X-ray-activated polymerization expanding the frontiers of deep-tissue hydrogel formation

• Published in: Nature communications Vol. 15; no. 1; p. 3247
• Main Authors: Zhang, Hailei, Tang, Boyan, Zhang, Bo, Huang, Kai, Li, Shanshan, Zhang, Yuangong, Zhang, Haisong, Bai, Libin, Wu, Yonggang, Cheng, Yongqiang, Yang, Yanmin, Han, Gang
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 15.04.2024; Nature Publishing Group; Nature Portfolio
• Subjects: 631/61/2035; 639/301/923/1027; 639/638/455/941; Biology; Bones; Crosslinking; Crosslinking polymerization; DNA damage; Harnesses; Humanities and Social Sciences; Hydrogels; Light; Mitigation; multidisciplinary; Penetration depth; Phosphors; Polymerization; Radiation damage; Science; Science (multidisciplinary); Tissue engineering; Ultraviolet radiation; X-rays
• ISSN: 2041-1723; 2041-1723
• DOI: 10.1038/s41467-024-47559-z

Photo-crosslinking polymerization stands as a fundamental pillar in the domains of chemistry, biology, and medicine. Yet, prevailing strategies heavily rely on ultraviolet/visible (UV/Vis) light to elicit in situ crosslinking. The inherent perils associated with UV radiation, namely the potential for DNA damage, coupled with the limited depth of tissue penetration exhibited by UV/Vis light, severely restrict the scope of photo-crosslinking within living organisms. Although near-infrared light has been explored as an external excitation source, enabling partial mitigation of these constraints, its penetration depth remains insufficient, particularly within bone tissues. In this study, we introduce an approach employing X-ray activation for deep-tissue hydrogel formation, surpassing all previous boundaries. Our approach harnesses a low-dose X-ray-activated persistent luminescent phosphor, triggering on demand in situ photo-crosslinking reactions and enabling the formation of hydrogels in male rats. A breakthrough of our method lies in its capability to penetrate deep even within thick bovine bone, demonstrating unmatched potential for bone penetration. By extending the reach of hydrogel formation within such formidable depths, our study represents an advancement in the field. This application of X-ray-activated polymerization enables precise and safe deep-tissue photo-crosslinking hydrogel formation, with profound implications for a multitude of disciplines. Photo-crosslinking polymerization facilitates precise control of hydrogel formation for various applications including tissue engineering, but most existing photo-crosslinking methods fail to achieve deep-tissue penetration, especially within bone structures. Here the authors report a strategy of low-dose X-ray-activated polymerization that enables deep-tissue hydrogel formation.