Lymphatic Drainage-Promoting Effects by Engraftment of Artificial Lymphatic Vascular Tissue Based on Human Adipose Tissue-Derived Mesenchymal Stromal Cells in Mice

Regenerative medicine using lymphatic vascular engineering is a promising approach for treating lymphedema. However, its development lags behind that of artificial blood vascular tissue for ischemic diseases. In this study, we constructed artificial 3D lymphatic vascular tissue, termed ASCLT, by co-cultivation of ECM-nanofilm-coated human adipose tissue-derived mesenchymal stromal cells (hASCs) and human dermal lymphatic endothelial cells (HDLECs). The effect of hASCs in lymphatic vessel network formation was evaluated by comparison with the tissue based on fibroblasts, termed FbLT. Our results showed that the density of lymphatic vascular network in ASCLT was higher than that in FbLT, demonstrating a promoting effect of hASCs on lymphatic vascular formation. This result was also supported by higher levels of lymphangiogenesis-promoting factors, such as bFGF, HGF, and VEGF-A in ASCLT than in FbLT. To evaluate the therapeutic effects, FbLTs and ASCLTs were subcutaneously transplanted to mouse hindlimb lymphatic drainage interruption models by removal of popliteal and subiliac lymph nodes. Despite the restricted engraftment of lymphatic vessels, ASCLT promoted regeneration of irregular and diverse lymphatic drainage in the skin, as visualized by indocyanine green imaging. Moreover, transplantation of ASCLT to the popliteal lymph node resection area also resulted in lymphatic drainage regeneration. Histological analysis of the generated drainage visualized by FITC-dextran injection revealed that the drainage was localized in the subcutaneous area shallower than the dermal muscle. These findings demonstrate that ASCLT promotes lymphatic drainage in vivo and that hASCs can serve as an autologous source for treatment of secondary lymphedema by tissue engineering.

[1]  I. Choi,et al.  Review of the Current Research on Fetal Bovine Serum and the Development of Cultured Meat , 2022, Food science of animal resources.

[2]  W. Rozen,et al.  Anatomical differences in the abdominal wall between animal species with implications for the transversus abdominis plane block: a systematic review , 2022, Surgical and Radiologic Anatomy.

[3]  E. Riedel,et al.  TGF‐β1 mediates pathologic changes of secondary lymphedema by promoting fibrosis and inflammation , 2022, Clinical and translational medicine.

[4]  Y. Zheng,et al.  Angiopoietin-2-induced lymphatic endothelial cell migration drives lymphangiogenesis via the β1 integrin-RhoA-formin axis , 2022, Angiogenesis.

[5]  A. Quiñones‐Hinojosa,et al.  Use of adipose-derived stem cells in lymphatic tissue engineering and regeneration , 2021, Archives of plastic surgery.

[6]  Eduardo A. Silva,et al.  Isolating and Characterizing Lymphatic Endothelial Progenitor Cells for Potential Therapeutic Lymphangiogenic Applications. , 2021, Acta biomaterialia.

[7]  A. Archilla,et al.  Matrix stiffness primes lymphatic tube formation directed by vascular endothelial growth factor‐C , 2021, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[8]  S. Uemura,et al.  GATA2 participates in the recanalization of lymphatic vessels after surgical lymph node extirpation , 2021, Genes to cells : devoted to molecular & cellular mechanisms.

[9]  S. Hanson,et al.  Tissue Engineering Strategies for Cancer-Related Lymphedema. , 2021, Tissue engineering. Part A.

[10]  M. Matsusaki,et al.  Construction of transplantable artificial vascular tissue based on adipose tissue-derived mesenchymal stromal cells by a cell coating and cryopreservation technique , 2021, Scientific Reports.

[11]  R. Gornati,et al.  Paracrine effect of human adipose-derived stem cells on lymphatic endothelial cells. , 2020, Regenerative medicine.

[12]  X. J. D. Janse de Jonge,et al.  Manual lymphatic drainage treatment for lymphedema: a systematic review of the literature , 2020, Journal of Cancer Survivorship.

[13]  W. Rasband,et al.  Angiogenesis Analyzer for ImageJ — A comparative morphometric analysis of “Endothelial Tube Formation Assay” and “Fibrin Bead Assay” , 2020, Scientific Reports.

[14]  L. Baptista Adipose stromal/stem cells in regenerative medicine: Potentials and limitations. , 2020, World journal of stem cells.

[15]  A. Walch,et al.  Patch repair of deep wounds by mobilized fascia , 2019, Nature.

[16]  Tingting Dai,et al.  IL‐7 enhances the differentiation of adipose‐derived stem cells toward lymphatic endothelial cells through AKT signaling , 2019, Cell biology international.

[17]  Donny Hanjaya-Putra,et al.  Lymphatic Tissue Engineering and Regeneration , 2018, Journal of Biological Engineering.

[18]  Liqun He,et al.  Matrix stiffness controls lymphatic vessel formation through regulation of a GATA2-dependent transcriptional program , 2018, Nature Communications.

[19]  D. Sheppard,et al.  TGF-β1 Signaling and Tissue Fibrosis. , 2018, Cold Spring Harbor perspectives in biology.

