Publications

Thanks to their biocompatibility and ability to support cell growth, alginate hydrogels are promising scaffolds for skin tissue regeneration. If conductive, they can further improve the wound healing process by electrical stimulation (ES). Herein, we explore the preparation and application of robust hydrogels synthesized via the thiol-yne click reaction, a highly efficient and rapid process. Hydrogels were obtained by functionalizing alginate with thiol groups and crosslinking them with a modified 3-arm polyethylene glycol (PEG) precursor (click-Alg). As a final step, the in situ chemical oxidative polymerization of poly(hydroxymethyl-3,4-ethylenedioxythiophene) (semi-interpenetrated PHMeEDOT) rendered them electro-responsive (click-Alg/PHMeEDOT). The gelation of the click-Alg hydrogels proceeded quickly (within 3 min), enabling rapid network formation for injectable application and resulting in high gel fraction, which ensured structural stability. After incorporating PHMeEDOT, a decrease in the pore size happened, while porosity remained predominantly open, with PHMeEDOT completely covering the pores surface. This coating enhanced the electrochemical response of click-Alg/PHMeEDOT hydrogels, whereas their mechanical similarity (with values of Young's modulus = 116 +/- 10.7 kPa) to skin tissue is expected to reduce mismatch risks, improve integration, and minimize stress-related healing issues. Optimized in vitro assays with Vero and HFF-1 cells subjected to 0.6 V for 20 min showed significant wound closure after 2 h, implying that increased electrochemical activity played a key role in promoting wound closure under ES. Overall, we highlight the synergy between both matrices and the effectiveness and potential of click-Alg/PHMeEDOT hydrogels as electrode-like wound dressings for electrically-driven skin tissue repair.

JTD Keywords: Alginate, Behavior, Cell, Collagen, Conducting polymer, Conductivity, Electrical stimulation, Fabrication, Hyaluronic-acid hydrogel, Hydrogel, In-vivo, Membranes, Model, Network, Thiol-yne click chemistry, Wound dressing

Bacterial colonization on biomaterials is a major issue, leading to approximately 20% of implant failures due to infection and biofilm formation. To address this, peptide-based hydrogels incorporating tailored bioactive peptides have emerged as promising candidates for applications in tissue engineering and infection control. Here, we have designed peptide sequences that incorporate i) a self-assembling unit (SaU) and ii) bioactive motifs, including the well-known arginine-glycine-aspartate (RGD) sequence to promote cell adhesion or an antimicrobial peptide derived from lactoferrin (LF) to exhibit antibacterial properties. To aid in the gelation, these peptides were combined with hyaluronic acid (HA), rendering peptide-based hydrogels without the need for additional external assembly triggers, simplifying their application in biomedical contexts. This protocol allowed for a spontaneous formation of a 3D fibrillar network, with structural and physicochemical properties suitable for tissue engineering. The biological evaluation revealed the ability of RGD-based hydrogels to increase the adhesion and spreading of osteoblastic cells compared to controls, while the LF-based hydrogels significantly reduced the viability and attachment of both Gram-positive and Gram-negative strains, clearly affecting bacterial morphology. This report demonstrates the feasibility of this technology to produce hydrogels incorporating distinct biological cues, highlighting their potential as versatile biomaterials to address diverse biomedical challenges.

JTD Keywords: Alginate, Antimicrobial peptide, Bacterial adhesion, Biomaterial, Cell adhesion, Circular-dichroism, Design, Hlf1-11 peptide, Human lactoferrin, Hyaluronic-acid, Lf, Molecules, Peptide-based hydrogels, Rgd, Self-assembling peptide, Titanium

Over the past decades, the development of nanoparticles (NPs) to increase the efficiency of clinical treatments has been subject of intense research. Yet, most NPs have been reported to possess low efficacy as their actuation is hindered by biological barriers. For instance, synovial fluid (SF) present in the joints is mainly composed of hyaluronic acid (HA). These viscous media pose a challenge for many applications in nanomedicine, as passive NPs tend to become trapped in complex networks, which reduces their ability to reach the target location. This problem can be addressed by using active NPs (nanomotors, NMs) that are self-propelled by enzymatic reactions, although the development of enzyme-powered NMs, capable of navigating these viscous environments, remains a considerable challenge. Here, the synergistic effects of two NMs troops, namely hyaluronidase NMs (HyaNMs, Troop 1) and urease NMs (UrNMs, Troop 2) are demonstrated. Troop 1 interacts with the SF by reducing its viscosity, thus allowing Troop 2 to swim more easily through the SF. Through their collective motion, Troop 2 increases the diffusion of macromolecules. These results pave the way for more widespread use of enzyme-powered NMs, e.g., for treating joint injuries and improving therapeutic effectiveness compared with traditional methods. The conceptual idea of the novel approach using hyaluronidase NMs (HyaNMs) to interact with and reduce the viscosity of the synovial fluid (SF) and urease NMs (UrNMs) for a more efficient transport of therapeutic agents in joints.image

JTD Keywords: Biological barrier, Clinical research, Clinical treatments, Collective motion, Collective motion,nanomotors,nanorobots,swarming,viscous medi, Collective motions, Complex networks, Enzymatic reaction, Enzymes, Hyaluronic acid, Hyaluronic-acid,ph,viscoelasticity,adsorption,barriers,behavior,ureas, Macromolecules, Medical nanotechnology, Nano robots, Nanomotors, Nanorobots, Swarming, Synovial fluid, Target location, Viscous media, Viscous medium

A plethora of applications using polysaccharides have been developed in recent years due to their availability as well as their frequent nontoxicity and biodegradability. These polymers are usually obtained from renewable sources or are byproducts of industrial processes, thus, their use is collaborative in waste management and shows promise for an enhanced sustainable circular economy. Regarding the development of novel delivery systems for biotherapeutics, the potential of polysaccharides is attractive for the previously mentioned properties and also for the possibility of chemical modification of their structures, their ability to form matrixes of diverse architectures and mechanical properties, as well as for their ability to maintain bioactivity following incorporation of the biomolecules into the matrix. Biotherapeutics, such as proteins, growth factors, gene vectors, enzymes, hormones, DNA/RNA, and antibodies are currently in use as major therapeutics in a wide range of pathologies. In the present review, we summarize recent progress in the development of polysaccharide-based hydrogels of diverse nature, alone or in combination with other polymers or drug delivery systems, which have been implemented in the delivery of biotherapeutics in the pharmaceutical and biomedical fields. © 2021 American Chemical Society.

JTD Keywords: biodegradable dextran hydrogels, biotherapeutics, bone morphogenetic protein-2, carrageenan-based hydrogels, chitosan-based hydrogels, controlled delivery, controlled-release, cross-linked hydrogels, growth-factor delivery, hydrogels, in-vitro characterization, polysaccharides, self-healing hydrogel, stimuli-responsiveness, tissue engineering, Antibodies, Bioactivity, Biodegradability, Biomedical fields, Biomolecules, Biotherapeutics, Chemical modification, Circular economy, Controlled delivery, Controlled drug delivery, Delivery systems, Drug delivery system, Functional polymers, Hyaluronic-acid hydrogels, Hydrogels, Industrial processs, Polysaccharides, Recent progress, Renewable sources, Stimuli-responsiveness, Targeted drug delivery, Tissue engineering, Waste management