Rhima M Coleman, PhD
Associate Professor of Orthopaedic Surgery
Associate Professor of Biomedical Engineering

Available to mentor
Rhima M Coleman, PhD
Associate Professor
  • About
  • Qualifications
  • Center Memberships
  • Research Overview
  • Recent Publications
    • About

    Articular cartilage lines the surface of long bones in joints and facilitates joint motion with a nearly frictionless surface that allows the bones to slide against one another. Traumatic cartilage injuries have a limited capacity to heal without medical intervention and can result in debilitating diseases, such as osteoarthritis, which are marked loss of mobility of the affected joint. Tissue engineering is a viable treatment option to repair these injuries. Development of a functional replacement for cartilage ultimately involves manipulating cell behavior so that the correct extracellular matrix (ECM) proteins are assembled and maintained at physiologic ratios and distributions to produce a biological tissue that closely matches native cartilage in its load bearing capacity. My research is focused on investigation 2 key areas of manipulating cell behavior for cartilage tissue regeneration: 1) genetic reprogramming of cells; and 2) cell-matrix interactions.

    Qualifications
    • PhD, Bioengineering
      Georgia Institute of Technology, Atlanta, 2007
    • MS, Mechanical Engineering
      Georgia Institute of Technology, Atlanta, 2003
    • BS, Mechanical Engineering
      University of Rochester, Rochester, 1999
    Center Memberships
    • Center Member
      Biosciences Initiative
    • Center Member
      Center for Cell Plasticity and Organ Design
    Research Overview

    Tissue Engineering and Biomaterials
    Tissue Engineering and Regenerative Medicine

    Recent Publications See All Publications
    • Journal Article
      Osteoporosis GWAS-implicated DNM3 locus contextually regulates osteoblastic and chondrogenic fate of mesenchymal stem/progenitor cells through oscillating miR-199a-5p levels.
      Kaur G, Pippin JA, Chang S, Redmond J, Chesi A, Wells AD, Maerz T, Grant SFA, Coleman RM, Hankenson KD, Wagley Y. JBMR Plus, 2024 May; 8 (5): ziae051 DOI:10.1093/jbmrpl/ziae051
      PMID: 38686038
    • Journal Article
      Modular, Vascularized Hypertrophic Cartilage Constructs for Bone Tissue Engineering Applications
      Kaur G, Schott N, Coleman RM, Stegemann J. BioRxiv, DOI:10.1101/2024.02.26.582166
    • Journal Article
      A synthetic, closed-looped gene circuit for the autonomous regulation of RUNX2 activity during chondrogenesis.
      Kaur G, Wu B, Murali S, Lanigan T, Coleman RM. FASEB J, 2024 Feb 29; 38 (4): e23484 DOI:10.1096/fj.202300348RR
      PMID: 38407380
    • Journal Article
      Cartilage thickness mismatches in patellar osteochondral allograft transplants affect local cartilage stresses.
      Rosario R, Arruda EM, Grant JA, Coleman RM. J Orthop Res, 2023 Nov; 41 (11): 2372 - 2383. DOI:10.1002/jor.25569
      PMID: 37031360
    • Journal Article
      Injectable Methacrylated Gelatin Hydrogel for Safe Sodium Hypochlorite Delivery in Endodontics.
      Dal-Fabbro R, Huang Y-C, Toledo PTA, Capalbo LC, Coleman RM, Sasaki H, Fenno JC, Bottino MC. Gels, 2023 Nov 13; 9 (11): DOI:10.3390/gels9110897
      PMID: 37998987
    • Presentation
      Autonomous RUNX2 Suppression in Engineered Cartilage
      Coleman RM. 2023 Oct;
    • Journal Article
      Ligand Composition and Coating Density Co-Modulate the Chondrocyte Function on Poly(glycerol-dodecanedioate).
      Qin Y, Coleman RM. J Funct Biomater, 2023 Sep 11; 14 (9): DOI:10.3390/jfb14090468
      PMID: 37754882
    • Presentation
      Anti-Hypertrophic and Anti-Inflammatory Effects of Autonomous RUNX2 Suppression in Engineered Cartilage
      Coleman RM. 2023 Jun;