Delivery of monocyte lineage cells in a biomimetic scaffold enhances tissue repair
Michael S. Hu, Graham G. Walmsley, Leandra A. Barnes, Kipp Weiskopf, Robert C. Rennert, Dominik Duscher, Michael Januszyk, Zeshaan N. Maan, Wan Xing Hong, Alexander T.M. Cheung, Tripp Leavitt, Clement D. Marshall, Ryan C. Ransom, Samir Malhotra, Alessandra L. Moore, Jayakumar Rajadas, H. Peter Lorenz, Irving L. Weissman, Geoffrey C. Gurtner, Michael T. Longaker
Michael S. Hu, Graham G. Walmsley, Leandra A. Barnes, Kipp Weiskopf, Robert C. Rennert, Dominik Duscher, Michael Januszyk, Zeshaan N. Maan, Wan Xing Hong, Alexander T.M. Cheung, Tripp Leavitt, Clement D. Marshall, Ryan C. Ransom, Samir Malhotra, Alessandra L. Moore, Jayakumar Rajadas, H. Peter Lorenz, Irving L. Weissman, Geoffrey C. Gurtner, Michael T. Longaker
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Research Article Therapeutics

Delivery of monocyte lineage cells in a biomimetic scaffold enhances tissue repair

Abstract

The monocyte lineage is essential to normal wound healing. Macrophage inhibition or knockout in mice results in impaired wound healing through reduced neovascularization, granulation tissue formation, and reepithelialization. Numerous studies have either depleted macrophages or reduced their activity in the context of wound healing. Here, we demonstrate that by increasing the number of macrophages or monocytes in the wound site above physiologic levels via pullulan-collagen composite dermal hydrogel scaffold delivery, the rate of wound healing can be significantly accelerated in both wild-type and diabetic mice, with no adverse effect on the quality of repair. Macrophages transplanted onto wounds differentiate into M1 and M2 phenotypes of different proportions at various time points, ultimately increasing angiogenesis. Given that monocytes can be readily isolated from peripheral blood without in vitro manipulation, these findings hold promise for translational medicine aimed at accelerating wound healing across a broad spectrum of diseases.

Authors

Michael S. Hu, Graham G. Walmsley, Leandra A. Barnes, Kipp Weiskopf, Robert C. Rennert, Dominik Duscher, Michael Januszyk, Zeshaan N. Maan, Wan Xing Hong, Alexander T.M. Cheung, Tripp Leavitt, Clement D. Marshall, Ryan C. Ransom, Samir Malhotra, Alessandra L. Moore, Jayakumar Rajadas, H. Peter Lorenz, Irving L. Weissman, Geoffrey C. Gurtner, Michael T. Longaker

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Figure 3

Transcriptional response of transplanted macrophages.

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Transcriptional response of transplanted macrophages. (A) Hierarchical c...
(A) Hierarchical clustering of cells from culture (left; red) and 24 hours after seeding onto hydrogel and placement onto wound (right; green). Gene expression is presented as fold change from median on a color scale from yellow (high expression, 32-fold above median) to blue (low expression, 32-fold below median), with gray indicating no expression. See Supplemental Figure 4 for the complete data set. (B) Differentially expressed genes between culture and wound macrophages identified using nonparametric two sample Kolmogorov-Smirnov testing. Thirty-seven genes exhibited significantly different (P < 0.05) distributions of single-cell expression between populations, with selected acute-phase reactants and M1/M2 markers illustrated here using median-centered Gaussian curve fits. The left vertical bar for each panel represents the fraction of qPCR reactions that failed to amplify in each group.