Clarissa Zimmerman Cooley
Overview
Explore the profile of Clarissa Zimmerman Cooley including associated specialties, affiliations and a list of published articles.
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Articles
10
Citations
204
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0
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Recent Articles
1.
Salameh N, Lurie D, Ipek O, Cooley C, Campbell-Washburn A
MAGMA
. 2023 Jul;
36(3):329-333.
PMID: 37482583
No abstract available.
2.
Mason E, Mattingly E, Herb K, Sliwiak M, Franconi S, Cooley C, et al.
Sci Rep
. 2021 Jun;
11(1):13456.
PMID: 34188077
Breast-conserving surgery (BCS) is a commonly utilized treatment for early stage breast cancers but has relatively high reexcision rates due to post-surgical identification of positive margins. A fast, specific, sensitive,...
3.
Mateen F, Cooley C, Stockmann J, Rice D, Vogel A, Wald L
Mult Scler Relat Disord
. 2021 Mar;
51:102903.
PMID: 33780808
A low-field (80 mT), portable MRI scanner has been developed that may address barriers to MRI for people with multiple sclerosis (MS). As a proof of concept study, we imaged...
4.
Cooley C, Stockmann J, Witzel T, LaPierre C, Mareyam A, Jia F, et al.
J Magn Reson
. 2020 Jun;
317:106764.
PMID: 32589583
No abstract available.
5.
Design and implementation of a low-cost, tabletop MRI scanner for education and research prototyping
Cooley C, Stockmann J, Witzel T, LaPierre C, Mareyam A, Jia F, et al.
J Magn Reson
. 2019 Nov;
310:106625.
PMID: 31765969
While access to a laboratory MRI system is ideal for teaching MR physics as well as many aspects of signal processing, providing multiple MRI scanners can be prohibitively expensive for...
6.
Wald L, McDaniel P, Witzel T, Stockmann J, Cooley C
J Magn Reson Imaging
. 2019 Oct;
52(3):686-696.
PMID: 31605435
Research in MRI technology has traditionally expanded diagnostic benefit by developing acquisition techniques and instrumentation to enable MRI scanners to "see more." This typically focuses on improving MRI's sensitivity and...
7.
McDaniel P, Cooley C, Stockmann J, Wald L
Magn Reson Med
. 2019 Jun;
82(5):1946-1960.
PMID: 31231885
Purpose: The size, cost, and siting requirements of conventional MRI systems limit their availability and preclude usage as monitoring or point-of-care devices. To address this, we developed a lightweight MRI...
8.
Cooley C, Haskell M, Cauley S, Sappo C, Lapierre C, Ha C, et al.
IEEE Trans Magn
. 2018 May;
54(1).
PMID: 29749974
Permanent magnet arrays offer several attributes attractive for the development of a low-cost portable MRI scanner for brain imaging. They offer the potential for a relatively lightweight, low to mid-field...
9.
Cooley C, Mandeville J, Mason E, Mandeville E, Wald L
Neuroimage
. 2018 May;
178:713-720.
PMID: 29738908
Magnetic Particle Imaging (MPI) is a rapidly developing imaging modality that directly measures and maps the concentration of injected superparamagnetic iron oxide nanoparticles (SPIOs). Since the agent does not cross...
10.
Cooley C, Stockmann J, Armstrong B, Sarracanie M, Lev M, Rosen M, et al.
Magn Reson Med
. 2014 Mar;
73(2):872-83.
PMID: 24668520
Purpose: As the premiere modality for brain imaging, MRI could find wider applicability if lightweight, portable systems were available for siting in unconventional locations such as intensive care units, physician...