Research progress on optimization strategies for adipose-derived stem cells therapy in chronic wounds

doi:10.3877/cma.j.issn.1673-9450.2025.05.014

Abstract

Abstract:

With the aging of the global population，the incidence of chronic wounds （such as diabetic foot ulcers，pressure injuries，venous ulcers） is increasing year by year，which has become a major challenge in clinical management，seriously compromising patient quality of life and imposing a heavy burden on the healthcare system. In recent years，adipose-derived stem cells （ADSCs） have shown great potential in the field of chronic wound therapy. However，the complex microenvironment of the wound seriously affects the survival and function of ADSCs. To address this challenge，a variety of optimization strategies have emerged. This article focuses on strategies to enhance the therapeutic efficacy of ADSCs for chronic wound treatment，systematically reviewing recent research progress in different treatment strategies，including various pretreatment methods，combination therapies with cytokines，and co-delivery systems utilizing biomaterials and tissue engineering. Furthermore, it critically analyzes the underlying mechanisms，unique advantages，and limitations of each strategy，aiming to provide a reference for advancing the clinical translation of ADSCs in chronic wound therapy.

Key words: Wound healing, Tissue engineering, Regenerative medicine, Adipose-derived stem cells, Pretreatment

Danna Yao, Yujie Xiao, Rongqin Feng, Panpan Sun, Lai Wei, Hongtao Wang. Research progress on optimization strategies for adipose-derived stem cells therapy in chronic wounds[J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2025, 20(05): 447-451.

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URL: https://zhssyxfzz.cma-cmc.com.cn/EN/10.3877/cma.j.issn.1673-9450.2025.05.014

