selected publications
-
Creating Stretchable Electronics from Dual Layer Flex-PCB for Soft Robotic Cardiac Mapping Catheters.
Micromachines.
2023
Academic Article
GET IT
Times cited: 278 -
Improved Functional Assessment of Ischemic Severity Using 3D Printed Models.
Frontiers in cardiovascular medicine.
2022
Academic Article
GET IT
Times cited: 59 -
Multilayer fabrication of durable catheter-deployable soft robotic sensor arrays for efficient left atrial mapping.
Science advances.
2020
Academic Article
GET IT
Times cited: 5 -
Automatic segmentation of multiple cardiovascular structures from cardiac computed tomography angiography images using deep learning.
PloS one.
2020
Academic Article
GET IT
Times cited: 14 - An approach to evaluate myocardial perfusion defect assessment for projection-based DECT: A phantom study. Clinical imaging. 2020 Academic Article GET IT
-
A Catheter-Deployable Soft Robotic Inflatable Basket for Enhanced Conformability to the Left Atrium of the Heart.
Advanced healthcare materials.
2020
Academic Article
GET IT
Times cited: 5 -
Rapid Manufacturing of Thin Soft Pneumatic Actuators and Robots.
Journal of visualized experiments : JoVE.
2019
Academic Article
GET IT
Times cited: 1 -
Microneedle Patterning of 3D Nonplanar Surfaces on Implantable Medical Devices Using Soft Lithography.
Micromachines.
2019
Academic Article
GET IT
Times cited: 140 -
An augmented reality system for image guidance of transcatheter procedures for structural heart disease.
PloS one.
2019
Academic Article
GET IT
Times cited: 25 -
Stereolithography for Personalized Left Atrial Appendage Occluders.
Advanced materials technologies.
2018
Academic Article
GET IT
Times cited: 7 -
Laser Cutting as a Rapid Method for Fabricating Thin Soft Pneumatic Actuators and Robots.
Soft robotics.
2018
Academic Article
GET IT
Times cited: 57 -
Patient-specific design of a soft occluder for the left atrial appendage.
Nature biomedical engineering.
2018
Academic Article
GET IT
Times cited: 37 -
Current progress in 3D printing for cardiovascular tissue engineering.
Biomedical materials (Bristol, England).
2015
Review
GET IT
Times cited: 127 -
Laser-induced nanoscale thermocapillary flow for purification of aligned arrays of single-walled carbon nanotubes.
ACS nano.
2014
Academic Article
GET IT
Times cited: 33 -
Microwave purification of large-area horizontally aligned arrays of single-walled carbon nanotubes.
Nature communications.
2014
Academic Article
GET IT
Times cited: 39 -
Using nanoscale thermocapillary flows to create arrays of purely semiconducting single-walled carbon nanotubes.
Nature nanotechnology.
2013
Academic Article
GET IT
Times cited: 153 -
Quantitative thermal imaging of single-walled carbon nanotube devices by scanning Joule expansion microscopy.
ACS nano.
2012
Academic Article
GET IT
Times cited: 23 -
Epitaxial growth of three-dimensionally architectured optoelectronic devices.
Nature materials.
2011
Letter
GET IT
Times cited: 108 -
Nanoscale, electrified liquid jets for high-resolution printing of charge.
Nano letters.
2010
Academic Article
GET IT
Times cited: 115 -
Alignment controlled growth of single-walled carbon nanotubes on quartz substrates.
Nano letters.
2009
Academic Article
GET IT
Times cited: 125 -
High-frequency performance of submicrometer transistors that use aligned arrays of single-walled carbon nanotubes.
Nano letters.
2009
Academic Article
GET IT
Times cited: 119