Development of a 3D Human Trabecular Meshwork Cell Culture System Using Natural Biopolymer Scaffolds

Information

  • Research Project
  • 9304410
  • ApplicationId
    9304410
  • Core Project Number
    R15EY027111
  • Full Project Number
    1R15EY027111-01A1
  • Serial Number
    027111
  • FOA Number
    PA-16-200
  • Sub Project Id
  • Project Start Date
    5/1/2017 - 7 years ago
  • Project End Date
    4/30/2020 - 4 years ago
  • Program Officer Name
    LIBERMAN, ELLEN S
  • Budget Start Date
    5/1/2017 - 7 years ago
  • Budget End Date
    4/30/2020 - 4 years ago
  • Fiscal Year
    2017
  • Support Year
    01
  • Suffix
    A1
  • Award Notice Date
    4/26/2017 - 7 years ago

Development of a 3D Human Trabecular Meshwork Cell Culture System Using Natural Biopolymer Scaffolds

Project Summary Aqueous humor outflow resistance is the primary determinant of intraocular pressure (IOP); increased outflow resistance is the basis for elevated IOP associated with glaucoma. In humans, IOP is primarily controlled by the outflow of the aqueous humor through the trabecular meshwork (TM). Researchers trying to screen new therapeutics for glaucoma, or elucidate TM cell behavior under various conditions, currently have the option of screening the response of TM cells cultured on flat two-dimensional plastic cell culture dishes, or screening the response of the TM using perfusion studies of donor eyes, which are expensive studies. Most in vitro studies of TM are over-simplified since there is a significant difference between the flat two-dimensional plastic surfaces on which the TM cells are traditionally cultured and the complex three- dimensional in vivo environment. The topographic features and biomechanic stresses present in vivo provide the cells with stimuli that influence their proliferation, migration, adhesion, and extracellular matrix (ECM) deposition. Our central hypothesis is that a novel constant flow perfusion system that utilizes a natural biopolymer scaffold with anisotropic pore structure to mimic more closely the trabecular meshwork cells' microenvironment can support TM cell growth and provide a platform that could be used for effective screening of various bioactive stimuli. From a biological and biomimetic point of view, natural polymers are desirable to use as biomaterial scaffolds, as their properties are very similar to the native ECM. Collagen, chondroitin sulfate (CS) and hyaluronic acid (HA) are the most predominant components of ECM of native TM. For this project, collagen-CS/HA scaffolds that have uniaxally aligned pores will be engineered to support TM cell growth. This proposal consists of three aims: (1) To determine the effect of hyaluronic acid and chondroitin sulfate on hTM cell growth and ECM production in our 3D collagen scaffolds; (2) To determine the influence of perfusion on the 3D hTM cell-seeded scaffolds; (3) To determine the effect of dexamethasone, TGF-?2, and Latrunculin B (Lat B) on the 3D hTM cell-seeded scaffolds under static and perfusion culture conditions. This 3D TM cell culture system will bring a huge advance to the field of glaucoma research and drug screening by establishing a system that allows the study of TM cells in an environment that more closely simulates their microenvironment, thus producing more physiologically relevant data. The potential impact this could ultimately have on patients is immense, as there are nearly 70 million people in the world that suffer from glaucoma. Furthermore, this research will provide exposure of graduate and undergraduate students to biomedical research at a university without an established bioengineering or biology department that has been traditionally focused on earth and energy sciences.

IC Name
NATIONAL EYE INSTITUTE
  • Activity
    R15
  • Administering IC
    EY
  • Application Type
    1
  • Direct Cost Amount
    311881
  • Indirect Cost Amount
    107720
  • Total Cost
    419601
  • Sub Project Total Cost
  • ARRA Funded
    False
  • CFDA Code
    867
  • Ed Inst. Type
    SCHOOLS OF ARTS AND SCIENCES
  • Funding ICs
    NEI:419601\
  • Funding Mechanism
    Non-SBIR/STTR RPGs
  • Study Section
    ZRG1
  • Study Section Name
    Special Emphasis Panel
  • Organization Name
    COLORADO SCHOOL OF MINES
  • Organization Department
    ENGINEERING (ALL TYPES)
  • Organization DUNS
    010628170
  • Organization City
    GOLDEN
  • Organization State
    CO
  • Organization Country
    UNITED STATES
  • Organization Zip Code
    804011887
  • Organization District
    UNITED STATES