Controllable nanotopography of lysine-branched self-assembling peptide hydrogels for tendon-bone insertion regeneration

Xu Liu; Chenyu Wang; Xiao Zhao; Yi Xiao; Yuzhi Sun; Xin Zhang; Qingqiang Yao; Yilun Wu; Yi-shen Zhu

doi:10.1007/s44307-026-00111-0

Advanced Biotechnology ›› 2026, Vol. 4 ›› Issue (2) :22 DOI: 10.1007/s44307-026-00111-0

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Controllable nanotopography of lysine-branched self-assembling peptide hydrogels for tendon-bone insertion regeneration

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Abstract

Recent advances in tissue engineering have highlighted the critical roles of both mechanical and biochemical characteristics in tendon-bone insertion (TBI) regeneration. However, the influence of surface topography, particularly the development of biocompatible hydrogels with aligned nanotopographical structures while preserving intrinsic mechanical properties, remains insufficiently explored. Here, we engineered a lysine-branched self-assembling peptide hydrogels (Lys-SAPHs) to promote TBI healing. Compared with pristine SAPH, Lys-SAPHs exhibited distinctive aligned 3D groove-like topographies without compromising mechanical integrity or hemocompatibility. In vitro, Lys-SAPHs enhanced tendon stem cells (TSCs) and bone marrow mesenchymal stem cells (BMSCs) proliferation, migration, and tendonogenic differentiation, while promoting macrophage polarization toward a reparative M2 phenotype. In a rat TBI defect model, optimized Lys-SAPH (FEK17:FEK8 = 1:6) treatment facilitated superior tendon–bone regeneration, evidenced by reduced bone defect area on micro-CT, improved Achilles functional index (AFI), and increased fibrocartilage formation compared with SAPH and control groups. This study highlighted the critical role of nanotopography in directing stem cell fate and immune modulation and presented Lys-SAPHs as a versatile platform for designing next-generation self-assembling peptide hydrogels for tendon-bone repair and broader regenerative applications.

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Nanotopography / Tendon-bone insertion regeneration / Lysine-branched self-assembling peptide hydrogels / Macrophage polarization / Stem cell differentiation

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Xu Liu, Chenyu Wang, Xiao Zhao, Yi Xiao, Yuzhi Sun, Xin Zhang, Qingqiang Yao, Yilun Wu, Yi-shen Zhu. Controllable nanotopography of lysine-branched self-assembling peptide hydrogels for tendon-bone insertion regeneration. Advanced Biotechnology, 2026, 4(2): 22 DOI:10.1007/s44307-026-00111-0

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	APostolakos J, Durant TJ, Dwyer CR, Russell RP, Weinreb JH, Alaee F, Beitzel K, Mccarthy MB, Cote MP, Mazzocca AD. The enthesis: a review of the tendon-to-bone insertion. Muscles Ligaments Tendons J, 2014, 4: 333-342

[2]	Bi Y, Ehirchiou D, Kilts TM, Inkson CA, Embree MC, Sonoyama W, Li L, Leet AI, Seo B-M, Zhang L, Shi S, Young MF. Identification of tendon stem/progenitor cells and the role of the extracellular matrix in their niche. Nat Med, 2007, 13: 1219-1227

[3]	Cai C, Meng Z, Zhao L, Wu T, Xu X, Zhu Y. A self-assembled peptide hydrogel for wound repair. J Mater Sci, 2022, 57: 1345-1361

[4]	Chen S, Wang H, Mainardi VL, Talò G, Mccarthy A, John JV, Teusink MJ, Hong L, Xie J. Biomaterials with structural hierarchy and controlled 3D nanotopography guide endogenous bone regeneration. Sci Adv, 2021, 7 eabg3089

[5]	Chen R-Q, Liu P-J, Li S, He H-P, Li D-M, Yuan G-X, Du X-Y, Su J-Y, Deng Z-H, Xu J. Healing of tendon-related diseases: insights from macrophage regulation. Mil Med Res, 2025, 12: 45

[6]	Cheng M, Jiang Y, Wang Y, Wu Y, Zhu Y. Enhancing osteosarcoma therapy through aluminium hydroxide nanosheets-enabled macrophage modulation. Int J Pharm, 2024, 649 123640

[7]	Dede eren A, Vasilevich A, Eren ED, Sudarsanam P, Tuvshindorj U, De Boer J, Foolen J. Tendon-derived biomimetic surface topographies induce phenotypic maintenance of tenocytes in vitro. Tissue Eng Part A, 2020, 27: 1023-1036

[8]	Du Y, Guo JL, Wang J, Mikos AG, Zhang S. Hierarchically designed bone scaffolds: from internal cues to external stimuli. Biomaterials, 2019, 218 119334

[9]	He T, Qiao S, Ma C, Peng Z, Wu Z, Ma C, Han L, Deng Q, Zhang T, Zhu Y. FEK self‐assembled peptide hydrogels facilitate primary hepatocytes culture and pharmacokinetics screening. J Biomed Mater Res B Appl Biomater, 2022, 110: 2015-2027

[10]	Jang K-M, Lim HC, Jung WY, Moon SW, Wang JH. Efficacy and safety of human umbilical cord blood–derived mesenchymal stem cells in anterior cruciate ligament reconstruction of a rabbit model: new strategy to enhance tendon graft healing. Arthroscopy, 2015, 31: 1530-1539

