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1. Inflammasome modulation with P2X7 inhibitor A438079-loaded dressings for diabetic wound healing

   https://doi.org/10.3389/fimmu.2024.1340405  

   Yaron, Jordan R; Bakkaloglu, Selin; Grigaitis, Nicole A; Babur, Farhan H; Macko, Sophia; Rhodes, Samantha; Norvor-Davis, Solenne; Rege, Kaushal (February 2024, Frontiers in Immunology)

   The inflammasome is a multiprotein complex critical for the innate immune response to injury. Inflammasome activation initiates healthy wound healing, but comorbidities with poor healing, including diabetes, exhibit pathologic, sustained activation with delayed resolution that prevents healing progression. In prior work, we reported the allosteric P2X7 antagonist A438079 inhibits extracellular ATP-evoked NLRP3 signaling by preventing ion flux, mitochondrial reactive oxygen species generation, NLRP3 assembly, mature IL-1β release, and pyroptosis. However, the short half-lifein vivolimits clinical translation of this promising molecule. Here, we develop a controlled release scaffold to deliver A438079 as an inflammasome-modulating wound dressing for applications in poorly healing wounds. We fabricated and characterized tunable thickness, long-lasting silk fibroin dressings and evaluated A438079 loading and release kinetics. We characterized A438079-loaded silk dressingsin vitroby measuring IL-1β release and inflammasome assembly by perinuclear ASC speck formation. We further evaluated the performance of A438079-loaded silk dressings in a full-thickness model of wound healing in genetically diabetic mice and observed acceleration of wound closure by 10 days post-wounding with reduced levels of IL-1β at the wound edge. This work provides a proof-of-principle for translating pharmacologic inhibition of ATP-induced inflammation in diabetic wounds and represents a novel approach to therapeutically targeting a dysregulated mechanism in diabetic wound impairment. 

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2. Accelerated dermal wound healing in diabetic mice by a H ₂ O ₂ -generating catechol-functionalized gelatin microgel

   https://doi.org/10.1039/D4TB01722F  

   Forooshani, Pegah Kord; Razaviamri, Fatemeh; Smies, Ariana; Morath, Lea M; Pinnaratip, Rattapol; Bhuiyan, Md_Saleh Akram; Rajachar, Rupak; Goldman, Jeremy; Lee, Bruce P (March 2025, Journal of Materials Chemistry B)

   Physically crosslinked gelatin microgels were functionalized with a bioadhesive molecule, catechol, to study the effect of in situ generated H2O2 on full-thickness wound repair in diabetic mice. Due to the physically crosslinked nature of the microgels, they transition into a hydrogel film upon hydration. The formation of a hydrogel film was confirmed by the changes in their morphology and viscoelastic properties. Additionally, these microgels released up to 86 μM of H2O2 as a result of catechol autoxidation. The generated H2O2 completely eradicated Staphylococcus epidermidis with an initial concentration of 103 CFU mL−1. These microgels were not cytotoxic and promoted VEGF upregulation in immortalized human keratinocytes (HaCaT) in vitro. When the microgels were applied to a full-thickness dermal wound in diabetic mice, dermal wound closure was accelerated over 14 days, achieving a wound closure of 90% based on the wound area. Microgel-treated wounds also resulted in complete re-epithelialization and regeneration of new dermal tissues with morphology and structure resembling those of native tissues. These results indicate that the release of micromolar concentrations of H2O2 can accelerate wound healing in a healing-impaired animal. 

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3. Tailored Multidimensional Forest Microneedles for Simultaneous Delivery of Multiple Drugs to Promote Chronic Wound Healing

   https://doi.org/10.1002/admt.202402048  

   Suresh, Hasika; Dos_Santos, Danilo_M; Myers, Darian; Sharma, Atul; Kruzshak, Samantha_J; Curry, Eli; Vissapragada, Sanjana; Tzanakakis, Emmanuel_S; Sonkusale, Sameer (April 2025, Advanced Materials Technologies)

