[1] L P da Silva, R L Reis, V M Correlo et al. Hydrogel-based strategies to advance therapies for chronic skin wounds. Annual Review of Biomedical Engineering, 21, 145-169(2019).

[2] A Bal-Öztürk, B Özkahraman, Z Özbaş et al. Advancements and future directions in the antibacterial wound dressings — a review. Journal of Biomedical Materials Research Part B: Applied Biomaterials, 109, 703-716(2020).

[3] C T Chang. The hemostatic effect and wound healing of novel collagen-containing polyester dressing. Journal of Biomaterials Science Polymer Edition, 34, 2124-2143(2023).

[4] B L Guo, R N Dong, Y P Liang et al. Haemostatic materials for wound healing applications. Nature Reviews Chemistry, 5, 773-791(2021).

[5] Y Li, D F Hao, G Feng et al. A hydrogel wound dressing ideally designed for chronic wound care. Matter, 6, 1060-1062(2023).

[6] Y Gu, B W Zhang, Z Guo et al. Radiation-induced cross-linking: a novel avenue to permanent 3D modification of polymeric membranes. Nuclear Science and Techniques, 32, 70(2021).

[7] Yang GAO, Xinxin FENG, Linfan LI et al. Preparation of a starch-based superabsorbent polymer by γ-ray irradiation and investigation of its properties. Journal of Radiation Research and Radiation Processing, 41, 010204(2023).

[8] R Changotra, J P Guin, S A Khader et al. Radiolytic degradation of ornidazole in aqueous solutions by electron beam irradiation: implications to parameters, kinetics, toxicity and cost evaluation. Journal of Environmental Chemical Engineering, 8, 104423(2020).

[9] S Afroz, F Afrose, A K M M Alam et al. Synthesis and characterization of polyethylene oxide (PEO)—N,N-dimethylacrylamide (DMA) hydrogel by gamma radiation. Advanced Composites and Hybrid Materials, 2, 133-141(2019).

[10] R Hafezi Moghaddam, S Dadfarnia, A M H Shabani et al. Electron beam irradiation synthesis of porous and non-porous pectin based hydrogels for a tetracycline drug delivery system. Materials Science & Engineering C, 102, 391-404(2019).

[11] Y T Wang, S Zhang, J Wang. Photo-crosslinkable hydrogel and its biological applications. Chinese Chemical Letters, 32, 1603-1614(2021).

[12] S X Zhang, X X Lei, Y L Lyu et al. Recent advances of chitosan as a hemostatic material: hemostatic mechanism, material design and prospective application. Carbohydrate Polymers, 327, 121673(2024).

[13] P W Zhao, Z D Guo, H Wang et al. A multi-crosslinking strategy of organic and inorganic compound bio-adhesive polysaccharide-based hydrogel for wound hemostasis. Biomaterials Advances, 152, 213481(2023).

[14] L H Fan, H Yang, J Yang et al. Preparation and characterization of chitosan/gelatin/PVA hydrogel for wound dressings. Carbohydrate Polymers, 146, 427-434(2016).

[15] H Hattori, Y Amano, Y Nogami et al. Hemostasis for severe hemorrhage with photocrosslinkable chitosan hydrogel and calcium alginate. Annals of Biomedical Engineering, 38, 3724-3732(2010).

[16] X F Li, P P Lu, H R Jia et al. Emerging materials for hemostasis. Coordination Chemistry Reviews, 475, 214823(2023).

[17] M Okawa, M Sakoda, S Ohta et al. The balance between the hemostatic effect and immune response of hyaluronan conjugated with different chain lengths of inorganic polyphosphate. Biomacromolecules, 21, 2695-2704(2020).

[18] Y X Chen, Y Xing, J H Han et al. Multifunctional MMP9-responsive silicasomes-GelMA hydrogels with bacteria-targeting capability and tissue restoration function for chronic wound infection. Chemical Engineering Journal, 475, 146246(2023).

[19] Q D Zhang, Q Y Duan, J Tu et al. Thrombin and thrombin-incorporated biomaterials for disease treatments. Advanced Healthcare Materials, 13, e2302209(2024).

