In vivo PPy(DBS) sensors to quantify excitability of cells via sodium fluctuations in extracellular solution

Ziebro, Thomas R.

28 June 2017

No description available.

Biomedical Engineering

Cellular Biology

Engineering

Mechanical Engineering

Neurology

Neurobiology

Neurosciences

conducting polymers

PPy

DBS

electrochemistry

bioengineering

biomedical engineering

mechanical engineering

chemistry

neuron

electrophysiology

electrochemistry

system dynamics

sensor design

smart material

tissue nanotransfection

Design and Development of an Intra-Ventricular Assistive Device For End Stage Congestive Heart Failure Patients: Conceptual Design

Hosseinipour, Milad

27 November 2013

No description available.

Biomechanics

Biomedical Engineering

Biomedical Research

Engineering

Materials Science

Mechanical Engineering

Mechanics

Medical Imaging

Rehabilitation

Surgery

Therapy

Fluid Dynamics

heart

congestive heart failure

ventricular assistive device

ionic polymer metal composite

shape memory alloy

smart material

finite element analysis

CAD modeling

total artificial heart

actuator

experiment

hemodynamic

MRI

heart restraint method

THE ROLE OF ENERGY DISSIPATION, SUPERELASTICITY, AND SHAPE MEMORY EFFECTS IN ARCHITECTED MATERIALS FOR ENGINEERING APPLICATIONS

Kristiaan Hector (13892400)

13 October 2022

<p>The main goal of this thesis research is to expand the range of unique properties of phase transforming cellular materials (PXCMs), a new class of architected materials, and to extend their applicability both in the engineering disciplines and in the medical field. A novel aspect of PXCMs is their unique energy dissipation during loading via a snapping mechanism associated with a geometric transition between one stable configuration to another stable configuration at the unit cell level. Phase transformation is analogous to displacive transformations, such as martensitic transformations in shape memory alloys, with no change in configurational entropy. To accomplish this goal, three problem areas are addressed with the first exploring the effects of length scale as added structural hierarchy on material properties and energy dissipation, the second providing an analysis of the durability of architected materials via a novel additive manufacturing method, and the third, an extension into the medical field. Two examples are provided that demonstrate the effects of length scale as added structural hierarchy on material properties, and a machine learning approach for the feasible design of materials with additional levels of structural hierarchy is presented. A simple design approach coupled with a novel additive manufacturing method is discussed for the design of architected materials with high durability. Lastly, a concept for de-clogging bile stents via a temperature driven, shape-memory mechanism inspired by peristaltic locomotion in the human esophagus is presented.</p>

Architectural engineering

Structural engineering

architected materials

cellular materials

PXCM

ASMA

phase transforming cellular materials

artificial shape memory analogs

stents

bile duct cancer

peristalsis

snap through

sinusoidal beams

tape spring ligaments

octets

fatigue

chiral PXCM

energy dissipation

super elasticity

shape memory effect

machine learning

smart material design

inverse design

genetic algorithms