   Abstract Chronic wounds present significant therapeutic challenges due to prolonged inflammation and bacterial infections, impeding healing. Conventional medicinal dressings typically deliver a single drug with a fixed release profile and lack responsiveness to variations in wound size, nature, or severity. This study introduces an innovative microneedle (MN) patch designed with different microneedle geometries and capable of dual‐drug delivery to address irregular wounds and complex therapeutic requirements. Utilizing CO₂ laser lithography, microneedle molds are fabricated with diverse geometries by precisely controlling laser parameters such as speed, power, and focus, achieving needle heights ranging from 162 ± 30 µm to 1570 ± 40 µm. The patch facilitates simultaneous delivery of simvastatin (SIM) for anti‐inflammatory and tetracycline hydrochloride (TH) for antibacterial properties, targeting different skin depths. In vitro diffusion studies confirm geometry‐dependent drug release profiles, with SIM achieving controlled release over three days and TH exhibiting sustained release over four days. Biocompatibility assays confirmed safety and enhanced fibroblast migration is noted in wound‐healing studies. Antimicrobial testing reveals a 99.9% reduction in bacterial viability. This cost‐effective and scalable approach enables precise, localized delivery and customization of MN arrays to match various wound geometries, offering a versatile platform for personalized medicine and improved chronic wound management. 

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4. Fibro‐Gel: An All‐Aqueous Hydrogel Consisting of Microfibers with Tunable Release Profile and its Application in Wound Healing

   https://doi.org/10.1002/adma.202211637  

   Shen, Yanting; Liu, Yuan; Nunes, Janine K; Wang, Chenmin; Xu, Miao; To, Michael KT; Stone, Howard A; Shum, Ho Cheung (May 2023, Advanced Materials)

   Abstract Injectable hydrogels are valuable tools in tissue engineering and regenerative medicine due to their unique advantages of injectability with minimal invasiveness and usability for irregularly shaped sites. However, it remains challenging to achieve scalable manufacturing together with matching physicochemical properties and on‐demand drug release for a high level of control over biophysical and biomedical cues to direct endogenous cells. Here, the use of an injectable fibro‐gel is demonstrated, a water‐filled network of entangled hydrogel microfibers, whose physicochemical properties and drug release profiles can be tailored to overcome these shortcomings. This fibro‐gel exhibits favorable in vitro biocompatibility and the capability to aid vascularization. The potential use of the fibro‐gel for advancing tissue regeneration is explored with a mice excision skin model. Preliminary in vivo tests indicate that the fibro‐gel promotes wound healing and new healthy tissue regeneration at a faster rate than a commercial gel. Moreover, it is demonstrated that the release of distinct drugs at different rates can further accelerate wound healing with higher efficiency, by using a two‐layer fibro‐gel model. The combination of injectability and tailorable properties of this fibro‐gel offers a promising approach in biomedical fields such as therapeutic delivery, medical dressings, and 3D tissue scaffolds for tissue engineering. 

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5. Secured delivery of basic fibroblast growth factor using human serum albumin-based protein nanoparticles for enhanced wound healing and regeneration

   https://doi.org/10.1186/s12951-023-02053-4  

   Son, Boram; Kim, Minju; Won, Hyosub; Jung, Ara; Kim, Jihyun; Koo, Yonghoe; Lee, Na Kyeong; Baek, Seung-Ho; Han, Uiyoung; Park, Chun Gwon; et al (December 2023, Journal of Nanobiotechnology)

   Abstract BackgroundBasic fibroblast growth factor (bFGF) is one of the critical components accelerating angiogenesis and tissue regeneration by promoting the migration of dermal fibroblasts and endothelial cells associated with matrix formation and remodeling in wound healing process. However, clinical applications of bFGF are substantially limited by its unstable nature due to rapid decomposition under physiological microenvironment. ResultsIn this study, we present the bFGF-loaded human serum albumin nanoparticles (HSA-bFGF NPs) as a means of enhanced stability and sustained release platform during tissue regeneration. Spherical shape of the HSA-bFGF NPs with uniform size distribution (polydispersity index < 0.2) is obtainedviaa simple desolvation and crosslinking process. The HSA-bFGF NPs securely load and release the intact soluble bFGF proteins, thereby significantly enhancing the proliferation and migration activity of human dermal fibroblasts. Myofibroblast-related genes and proteins were also significantly down-regulated, indicating decrease in risk of scar formation. Furthermore, wound healing is accelerated while achieving a highly organized extracellular matrix and enhanced angiogenesis in vivo. ConclusionConsequently, the HSA-bFGF NPs are suggested not only as a delivery vehicle but also as a protein stabilizer for effective wound healing and tissue regeneration. 

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