People
| Name | Role | Research Project | |
|---|---|---|---|
 Anna Devor |
PL | Neurovascular Imaging Laboratory | adevor@bu.edu |
 David Kleinfeld |
PL | Neurophysics Laboratory | dk@physics.ucsd.edu |
 Jon Polimeni |
PL | Magnetic Resonance – Physics & Instrumentation Group | jrpolimeni@mgh.harvard.edu |
 Laura D Lewis |
PL | Lewis Neuro Laboratory | ldlewis@mit.edu |
 Xin Yu |
PL | TNNC Laboratory | xyu9@mgh.harvard.edu |
|
Sava Sakadzic |
PL | Optics @Martinos | xyu9@mgh.harvard.edu |
 Josef B. Mandeville |
PL | Mandeville Laboratory | jbm@nmr.mgh.harvard.edu |
 Gal Mishne |
PL | Halıcıoğlu Data Science Institute | gmishne@ucsd.edu |
 Duygu Kuzum |
PL | Neuroelectronics Laboratory | dkuzum@eng.ucsd.edu |
 Massimo Vergassola |
PL | Vergassola Group | massimo.vergassola@phys.ens.fr |
 Andreas Linninger |
PL | Laboratory for Product and Process Design | linninge@uic.edu |
 Lei Tian |
PL | Computational Imaging Systems Lab | leitian@bu.edu |
 Mike Economo |
PL | Economo Laboratory | mne@bu.edu |
 Bruce Rosen |
PL | Quantitative Tumor Imaging Laboratory | brrosen@mgh.harvard.edu |
 Martin Thunemann |
PL | Neurovascular Imaging Laboratory | martinth@bu.edu |
 Nicholas Cicero |
PhD Candidate | Nick’s work is primarily focused on investigating the subcortical neuromodulatory systems that regulate sleep-wake states in humans using high spatial resolution functional MRI at 7 Tesla with simultaneous EEG. By using high spatial resolution fMRI, Nick’s work will elucidate the functional responses of distinct subcortical nuclei during transitions between arousal states at a spatial precision that more closely matches the size of these regions. | ngcicero@bu.edu |
 Bradley C. Rauscher |
PhD Candidate | Bradley studies how the hemodynamic signal reflects underlying neuronal activity and intrinsic neuromodulation in order to better understand noninvasive functional imaging. To do this, he mainly utilize widefield cortical imaging to observe spontaneous (resting state) fluctuations in neuronal activity, neuromodulator release, and oxy/deoxy/total hemoglobin across the dorsal surface of the cortex. Using this type of data, he creates models for hemodynamics which take into account neuronal activity, neuromodulator release, and brain state. | bcraus@bu.edu |
 Kate Herrema |
PhD Candidate | Kate is working on the implantation of human cortical organoids into rodent cortex as a strategy to model neurodevelopment in health and disease. They employ multimodal monitoring (two-photon calcium imaging and electrophysiological recordings) to investigate structural and functional changes as human neurons integrate into host circuitry. She is also developing a biomaterial controlled drug release platform to deliver developmental morphogens to the implanted organoid in order to direct cell patterning and maturation in-vivo. | kherrema@bu.edu |
 Dora Balog |
PhD Candidate | Dora’s project focuses on modeling implicitly neuromodulation in pyramidal cells. To achieve this on a single-cell level, she is modifying the popular Hay model first for acetylcholine, then for norepinephrine, and will proceed to build populations of pyramidal cells in the foreseeable future. The overarching goal is to be able to translate calcium dynamics to EEG, to aid the efforts of human application. | dbalog@bu.edu |