https://zhssyxfzz.cma-cmc.com.cn/EN/Y2025/V20/I05/447

References 44

［1］	Sun H，Saeedi P，Karuranga S，et al. IDF Diabetes Atlas： global，regional and country-level diabetes prevalence estimates for 2021 and projections for 2045［J］. Diabetes Res Clin Pract，2022，183： 109119.
［2］	Wang Y，Wang C，Zheng L. Bibliometric analysis of systematic review and meta-analysis on diabetic foot ulcer［J］. Heliyon，2024，10（6）： e27534.
［3］	Peña OA，Martin P. Cellular and molecular mechanisms of skin wound healing［J］. Nat Rev Mol Cell Biol，2024，25（8）： 599-616.
［4］	Veith AP，Henderson K，Spencer A，et al. Therapeutic strategies for enhancing angiogenesis in wound healing［J］. Adv Drug Deliv Rev，2019，146： 97-125.
［5］	Tyeb S，Shiekh PA，Verma V，et al. Adipose-derived stem cells （ADSCs） loaded gelatin-sericin-laminin cryogels for tissue regeneration in diabetic wounds［J］. Biomacromolecules，2020，21（2）： 294-304.
［6］	Kocan B，Maziarz A，Tabarkiewicz J，et al. Trophic activity and phenotype of adipose tissue-derived mesenchymal stem cells as a background of their regenerative potential［J］. Stem Cells Int，2017，2017： 1653254.
［7］	Gandolfi S，Sanouj A，Chaput B，et al. The role of adipose tissue-derived stromal cells，macrophages and bioscaffolds in cutaneous wound repair［J］. Biol Direct，2024，19（1）： 85.
［8］	An Y，Lin S，Tan X，et al. Exosomes from adipose-derived stem cells and application to skin wound healing［J］. Cell Prolif，2021，54（3）： e12993.
［9］	Hu Y，Tao R，Chen L，et al. Exosomes derived from pioglitazone-pretreated MSCs accelerate diabetic wound healing through enhancing angiogenesis［J］. J Nanobiotechnology，2021，19（1）： 150.
［10］	Li Y，Xiao Y，Shang Y，et al. Exosomes derived from adipose tissue-derived stem cells alleviated H₂O₂-induced oxidative stress and endothelial-to-mesenchymal transition in human umbilical vein endothelial cells by inhibition of the mir-486-3p/Sirt6/Smad signaling pathway［J］. Cell Biol Toxicol，2024，40（1）： 39.
［11］	Dong Y，Zhang Y，Li F，et al. GKT137831 in combination with adipose-derived stem cells alleviates high glucose-induced inflammaging and improves diabetic wound healing［J］. J Leukoc Biol，2024，115（5）： 882-892.
［12］	Li S，Li Y，Wu Z，et al. Diabetic ferroptosis plays an important role in triggering on inflammation in diabetic wound［J］. Am J Physiol Endocrinol Metab，2021，321（4）： E509-E520.
［13］	Kakudo N，Morimoto N，Ogawa T，et al. Hypoxia enhances proliferation of human adipose-derived stem cells via HIF-1ɑ activation［J］. PLoS One，2015，10（10）： e0139890.
［14］	Li S，Sun J，Yang J，et al. Gelatin methacryloyl （GelMA） loaded with concentrated hypoxic pretreated adipose-derived mesenchymal stem cells（ADSCs） conditioned medium promotes wound healing and vascular regeneration in aged skin［J］. Biomater Res，2023，27（1）： 11.
［15］	Zhao Y，Zhang M，Lu GL，et al. Hypoxic preconditioning enhances cellular viability and pro-angiogenic paracrine activity： the roles of VEGF-A and SDF-1a in rat adipose stem cells［J］. Front Cell Dev Biol，2020，8： 580131.
［16］	Wang J，Wu H，Peng Y，et al. Hypoxia adipose stem cell-derived exosomes promote high-quality healing of diabetic wound involves activation of PI3K/Akt pathways［J］. J Nanobiotechnology，2021，19（1）： 202.
［17］	Hu N，Cai Z，Jiang X，et al. Hypoxia-pretreated ADSC-derived exosome-embedded hydrogels promote angiogenesis and accelerate diabetic wound healing［J］. Acta Biomater，2023，157： 175-186.
［18］	He J，Fang B，Shan S，et al. Mechanical stretch promotes hypertrophic scar formation through mechanically activated cation channel Piezo1［J］. Cell Death Dis，2021，12（3）： 226.
［19］	Xue Z，Hu D，Tang H，et al. Mechanical force regulates the paracrine functions of ADSCs to assist skin expansion in rats［J］. Stem Cell Res Ther，2024，15（1）： 250.
［20］	He J，Shan S，Jiang T，et al. Mechanical stretch preconditioned adipose-derived stem cells elicit polarization of anti-inflammatory M2-like macrophages and improve chronic wound healing［J］. FASEB J，2024，38（10）： e23626.
［21］	Fang B，Liu Y，Zheng D，et al. The effects of mechanical stretch on the biological characteristics of human adipose-derived stem cells［J］. J Cell Mol Med，2019，23（6）： 4244-4255.
［22］	Maziarz A，Kocan B，Bester M，et al. How electromagnetic fields can influence adult stem cells： positive and negative impacts［J］. Stem Cell Res Ther，2016，7（1）： 54.
［23］	Sendera A，Pikuła B，Banaś-Ząbczyk A. Preconditioning of pesenchymal stem cells with electromagnetic fields and its impact on biological responses and "fate"-potential use in therapeutic applications［J］. Front Biosci （Landmark Ed），2023，28（11）： 285.