[11]	Li J, Xing R, Bai S, Yan X. Recent advances of self-assembling peptide-based hydrogels for biomedical applications. Soft Matter, 2019, 15: 1704-1715

[12]	Li L, Li J, Guo J, Zhang H, Zhang X, Yin C, Wang L, Zhu Y, Yao Q. 3D molecularly functionalized cell-free biomimetic scaffolds for osteochondral regeneration. Adv Funct Mater, 2019, 29 1807356

[13]	López-serrano C, Rémy M, Leste-Lasserre T, Laroche G, Durrieu M-C. Unravelling the synergies: effects of hydrogel mechanics and biofunctionalization on mesenchymal stem cell osteogenic differentiation. Mater Adv, 2025, 6: 4646-4659

[14]	Luu TU, Gott SC, Woo BWK, Rao MP, Liu WF. Micro- and nanopatterned topographical cues for regulating macrophage cell shape and phenotype. ACS Appl Mater Interfaces, 2015, 7: 28665-28672

[15]	Millar NL, Murrell GAC, Mcinnes IB. Inflammatory mechanisms in tendinopathy – towards translation. Nat Rev Rheumatol, 2017, 13: 110-122

[16]	Murrell GA, Lilly EG, Davies H, Best TM, Goldner RD, Seaber AV. The Achilles functional index. J Orthop Res, 1992, 10: 398-404

[17]	Ni Q, Zhu J, Li Z, Li B, Wang H, Chen L. Simvastatin promotes rat Achilles tendon-bone interface healing by promoting osteogenesis and chondrogenic differentiation of stem cells. Cell Tissue Res, 2023, 391: 339-355

[18]	Qi GB, Gao YJ, Wang L, Wang H. Self‐assembled peptide‐based nanomaterials for biomedical imaging and therapy. Adv Mater, 2018, 30 1703444

[19]	Rodeo SA. Biologic augmentation of rotator cuff tendon repair. J Shoulder Elbow Surg, 2007, 16: S191-S197

[20]	Samitier G, Marcano AI, Alentorn-Geli E, Cugat R, Farmer KW, Moser MW. Failure of anterior cruciate ligament reconstruction. Arch Bone Jt Surg, 2015, 3: 220-240

[21]	Shavykin OV, Neelov IM, Borisov OV, Darinskii AA, Leermakers FAM. SCF theory of uniformly charged dendrimers: impact of asymmetry of branching, generation number, and salt concentration. Macromolecules, 2020, 53: 7298-7311

[22]	Sun, Y., Sheng, R., Cao, Z., Liu, C., Li, J., Zhang, P., Du, Y., Mo, Q., Yao, Q., Chen, J. & Zhang, W. Bioactive fiber-reinforced hydrogel to tailor cell microenvironment for structural and functional regeneration of myotendinous junction. Science Advances, 10, eadm7164.

[23]	Swanson WB, Omi M, Zhang Z, Nam HK, Jung Y, Wang G, Ma PX, Hatch NE, Mishina Y. Macropore design of tissue engineering scaffolds regulates mesenchymal stem cell differentiation fate. Biomaterials, 2021, 272 120769

[24]	Taşkesen, A., ATaoğlu, B., Özer, M., Demirkale, İ. & Turanli, S. 2015. Glucosamine-chondroitin sulphate accelerates tendon-to-bone healing in rabbits. Eklem Hastalik Cerrahisi, 26, 77–83.

[25]	Wang H, He K, Cheng C-K. The structure, biology, and mechanical function of tendon/ligament–bone interfaces. Tissue Eng Part B Rev, 2024, 30: 545-558

[26]

Wu, T., Wu, Y., Cao, Z., Zhao, L., LV, J., LI, J., XU, Y., Zhang, P., Liu, X., Sun, Y., Cheng, M., Tang, K., Jiang, X., Ling, C., Yao, Q. & Zhu, Y. 2023. Cell-free and cytokine-free self-assembling peptide hydrogel-polycaprolactone composite scaffolds for segmental bone defects. Biomaterials Science, 11, 840–853.

[27]	Yang C, Teng Y, Geng B, Xiao H, Chen C, Chen R, Yang F, Xia Y. Strategies for promoting tendon-bone healing: current status and prospects. Front Bioeng Biotechnol, 2023, 11 1118468

[28]	Ye Y-J, Xu Y-F, Hou Y-B, Yin D-C, Su D-B, Zhao Z-X. Regulation of tendon stem cell behavior by designed nanoporous topography of microfibers. Biomacromol, 2023, 24: 5859-5870

[29]	Zhu L, Luo D, Liu Y. Effect of the nano/microscale structure of biomaterial scaffolds on bone regeneration. Int J Oral Sci, 2020, 12: 6

[30]	Zhu, Y., Liang, H., Liu, X., Wu, J., Yang, C., Wong, T. M., Kwan, K. Y. H., Cheung, K. M. C., Wu, S. & Yeung, K. W. K. 2021. Regulation of macrophage polarization through surface topography design to facilitate implant-to-bone osteointegration. Science Advances, 7, eabf6654.