[20] C Y Wang, T Y Wu, G W Liu et al. Promoting coagulation and activating SMAD3 phosphorylation in wound healing via a dual-release thrombin-hydrogel. Chemical Engineering Journal, 397, 125414(2020).

[21] W Mozalewska, R Czechowska-Biskup, A K Olejnik et al. Chitosan-containing hydrogel wound dressings prepared by radiation technique. Radiation Physics and Chemistry, 134, 1-7(2017).

[22] F S Liu, X W Zhang, X L Xiao et al. Improved hydrophobicity, antibacterial and mechanical properties of polyvinyl alcohol/quaternary chitosan composite films for antibacterial packaging. Carbohydrate Polymers, 312, 120755(2023).

[23] L Zhao, H Mitomo, M L Zhai et al. Synthesis of antibacterial PVA/CM-chitosan blend hydrogels with electron beam irradiation. Carbohydrate Polymers, 53, 439-446(2003).

[24] M Moritz, M Geszke-Moritz. The newest achievements in synthesis, immobilization and practical applications of antibacterial nanoparticles. Chemical Engineering Journal, 228, 596-613(2013).

[25] S Q Li, S J Dong, W G Xu et al. Antibacterial hydrogels. Advanced Science, 5, 1700527(2018).

[26] A Kapanya, R Somsunan, R Molloy et al. Synthesis of polymeric hydrogels incorporating chlorhexidine gluconate as antibacterial wound dressings. Journal of Biomaterials Science Polymer Edition, 31, 895-909(2020).

[27] M K Rai, S D Deshmukh, A P Ingle et al. Silver nanoparticles: the powerful nanoweapon against multidrug-resistant bacteria. Journal of Applied Microbiology, 112, 841-852(2012).

[28] C Choipang, P Chuysinuan, O Suwantong et al. Hydrogel wound dressings loaded with PLGA/ciprofloxacin hydrochloride nanoparticles for use on pressure ulcers. Journal of Drug Delivery Science and Technology, 47, 106-114(2018).

[29] S Bozdag, W Weyenberg, E Adriaens et al. In vitro evaluation of gentamicin- and vancomycin-containing minitablets as a replacement for fortified eye drops. Drug Development and Industrial Pharmacy, 36, 1259-1270(2010).

[30] B Singh, Rajneesh. Gamma radiation synthesis and characterization of gentamicin loaded polysaccharide gum based hydrogel wound dressings. Journal of Drug Delivery Science and Technology, 47, 200-208(2018).

[31] S M Nasef, E E Khozemy, G A Mahmoud. pH-responsive chitosan/acrylamide/gold/nanocomposite supported with silver nanoparticles for controlled release of anticancer drug. Scientific Reports, 13, 7818(2023).

[32] B L Tao, C C Lin, Y M Deng et al. Copper-nanoparticle-embedded hydrogel for killing bacteria and promoting wound healing with photothermal therapy. Journal of Materials Chemistry B, 7, 2534-2548(2019).

[33] M Ovais, I Ahmad, A T Khalil et al. Wound healing applications of biogenic colloidal silver and gold nanoparticles: recent trends and future prospects. Applied Microbiology and Biotechnology, 102, 4305-4318(2018).

[34] X L Liu, P Y Lee, C M Ho et al. Silver nanoparticles mediate differential responses in keratinocytes and fibroblasts during skin wound healing. ChemMedChem, 5, 468-475(2010).

[35] S J Wang, Y W Zhang, H L Ma et al. Ionic-liquid-assisted facile synthesis of silver nanoparticle-reduced graphene oxide hybrids by gamma irradiation. Carbon, 55, 245-252(2013).

[36] D Singh, A Singh, R Singh. Polyvinyl pyrrolidone/carrageenan blend hydrogels with nanosilver prepared by gamma radiation for use as an antimicrobial wound dressing. Journal of Biomaterials Science Polymer Edition, 26, 1269-1285(2015).

[37] Y Zhou, Y H Zhao, L Wang et al. Radiation synthesis and characterization of nanosilver/gelatin/carboxymethyl chitosan hydrogel. Radiation Physics and Chemistry, 81, 553-560(2012).

[38] F I Abou El Fadl, D E Hegazy, N A Maziad et al. Effect of nano-metal oxides (TiO2, MgO, CaO, and ZnO) on antibacterial property of (PEO/PEC-co-AAm) hydrogel synthesized by gamma irradiation. International Journal of Biological Macromolecules, 250, 126248(2023).