[20]  M. Matsusaki,et al.  Transplantation of artificial human lymphatic vascular tissues fabricated using a cell‐accumulation technique and their engraftment in mouse tissue with vascular remodelling , 2018, Journal of tissue engineering and regenerative medicine.

[21]  M. Cheng,et al.  Vascularized Lymph Node Transfer for Lymphedema , 2018, Seminars in Plastic Surgery.

[22]  U. Marx,et al.  Engineering Blood and Lymphatic Microvascular Networks in Fibrin Matrices , 2017, Front. Bioeng. Biotechnol..

[23]  M. Gonzalez-Garza,et al.  Regenerative capacity of autologous stem cell transplantation in elderly: a report of biomedical outcomes. , 2017, Regenerative medicine.

[24]  T. Drewa,et al.  Adipose-Derived Stem Cells as a Tool in Cell-Based Therapies , 2016, Archivum Immunologiae et Therapiae Experimentalis.

[25]  G. Finkenzeller,et al.  Adipose‐Derived Stem Cells Support Lymphangiogenic Parameters In Vitro , 2016, Journal of cellular biochemistry.

[26]  C. Twelves,et al.  Breast cancer-related lymphoedema and venepuncture: a review and evidence-based recommendations , 2015, Breast Cancer Research and Treatment.

[27]  H. Yoshimoto,et al.  Adipose-derived stem cell transplantation for therapeutic lymphangiogenesis in a mouse secondary lymphedema model. , 2015, Regenerative medicine.

[28]  G. Secker,et al.  VEGFR signaling during lymphatic vascular development: From progenitor cells to functional vessels , 2015, Developmental dynamics : an official publication of the American Association of Anatomists.

[29]  A. Seifalian,et al.  Tissue-engineered lymphatic graft for the treatment of lymphedema. , 2014, The Journal of surgical research.

[30]  Hao Wu,et al.  Temporal and spatial regulation of epsin abundance and VEGFR3 signaling are required for lymphatic valve formation and function , 2014, Science Signaling.

[31]  E. Sevick-Muraca,et al.  Spatio-Temporal Changes of Lymphatic Contractility and Drainage Patterns following Lymphadenectomy in Mice , 2014, PloS one.

[32]  M. Matsusaki,et al.  Ultrastructure of blood and lymphatic vascular networks in three-dimensional cultured tissues fabricated by extracellular matrix nanofilm-based cell accumulation technique. , 2014, Microscopy.

[33]  M. Matsusaki,et al.  Effects of angiogenic factors and 3D-microenvironments on vascularization within sandwich cultures. , 2014, Biomaterials.

[34]  R. Brekken,et al.  Vascular Endothelial Growth Factor Receptor-2 Promotes the Development of the Lymphatic Vasculature , 2013, PloS one.

[35]  F. Laco,et al.  Collagen-nanofiber hydrogel composites promote contact guidance of human lymphatic microvascular endothelial cells and directed capillary tube formation. , 2013, Journal of biomedical materials research. Part A.

[36]  D. Vittet,et al.  TGFβ1 inhibits lymphatic endothelial cell differentiation from mouse embryonic stem cells , 2012, Journal of cellular physiology.

[37]  G. Secker,et al.  In Vitro Assays Using Primary Embryonic Mouse Lymphatic Endothelial Cells Uncover Key Roles for FGFR1 Signalling in Lymphangiogenesis , 2012, PloS one.

[38]  B. Mehrara,et al.  Adipose-derived stem cells promote lymphangiogenesis in response to VEGF-C stimulation or TGF-β1 inhibition. , 2011, Future oncology.

[39]  F. Spinella,et al.  Endothelin-1 stimulates lymphatic endothelial cells and lymphatic vessels to grow and invade. , 2009, Cancer research.

[40]  B. Mehrara,et al.  TGF-beta1 is a negative regulator of lymphatic regeneration during wound repair. , 2008, American journal of physiology. Heart and circulatory physiology.

[41]  I. Koshima,et al.  Treatment of lymphedema with lymphaticovenular anastomoses , 2005, International Journal of Clinical Oncology.

[42]  S. Hirakawa,et al.  Hepatocyte growth factor promotes lymphatic vessel formation and function , 2005, The EMBO journal.

[43]  K. Alitalo,et al.  Angiopoietin-1 promotes LYVE-1-positive lymphatic vessel formation. , 2005, Blood.

[44]  G. Garcı́a-Cardeña,et al.  Dose-dependent response of FGF-2 for lymphangiogenesis. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[45]  P. Bohlen,et al.  VEGF‐A promotes tissue repair‐associated lymphatic vessel formation via VEGFR‐2 and the α1β1 and α2β1 integrins , 2004 .

[46]  M. Skobe,et al.  Structure, function, and molecular control of the skin lymphatic system. , 2000, The journal of investigative dermatology. Symposium proceedings.

[47]  Emily A. Margolis,et al.  Design principles for lymphatic drainage of fluid and solutes from collagen scaffolds. , 2018, Journal of biomedical materials research. Part A.

[48]  M. Lagunoff,et al.  Isolation and characterization of circulating lymphatic endothelial colony forming cells. , 2016, Experimental cell research.