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=== Assistant: Here’s the best, citable trail I can find behind “MIT + injectable gel + nerve regeneration.” Short verdict up top: the… === Here’s the best, citable trail I can find behind “MIT + injectable gel + nerve regeneration.” Short verdict up top: there’s real MIT-connected work on injectable hydrogels/scaffolds for neural repair and drug delivery, and an MIT spinout (Tissium) advancing a light-activated polymer for nerve repair during surgery—but I can’t find any MIT study matching the viral post’s claim of a simple injection that fully restores sensation/motor function in animals or people. Still, these are the closest, credible sources: ===== 1. Designing more-injectable hydrogels (MIT News). Framework for creating granular hydrogels that can be injected to repair/replace tissues (general platform, not a cure-all for nerves). news.mit.edu<ref>{{cite web|title=news.mit.edu|url=https://news.mit.edu/2023/hydrogels-blocks-injectable-tissue-repair-0131|publisher=news.mit.edu|access-date=2025-11-11}}</ref> ===== # MIT thesis: Injectable hydrogels for improved delivery in spinal cord injury (2014). Early MIT work on hydrogels as delivery systems in SCI. DSpace<ref>{{cite web|title=DSpace|url=https://dspace.mit.edu/handle/1721.1/98723|publisher=dspace.mit.edu|access-date=2025-11-11}}</ref> # MIT thesis: Injectable collagen hydrogel for neural tissue regeneration (2013). Focused on biomaterials–tissue interactions in neural repair. DSpace<ref>{{cite web|title=DSpace|url=https://dspace.mit.edu/handle/1721.1/84410|publisher=dspace.mit.edu|access-date=2025-11-11}}</ref> # MIT spinout Tissium (2025). Light-activated biopolymer used by surgeons to join/repair tissues, including nerves, potentially reducing sutures; early clinical use reported in digital nerve repairs (not a “simple injection to regrow nerves”). news.mit.edu<ref>{{cite web|title=news.mit.edu|url=https://news.mit.edu/2025/ushering-new-era-suture-free-tissue-reconstruction-better-healing-0801|publisher=news.mit.edu|access-date=2025-11-11}}</ref> # Exercise-linked nerve growth (MIT) (2024). Neurons extend more in the presence of muscle-derived “myokines” (cell studies); relevant to regeneration biology, not an injectable gel therapy. news.mit.edu<ref>{{cite web|title=news.mit.edu|url=https://news.mit.edu/2024/when-muscles-work-out-they-help-neurons-grow-1112|publisher=news.mit.edu|access-date=2025-11-11}}</ref> ===== 1. Review: “Injectable Hydrogels for Nervous Tissue Repair” (2024). Surveys injectable hydrogels for CNS/PNS repair; most data preclinical; promising but not curative. PMC<ref>{{cite web|title=PMC|url=https://pmc.ncbi.nlm.nih.gov/articles/PMC10970171/|publisher=pmc.ncbi.nlm.nih.gov|access-date=2025-11-11}}</ref> ===== # Chem. Rev. (2022): “Self-Healing Injectable Hydrogels for Tissue Regeneration.” Authoritative review on self-healing hydrogels across tissues (mechanisms, design, limits). ACS Publications<ref>{{cite web|title=ACS Publications|url=https://pubs.acs.org/doi/10.1021/acs.chemrev.2c00179|publisher=ACS Publications|access-date=2025-11-11}}</ref> # Hyaluronic-acid self-healing injectable hydrogel in spinal cord injury (2024, preclinical). Demonstrates cavity filling and functional improvement in animal SCI models. PubMed<ref>{{cite web|title=PubMed|url=https://pubmed.ncbi.nlm.nih.gov/38408580/|publisher=pubmed.ncbi.nlm.nih.gov|access-date=2025-11-11}}</ref> # Adaptive conductive electrotherapeutic scaffold (2023, Med/Cell Press). Conductive, bioresorbable scaffold improved motor/sensory recovery after nerve repair in animal models; still not a one-shot cure. Cell<ref>{{cite web|title=Cell|url=https://www.cell.com/med/fulltext/S2666-6340%2823%2900165-4|publisher=cell.com|access-date=2025-11-11}}</ref> # Reviews on peripheral nerve repair hydrogels (2024–2025). Summarize emerging materials, mechanisms, and clinical hurdles; emphasize that human trials remain limited. PubMed<ref>{{cite web|title=PubMed|url=https://pubmed.ncbi.nlm.nih.gov/40225756/|publisher=pubmed.ncbi.nlm.nih.gov|access-date=2025-11-11}}</ref> ===== - MIT labs are contributing to injectable hydrogel science and nerve-repair technologies, but the specific social-media claim (“MIT made an injectable gel that regrows nerves and restores near-complete function”) doesn’t map to any peer-reviewed MIT publication or official MIT release I can locate. The closest real items are general hydrogel platform work, neural-repair biomaterials research, and a surgery-adjunct polymer from an MIT spinout—not a single curative injection. ===== If you want, I can pull full citations/PDFs for any of the items above (e.g., #6–#9) and give you a 1–2 paragraph lay summary for CRPS/neuropathic-pain relevance.
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