［24］	Zerillo L，Coletta CC，Madera JR，et al. Extremely low frequency-electromagnetic fields promote chondrogenic differentiation of adipose-derived mesenchymal stem cells through a conventional genetic program［J］. Sci Rep，2024，14（1）： 10182.
［25］	Tao Z，Liu L，Wu M，et al. Metformin promotes angiogenesis by enhancing VEGFa secretion by adipose-derived stem cells via the autophagy pathway［J］. Regen Biomater，2023，10： rbad043.
［26］	Li S，Zhao C，Shang G，et al. α-ketoglutarate preconditioning extends the survival of engrafted adipose-derived mesenchymal stem cells to accelerate healing of burn wounds［J］. Exp Cell Res，2024，439（1）： 114095.
［27］	Cremers NA，Lundvig DM，van Dalen SC，et al. Curcumin-induced heme oxygenase-1 expression prevents H₂O₂-induced cell death in wild type and heme oxygenase-2 knockout adipose-derived mesenchymal stem cells［J］. Int J Mol Sci，2014，15（10）： 17974-17999.
［28］	Azam M，Ghufran H，Butt H，et al. Curcumin preconditioning enhances the efficacy of adipose-derived mesenchymal stem cells to accelerate healing of burn wounds［J］. Burns Trauma，2021，9： tkab021.
［29］	Liao N，Shi Y，Zhang C，et al. Antioxidants inhibit cell senescence and preserve stemness of adipose tissue-derived stem cells by reducing ROS generation during long-term in vitro expansion［J］. Stem Cell Res Ther，2019，10（1）： 306.
［30］	Levy O，Kuai R，Siren EMJ，et al. Shattering barriers toward clinically meaningful MSC therapies［J］. Sci Adv，2020，6（30）： eaba6884.
［31］	Srifa W，Kosaric N，Amorin A，et al. Cas9-AAV6-engineered human mesenchymal stromal cells improved cutaneous wound healing in diabetic mice［J］. Nat Commun，2020，11（1）： 2470.
［32］	Lopez-Yus M，García-Sobreviela MP，Del Moral-Bergos R，et al. Gene therapy based on mesenchymal stem cells derived from adipose tissue for the treatment of obesity and its metabolic complications［J］. Int J Mol Sci，2023，24（8）： 7468.
［33］	Xu J，Liu X，Zhao F，et al. HIF1α overexpression enhances diabetic wound closure in high glucose and low oxygen conditions by promoting adipose-derived stem cell paracrine function and survival［J］. Stem Cell Res Ther，2020，11（1）： 148.
［34］	Song S，Zhang G，Chen X，et al. HIF-1α increases the osteogenic capacity of ADSCs by coupling angiogenesis and osteogenesis via the HIF-1α/VEGF/AKT/mTOR signaling pathway［J］. J Nanobiotechnology，2023，21（1）： 257.
［35］	Li Y，Li D，You L，et al. dCas9-based PDGFR-β activation ADSCs accelerate wound healing in diabetic mice through angiogenesis and ECM remodeling［J］. Int J Mol Sci，2023，24（6）： 5949.
［36］	Kim MH，Hong HN，Hong JP，et al. The effect of VEGF on the myogenic differentiation of adipose tissue derived stem cells within thermosensitive hydrogel matrices［J］. Biomaterials，2010，31（6）： 1213-1218.
［37］	Ebrahim N，Dessouky AA，Mostafa O，et al. Adipose mesenchymal stem cells combined with platelet-rich plasma accelerate diabetic wound healing by modulating the Notch pathway［J］. Stem Cell Res Ther，2021，12（1）： 392.
［38］	Leong J，Hong YT，Wu YF，et al. Surface tethering of inflammation-modulatory nanostimulators to stem cells for ischemic muscle repair［J］. ACS Nano，2020，14（5）： 5298-5313.
［39］	Brizio M，Mancini M，Lora M，et al. Cytokine priming enhances the antifibrotic effects of human adipose derived mesenchymal stromal cells conditioned medium［J］. Stem Cell Res Ther，2024，15（1）： 329.
［40］	Wang P，Cai F，Li Y，et al. Emerging trends in the application of hydrogel-based biomaterials for enhanced wound healing： a literature review［J］. Int J Biol Macromol，2024，261（Pt 1）： 129300.
［41］	Sridhar R，Lakshminarayanan R，Madhaiyan K，et al. Electrosprayed nanoparticles and electrospun nanofibers based on natural materials： applications in tissue regeneration，drug delivery and pharmaceuticals［J］. Chem Soc Rev，2015，44（3）： 790-814.
［42］	Kong W，Bao Y，Li W，et al. Collaborative enhancement of diabetic wound healing and skin regeneration by recombinant human collagen hydrogel and hADSCs［J］. Adv Healthc Mater，2024，13（29）： e2401012.
［43］	Tang Y，Tong X，Conrad B，et al. Injectable and in situ crosslinkable gelatin microribbon hydrogels for stem cell delivery and bone regeneration in vivo［J］. Theranostics，2020，10（13）： 6035-6047.
［44］	Sun Y，Li Y，Ding X，et al. An NIR-responsive hydrogel loaded with polydeoxyribonucleotide nano-vectors for enhanced chronic wound healing［J］. Biomaterials，2025，314： 122789.

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