Thermoresponsive and Photocrosslinkable Poly(2-alkyl-2-oxazoline) Toolbox - Customizable Ultralow-Fouling Hydrogel Coatings for Blood Plasma Environments.

This study focuses on developing surface coatings with excellent antifouling properties, crucial for applications in the medical, biological, and technical fields, for materials and devices in direct contact with living tissues and bodily fluids such as blood. This approach combines thermoresponsive poly(2-alkyl-2-oxazoline)s, known for their inherent protein-repellent characteristics, with established antifouling motifs based on betaines. The polymer framework is constructed from various monomer types, including a novel benzophenone-modified 2-oxazoline for photocrosslinking and an azide-functionalized 2-oxazoline, allowing subsequent modification with alkyne-substituted antifouling motifs through copper(I)-catalyzed azide-alkyne cycloaddition. From these polymers surface-attached networks are created on benzophenone-modified gold substrates via photocrosslinking, resulting in hydrogel coatings with several micrometers thickness when swollen with aqueous media. Given that poly(2-alkyl-2-oxazoline)s can exhibit a lower critical solution temperature in water, their temperature-dependent solubility is compared to the swelling behavior of the surface-attached hydrogels upon thermal stimulation. The antifouling performance of these hydrogel coatings in contact with human blood plasma is further evaluated by surface plasmon resonance and optical waveguide spectroscopy. All surfaces demonstrate extremely low retention of blood plasma components, even with undiluted plasma. Notably, hydrogel layers with sulfobetaine moieties allow efficient penetration by plasma components, which can then be easily removed by rinsing with buffer.

Comparison of Physicochemical Characteristics and Biostimulatory Functions in Two Calcium Hydroxyapatite-Based Dermal Fillers.

BACKGROUND:   Dermal fillers containing calcium hydroxyapatite (CaHA) are categorized as biostimulatory. However, differences in CaHA biomaterial likely affect the resultant induction of collagen synthesis, and variability in microsphere shape and size likely influences a patient’s immune response. This study compares 2 CaHA based fillers: one suspended in carboxymethylcellulose (denoted "CaHA/CMC"), and one crosslinked with 1,4-butanediol diglycidyl ether to hyaluronic acid (denoted "CaHA/HA"). OBJECTIVE: To characterize CaHA/CMC and CaHA/HA fillers to stimulate in vitro collagen biosynthesis. METHODS: Physicochemical evaluations included G′ and extrusion force. Scanning electron microscopy (SEM) was used to characterize isolated CaHA microspheres and freeze-dried formulations. Collagen I and III expression were evaluated using immunofluorescence. RESULTS: CaHA/CMC showed higher G′ (P<0.001) and lower extrusion force (P=0.0003), with uniform polymeric-matrix interactions, compared with CaHA/HA. On SEM, isolated microspheres and freeze-dried CaHA/CMC showed round and smooth surfaced microspheres of similar size. Isolated microspheres and freeze-dried CaHA/HA showed nonhomogeneous, broken microspheres, of various sizes, with fragments embedded in the polymer matrix. Although both fillers induced collagen III expression, only CaHA/CMC induced longer-lasting collagen I expression, with increases of 123% (P=0.007) and 164% (P<0.0001) at 2 and 5 mg/mL, respectively, compared with control. CaHA/CMC also increased collagen I expression at equivalent CaHA microsphere concentrations at 2 (P=0.0052) and 5 mg/mL (P<0.0001), compared with CaHA/HA. CONCLUSION: The physicochemical characteristics selected for evaluation were more favorable for CaHA/CMC than CaHA/HA. When compared with CaHA/HA, the smooth, homogeneous microsphere composition of CaHA/CMC promoted significantly more collagen I biosynthesis, an essential process for tissue augmentation and long-lasting aesthetic improvement. Citation: Kunzler C, Hartmann C, Nowag B, et al. Comparison of physicochemical characteristics and biostimulatory functions in two calcium hydroxyapatite-based dermal fillers. J Drugs Dermatol. 2023;22(9):910-916. doi:10.36849/JDD.7684.

Giant Biodegradable Poly(ethylene glycol)-block-Poly(ε-caprolactone) Polymersomes by Electroformation.

Here, the formation of giant enzyme-degradable polymersomes using the electroformation method is reported. Poly(ethylene glycol)-block-poly(ε-caprolactone) polymersomes have been shown previously to be attractive candidates for the detection of bacterial proteases and protease mediated release of encapsulated reporter dyes and antimicrobials. To maximize the efficiency, the maximization of block copolymer (BCP) vesicle size without compromising their properties is of prime importance. Thus, the physical-chemical properties of the BCP necessary to self-assemble into polymeric vesicles by electroformation are first identified. Subsequently, the morphology of the self-assembled structures is extensively characterized by different microscopy techniques. The vesicular structures are visualized for giant polymersomes by confocal laser scanning microscopy upon incorporation of reporter dyes during the self-assembly process. Using time correlated single photon counting and by analyzing the fluorescence decay curves, the nanoenvironment of the encapsulated fluorophores is unveiled. Using this approach, the hollow core structure of the polymersomes is confirmed. Finally, the encapsulation of different dyes added during the electroformation process is studied. The results underline the potential of this approach for obtaining microcapsules for subsequent triggered release of signaling fluorophores or antimicrobially active cargo molecules that can be used for bacterial infection diagnostics and/or treatment.