The lab’s assets include three MRI systems available for pediatric studies, cardiac imaging processing, cardiovascular imaging and therapeutic ultrasound. A robust echocardiogram program conducts 10,000 transthoracic echocardiograms and 1,300 fetal echocardiograms per year, and maintains a database with 10 years of data.

In conjunction with the Molecular Imaging Center, the Center for Infection and Inflammation Imaging Research core provides state-of-the art small animal imaging equipment, including PET, SPECT, CT and US, to support the wide range of scientific projects within the diverse research community of the Johns Hopkins University and beyond. Trained technologists assist investigators in the use of these facilities.

Research in the Biophotonics Imaging Technologies (BIT) Laboratory focuses on developing optical imaging and nano-biophotonics technology to reduce the random sampling errors in clinical diagnosis, improve early disease detection and guidance of biopsy and interventions, and improve targeted therapy and monitoring treatment outcomes. The imaging technologies feature nondestructiveness, unique functional and molecular specificity, and multi-scale resolution (from organ, to architectural morphology, cellular, subcellular and molecular level). The nano-biophotonics technologies emphasize heavily on biocompatibility, multi-function integration and fast track clinical translation. These imaging and nano-biophotonics technologies can also be potentially powerful tools for basic research such as for drug screening, nondestructive assessment of engineered biomaterials in vitro and in vivo, and for studying brain functions on awake animals under normal or controlled social conditions.

Dr. Bhujwalla’s lab promotes preclinical and clinical multimodal imaging applications to understand and effectively treat cancer. The lab’s work is dedicated to the applications of molecular imaging to understand cancer and the tumor environment. Significant research contributions include 1) developing ‘theranostic agents’ for image-guided targeting of cancer, including effective delivery of siRNA in combination with a prodrug enzyme 2) understanding the role of inflammation and cyclooxygenase-2 (COX-2) in cancer using molecular and functional imaging 3) developing noninvasive imaging techniques to detect COX-2 expressing in tumors 4) understanding the role of hypoxia and choline pathways to reduce the stem-like breast cancer cell burden in tumors 5) using molecular and functional imaging to understand the role of the tumor microenvironment including the extracellular matrix, hypoxia, vascularization, and choline phospholipid metabolism in prostate and breast cancer invasion and metastasis, with the ultimate goal of preventing cancer metastasis and 6) molecular and functional imaging characterization of cancer-induced cachexia to understand the cachexia-cascade and identify novel targets in the treatment of this condition.

Research in the Quantitative Imaging Technologies lab — a component of the Imaging for Surgery, Therapy and Radiology (I-STAR) Lab — focuses on novel technologies to derive accurate structural and physiological measurements from medical images. Our team works on optimization of imaging systems and algorithms to support a variety of quantitative applications, with recent focus on orthopedics and bone health. For example, we have developed an ultra-high resolution imaging chain for an orthopedic CT system to enable in-vivo measurements of bone microstructure. Our interests also include automated methods to extract quantitative information from images, including anatomical and micro-structural measurements, and shape analysis.

The neuroimaging and Modulation Laboratory (NIMLAB) investigates neural correlates of cognition and behavior using neuroimaging methods such as functional magnetic resonance imaging (fMRI) and neuromodulation techniques such as transcranial magnetic stimulation (TMS). We are looking in depth at the contributions of the cerebellum and cerebro-cerebellar circuits to cognition; the effects of chronic heavy alcohol consumption on cognition and brain activation underlying cognitive function; how aging in humans affects neural systems that are important for associative learning and stimulus awareness; and the integration of transcranial magnetic stimulation with functional MRI.

The In-vivo Cellular and Molecular Imaging Center conducts multidisciplinary research on cellular and molecular imaging related to cancer. We provide resources, such as consultation on biostatistics and bioinformatics and optical imaging and probe development, to understand and effectively treat cancer. Our molecular oncology experts consult on preclinical studies, use of human tissues, interpretation of data and molecular characterization of cells and tumor tissue.

Psychiatric Neuroimaging (PNI) is active in neuropsychiatric research using imaging methods such as MRI, fMRI, PET and DTI to understand the mechanisms and brain networks underlying human cognition. PNI faculty have published hundreds of papers on a variety of brain disorders which include but are not limited to Alzheimer's disease, Parkinson's disease, bipolar disorder, and eating disorders. Faculty in the division have been awarded numerous peer-reviewed grants by the National Institutes of Health, foundations and other funding organizations.

Established in 2004, the MRB Molecular Imaging Service Center and Cancer Functional Imaging Core provides comprehensive molecular and functional imaging infrastructure to support the imaging research needs of the Johns Hopkins University faculty. Approximately 55-65 different Principal Investigators use the center annually. The MRB Molecular Imaging Service Center is located behind the barrier within the transgenic animal facility in the basement of MRB. The MRB location houses a 9.4T MRI/S scanner for magnetic resonance imaging and spectroscopy, an Olympus multiphoton microscope with in vivo imaging capability, a PET-CT scanner, a PET-SPECT scanner, and a SPECT-CT scanner for nuclear imaging, multiple optical imaging scanners including an IVIS Spectrum, and a LI COR near infrared scanner, and an ultrasound scanner. A brand new satellite facility in CRB2-LB03 opens in 2019 to house a simultaneous 7T PET-MR scanner, as well as additional imaging equipment, to meet the growing molecular and functional imaging research needs of investigators. To image with us, MRB Animal Facility training and Imaging Center Orientation are required to obtain access to the MRB Animal Facility and to the MRB Molecular Imaging Center (Suite B14). The MRB Animal Facility training group meets at 9:30 am on Thursdays at the Turner fountain/MRB elevator lobby. The Imaging Center orientation group meets at 1 pm on Thursdays at the Turner fountain, and orientation takes approximately 30 min. Please keep in mind that obtaining access to both facilities requires time, so please plan in advance.

The RISE Lab’s research focuses on developing and evaluating cellular/molecular imaging biosensors and drug/nanoparticle delivery systems for improved therapeutic indices in precision medicine.