, we developed an approach (transfer printing) to deliver monolayer of cells to the hindlimb ischemic tissue using thermosensitive hydrogels, and investigated its efficacy in long term retention upon transplantation and therapeutic angiogenesis. We first investigated the in vitro maintenance of robust cell–cell contacts and stable expression of the ECM proteins in myoblast layer following transfer printing process. In order to confirm the therapeutic effect of the myoblasts in vivo, we cultured a monolayer of C2C12 myoblasts on thermosensitive hydrogels, which was then transferred to the hindlimb ischemia tissue of athymic mice directly from the hydrogel by conformal contact. The transferred myoblast layer was retained for a longer period of time than an intramuscularly injected cell suspension. In addition, the morphology of the mice and laser Doppler perfusion (28 days after treatment) supported that the myoblast layer enhanced the therapeutic effects on the ischemic tissue. In summary, the transplantation of the C2C12 myoblast layer using a tissue transfer printing method could represent a new approach for the treatment of PAD by therapeutic angiogenesis.     

Controlled Growth of Polyamide Films atop Homogenous and Heterogeneous Hydrogels Using Gel–Liquid Interfacial Polymerization

Controlled growth of crosslinked polyamide (PA) thin films is demonstrated at the interface of a monomer‐soaked hydrogel and an organic solution of the complementary monomer. Termed gel–liquid interfacial polymerization (GLIP), the resulting PA films are measured to be chemically and mechanically analogous to the active layer in thin film composite (TFC) membranes. PA thin films are prepared using the GLIP process on both a morphologically homogeneous hydrogel prepared from poly(2‐hydroxyethylmethacrylate) and a phase‐separated, heterogeneous hydrogel prepared from poly(acrylamide). Two monomer systems are examined: trimesoyl chloride (TMC) reacting with m‐phenylene diamine (MPD) and TMC reacting with piperazine (PIP). Unlike the self‐limiting growth behavior in TFC membrane fabrication, diffusion‐limited, continuous growth of the PA films is observed, where both the thickness and roughness of the PA layers increase with reaction time. A key morphological difference is found between the two monomer systems using the GLIP process; TMC/MPD produces a ridge‐and‐valley surface morphology whereas TMC/PIP produces nodule/granular structures. The GLIP process represents a unique opportunity to not only explore the pore characteristics (size, spacing, and continuity) on the resulting structure and morphology of the interfacially polymerized thin films, but also a method to modify the surface of (or encapsulate) hydrogels.     

Photofunctionalizable Hydrogel for Fabricating Volume Optical Diffractive Sensors

Volume amplitude gratings made of mesoporous hydrogels are beneficial for sensing, but are difficult to fabricate because they involve creating high aspect ratio features in soft materials. A novel photofunctionalizable hydrogel is reported and its suitability for fabricating grating sensors is demonstrated comprising of features with an aspect ratio of ≈3.2. To make a photofunctionalizable hydrogel with high optical quality that can be patterned using widely available light sources, a water‐soluble photoactive monomer and sensitizer are synthesized. A transmission amplitude grating is subsequently fabricated in a ≈100 µm thick photofunctionalizable hydrogel film by reaction of the free amines generated in the photoexposed regions with pH‐responsive fluorescein isothiocyanate. The volume hydrogel grating described herein is shown to be suitable for real‐time sensing of pH as an exemplar analyte. This work will have a significant impact on the fabrication of diffractive optical structures in thick films of hydrogels that are highly promising for biomolecular sensing in disease diagnosis and healthcare monitoring.     

Control the fate of human umbilical cord mesenchymal stem cells with dual‐enzymatically cross‐linked gelatin hydrogels for potential applications in nerve regeneration

Stem‐cell‐based therapy is a promising strategy to treat challenging neurological diseases, while its application is hindered primarily by the low viability and uncontrolled differentiation of stem cell. Hydrogel can be properly engineered to share similar characteristics with the target tissue, thus promoting cell viability and directing cell differentiation. In this study, we proposed a new dual‐enzymatically cross‐linked and injectable gelatin hydrogel for regulating survival, proliferation, and differentiation of human umbilical cord mesenchymal stem cells (hUC‐MSCs) in a three‐dimensional matrix. This injectable gelatin hydrogel was formed by oxidative coupling of gelatin–hydroxyphenyl acid conjugates catalyzed by hydrogen horseradish peroxidase (HRP) and choline oxidase (ChOx). Modulus and H₂O₂ release can be well controlled by ChOx activity. Results from calcein‐AM/PI staining and Ki67 immunofluorescence tests demonstrated that the survival and proliferation behavior of hUC‐MSCs were highly enhanced in HRP_1UChOx_0.25U hydrogel with lower modulus and less H₂O₂ release compared with other groups. Attractively, the expression of neuron‐specific markers β‐III tubulin, neurofilament light chain (NFL), and synapsin‐1 was significantly increased in HRP_1UChOx_0.25U hydrogel as well. Additionally, in vitro hemolysis test and in vivo HE staining data highlighted the good biocompatibility. Undoubtedly, this injectable gelatin hydrogel's ability to control hUC‐MSCs' fate holds enormous potentials in nervous disorders' therapy and nerve regeneration.