Find a Research Lab

Research Lab Results

Results per page:

  • Grayson Lab for Craniofacial and Orthopaedic Tissue Engineering

    The Grayson Lab focuses on craniofacial and orthopaedic tissue engineering. Our research addresses the challenges associated with spatio-temporal control of stem cell fate in order to engineer complex tissue constructs. We are developing innovative methods to guide stem cell differentiation patterns and create patient-specific grafts with functional biological and mechanical characteristics. We employ engineering techniques to accurately control growth factor delivery to cells in biomaterial scaffolds as well as to design advanced bioreactors capable of maintaining cell viability in large tissue constructs. These technologies are used to enable precise control of the cellular microenvironment and uniquely address fundamental questions regarding the application of biophysical cues to regulate stem cell differentiation.
    Lab Website

    Principal Investigator

    Warren L. Grayson, PhD

    Department

    Biomedical Engineering

  • Elisseeff Lab

    The mission of the Elisseeff Lab is to engineer technologies to repair lost tissues. We aim to bridge academic research and technology discovery to treat patients and address clinically relevant challenges related to tissue engineering. To accomplish this goal we are developing and enabling materials, studying biomaterial structure-function relationships and investigating mechanisms of tissue development to practically rebuild tissues. The general approach of tissue engineering is to place cells on a biomaterial scaffold that is designed to provide the appropriate signals to promote tissue development and ultimately restore normal tissue function in vivo. Understanding mechanisms of cellular interactions (both cell-cell and cell-material) and tissue development on scaffolds is critical to advancement of the field, particularly in applications employing stem cells. Translation of technologies to tissue-specific sites and diseased environments is key to better design, understanding, and ultimately efficacy of tissue repair strategies. We desire to translate clinically practical strategies, in the form of biomaterials/medical devices, to guide and enhance the body's natural capacity for repair. To accomplish the interdisciplinary challenge of regenerative medicine research, we maintain a synergistic balance of basic and applied/translational research.
    Lab Website

    Principal Investigator

    Jennifer Hartt Elisseeff, PhD

    Department

    Ophthalmology

  • Advanced Optics Lab

    The Advanced Optics Lab uses innovative optical tools, including laser-based nanotechnologies, to understand cell motility and the regulation of cell shape. We pioneered laser-based nanotechnologies, including optical tweezers, nanotracking, and laser-tracking microrheology. Applications range from physics, pharmaceutical delivery by phagocytosis (cell and tissue engineering), bacterial pathogens important in human disease and cell division. Other projects in the lab are related to microscopy, specifically combining fluorescence and electron microscopy to view images of the subcellular structure around proteins.
    Lab Website

    Principal Investigator

    Scot C. Kuo, PhD

    Department

    Biomedical Engineering

  • Kunisaki Lab

    The Kunisaki lab is a NIH-funded regenerative medicine group within the Division of General Pediatric Surgery at Johns Hopkins that works at the interface of stem cells, mechanobiology, and materials science. We seek to understand how biomaterials and mechanical forces affect developing tissues relevant to pediatric surgical disorders. To accomplish these aims, we take a developmental biology approach using induced pluripotent stem cells and other progenitor cell populations to understand the cellular and molecular mechanisms by which fetal organs develop in disease.

    Our lab projects can be broadly divided into three major areas: 1) fetal spinal cord regeneration 2) fetal lung development 3) esophageal regeneration

    Lab members: Juan Biancotti, PhD (Instructor/lab manager); Annie Sescleifer, MD (postdoc surgical resident); Kyra Halbert-Elliott (med student), Ciaran Bubb (undergrad)

    Recent publications:
    Kunisaki SM, Jiang G, Biancotti JC, Ho KKY, Dye BR, Liu AP, Spence JR. Human induced pluripotent stem cell-derived lung organoids in an ex vivo model of congenital diaphragmatic hernia fetal lung. Stem Cells Translational Medicine 2021, PMID: 32949227

    Biancotti JC, Walker KA, Jiang G, Di Bernardo J, Shea LD, Kunisaki SM. Hydrogel and neural progenitor cell delivery supports organotypic fetal spinal cord development in an ex vivo model of prenatal spina bifida repair. Journal of Tissue Engineering 2020, PMID: 32782773.

    Kunisaki SM. Amniotic fluid stem cells for the treatment of surgical disorders in the fetus and neonate. Stem Cells Translational Medicine 2018, 7:767-773

    Principal Investigator

    Shaun Michael Kunisaki, MD MSC

    Department

    Surgery

  • Borahay Lab: Gynecologic and Fibroids Research

    Dr. Borahay's lab focuses on understanding pathobiology, developing novel treatments, and carrying out high quality clinical trials for common gynecologic problems with a special focus on uterine fibroids. Our lab also investigates the causes and novel treatments for menstrual disorders such as heavy and irregular periods. In addition, Dr. Borahay’s team explores innovative approaches to minimally invasive gynecologic surgery, focusing on outpatient procedures with less pain and faster recovery times.
  • Laboratory for Fetal and Neonatal Organ Regeneration

    Researchers in the Laboratory for Fetal and Neonatal Organ Regeneration in the Department of Surgery at the Johns Hopkins School of Medicine are studying whether cellular reprogramming, stem cells, and ex vivo modeling can be applied to improve organ regeneration in pediatric surgical patients. To execute these aims, the lab collaborates with developmental biologists and biomedical engineers throughout the country and employs cutting-edge molecular strategies and pre-clinical animal models.

    Principal Investigator

    Shaun Michael Kunisaki, MD MSC

    Department

    Surgery

  • The Spinal Fusion Laboratory

    Five to 35 percent of spine fusionprocedures fail, even when using the gold standard treatment of grafting bone from the patient's own iliac crest. Fusion failure, otherwise known as pseudoarthrosis, is a major cause of failed back surgery syndrome (FBSS) and results in significant pain and disability, increasing the need for additional procedures and driving up health care costs. The ultimate goal of the Spinal Fusion Laboratory is to eliminate pseudoarthrosis by using animal models to study various strategies for improving spinal fusion outcomes, including delivery of various growth factors and biological agents; stem cell therapies and tissue engineering approaches.
    Lab Website

    Principal Investigator

    Timothy F. Witham, MD

    Department

    Neurosurgery