[39] H Albalwi, F I Abou El Fadl, M M Ibrahim et al. Antibacterial impact of acrylic acid/polyvinyl alcohol/MgO various nanocomposite hydrogels prepared by gamma radiation. Polymer Bulletin, 79, 7697-7709(2022).

[40] J Y Yang, D L Liu, Y S Li et al. Radiation construction and excellent performances of Ag NPs/TiO2/PEG/PVP multifunctional aerogel: adsorption-photocatalytic degradation, photosensitive antibacterial and cytotoxicity. Journal of Materiomics, 10, 585-593(2024).

[41] Y S Li, Y Han, J T Qin et al. Photosensitive antibacterial and cytotoxicity performances of a TiO2/carboxymethyl chitosan/poly(vinyl alcohol) nanocomposite hydrogel by in situ radiation construction. Journal of Applied Polymer Science, 133, e44150(2016).

[42] M Arab, M Jallab, M Ghaffari et al. Synthesis, rheological characterization, and antibacterial activity of polyvinyl alcohol (PVA)/zinc oxide nanoparticles wound dressing, achieved under electron beam irradiation. Iranian Polymer Journal, 30, 1019-1028(2021).

[43] A I Raafat, N M El-Sawy, N A Badawy et al. Radiation fabrication of Xanthan-based wound dressing hydrogels embedded ZnO nanoparticles: in vitro evaluation. International Journal of Biological Macromolecules, 118, 1892-1902(2018).

[44] M H Casimiro, A Pereira, J P Leal et al. Chitosan/PVA based membranes processed by gamma radiation as scaffolding materials for skin regeneration. Membranes, 11, 561(2021).

[45] Feng YE, Yu GU, Fei HAN et al. Preparation of sodium alginate-based super absorbent polymer by radiation grafting and crosslinking. Nuclear Techniques, 43, 120301(2020).

[46] B Singh, L Varshney, S Francis et al. Designing tragacanth gum based sterile hydrogel by radiation method for use in drug delivery and wound dressing applications. International Journal of Biological Macromolecules, 88, 586-602(2016).

[47] M J Afshari, N Sheikh, H Afarideh. PVA/CM-chitosan/honey hydrogels prepared by using the combined technique of irradiation followed by freeze-thawing. Radiation Physics and Chemistry, 113, 28-35(2015).

[48] H Y Yao, H R Lin, G P Sue et al. Chitosan-based hydrogels prepared by UV polymerization for wound dressing. Polymers and Polymer Composites, 27, 155-167(2019).

[49] B Hu, M Z Gao, K O Boakye-Yiadom et al. An intrinsically bioactive hydrogel with on-demand drug release behaviors for diabetic wound healing. Bioactive Materials, 6, 4592-4606(2021).

[50] B Singh, L Varshney, S Francis et al. Synthesis and characterization of tragacanth gum based hydrogels by radiation method for use in wound dressing application. Radiation Physics and Chemistry, 135, 94-105(2017).

[51] Y Araki, M Kaibori, S Matsumura et al. Novel strategy for the control of postoperative pain: long-lasting effect of an implanted analgesic hydrogel in a rat model of postoperative pain. Anesthesia and Analgesia, 114, 1338-1345(2012).

[52] Y N Dong, Y X Li, B R Fan et al. Long-term antibacterial, antioxidative, and bioadhesive hydrogel wound dressing for infected wound healing applications. Biomaterials Science, 11, 2080-2090(2023).

[53] R W Cui, L H Zhang, R Y Ou et al. Polysaccharide-based hydrogels for wound dressing: design considerations and clinical applications. Frontiers in Bioengineering and Biotechnology, 10, 845735(2022).

[54] C Zhou, C J Sheng, J J Chen et al. Gradual hydrogel degradation for programable repairing full-thickness skin defect wound. Chemical Engineering Journal, 450, 138200(2022).

[55] J Z Lan, L X Shi, W Y Xiao et al. A rapid self-pumping organohydrogel dressing with hydrophilic fractal microchannels to promote burn wound healing. Advanced Materials, 35, e2301765(2023).