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Injection Catheter for Stem Cells
Adam Goon, Michael Conrardy, Joel Webb, Andrew Bertram
Client: Dr. Tim Hacker, PhD (UW Department of Medicine)
Advisor: Prof. John Webster (UW Biomedical Engineering Department)
The purpose of this project is to create a catheter that can provide multiple injections
in a reduced amount of time compared to the current procedure. The catheter will
be used by the client in his research of injecting stem cells into the heart to
determine if it will produce new cardiomyocytes of the heart. The final design
consists of three components that can provide multiple injections at different
locations in the ventricle. The design has adjustable height and can be rotated 360
degrees, so all walls of the ventricle can be reached. The final prototype would be
made of extruded polyurethane with an injection catheter that has a nitinol needle
for injections.
Background
Three component guided catheter
• Flexible tube in which internal component is
inserted
• Contains small slots from which needle can exit
• Contains a rectangular track to assure internal
component is linearly aligned with slots
• 9 French (3 mm OD x 2.25 mm ID)
Testing
Accuracy Testing
Figure 3: External component with 14
slots and a track for internal component
to travel along
• Research will determine to what extent stem cells can
regenerate dead or damaged heart cells
• The procedure involves the use of x-ray imaging, contrast
agent and an ECG to determine the placement of the
catheter on the heart walls (see Figure 1)
Internal Component
Figure 1. An X-ray
image of the catheter
inside the left
ventricle during a
procedure
•Currently, no catheters to provide multiple injections in the
heart
Estimated cost to extrude
polyurethane for true-to-scale
catheter in UW Polymers Lab:
$5000
External Component
• Current research is being conducted involving the
injection of stem cells into dead heart tissue
• Our client is using a single injection catheter (Myostar by
Biosense-Webster, see Figure 2) that must be repositioned
for each injection site on pigs
Budget
Final Design
Abstract
Figure 4: Internal component with circular
track for injection component. Extruded
track to go along external component
• Solid tube inserted within external component
• Contains rectangular extrusion in which track of
external component would travel
• Contains circular track for injection component
• Guides injection component out of holes along
external component at ~60 degree angle
• Positioned catheter a fixed distance
from graph paper (3.5 in. or 88.9
mm)
• 12 trials of marking where needle
contacted paper
•Inner component height kept
constant during all 12 trials
• Determined mean point of all 12
trials
• Standard deviation showed how far
each injection would be from
mean point
Injection Component
Motivation
• Current use of single injection catheter is very
time consuming
• The heart is still beating so moving the
catheter around is difficult
Figure 2. Current
catheter used to inject
stem cells. The catheter
incorporates a single
retractable needle at the
tip [1]
• Needle depth is inconsistent due to different
bending angles
• Alternative catheters are not flexible enough to
pass aorta and enter ventricle
Client Requirements
•Multiple injections: The catheter must be able to create multiple, quick injections to
decrease time of procedure
•Y-distance determined to compare to
distance between holes on outer
component
• Follows circular track of internal component
• Polyurethane tubing with lumen for stem
cells
• 3 mm long, 27 gauge nitinol needle at tip
• Protrudes up to 25 mm from internal
component into left ventricle
Figure 8: Scatter plot of 12 points of
injections at 3 different hole locations
Standard Deviation
• x-direction: 3.05 mm (0.36 mm)*
• y-direction: 3.56 in. (0.42 mm)*
Y-Distance between mean points:
• Hole 6 to 7: 20.32 mm (2.40 mm)*
• Hole 7 to 8: 19.30 mm (2.28 mm)*
* Estimated measurements in true-to-scale
design
Future Work
Figure 5: Injection component with
polyurethane tubing and a 3 mm long nitinol
needle on the end for injections
• Determine method of rapid prototyping or plastic extrusion to create prototype of
true-to-scale catheter
• Determine optimal slot size without affecting structural integrity of catheter
Materials:
• Polyurethane will be used for interior and exterior
• 27 gauge nitinol needle used on the injection component
• Current catheter can be used for injection component
Dimensions
Internal Component
•Develop mechanical handle to ensure proper alignment of holes and track
•Test for accuracy, consistency, and time reduction of procedure on true-to-scale
prototype
• Test lengths of needles to determine which size will work best in true-to-scale
design
External Component
•Size: Must be small enough in diameter to fit through the arteries and aorta of the body
• < 14 French diameter (4.66 mm)
Acknowledgements
Special Thanks to:
John Webster, Professor, UW-Madison Biomedical Engineering Dept.
Tim Hacker, UW Department of Medicine
Amish Raval, Assistant Professor, UW-Hospital
Tim Osswald, Professor, UW-Madison Mechanical Engineering Dept. and Polymers Lab
•Flexibility: The catheter must be made out of flexible enough material to curve
through the aorta
• Consistency: The needle must enter the muscle wall of the heart with a constant depth
References
•Accuracy: The catheter must be positioned in the heart to improve accuracy of injections
at the same location
Figure 6: True-to-scale internal component
with dimensions
Figure 7: True-to-scale external component
with dimensions
[1] http://www.med.upenn.edu/mcrc/patel_lab/documents/LVCatheterUsingEtOHinSwineJICE.pdf
[2] http://www.memory-metalle.de/html/01_start/index_outer_frame.htm
[3] http://www.alzet.com/products/Alzt_cathrs.php