Building on previous studies in which the transport and targeting of 90Y microspheres for liver tumor treatment were numerically analyzed based on medical data sets, this two-part paper discusses the influence of an anchored, radially adjustable catheter on local blood flow and microsphere delivery in an idealized hepatic artery system (Part I). In Part II a patient-inspired case study with necessary conditions for optimal targeting of radioactive microspheres (i.e., yttrium 90) onto liver tumors is presented. A new concept of optimal catheter positioning is introduced for selective targeting of two daughter-vessel exits potentially connected to liver tumors. Assuming laminar flow in rigid blood vessels with an anchored catheter in three controlled positions, the transient three-dimensional (3D) transport phenomena were simulated employing user-enhanced engineering software. The catheter position as well as injection speed and delivery function may influence fluid flow and particle transport. Although the local influences of the catheter may not be negligible, unique cross-sectional particle release zones exist, with which selectively the new controlled targeting methodology would allow optimal microsphere delivery. The insight gained from this analysis paves the way for improved design and testing of a smart microcatheter (SMC) system as well as new investigations leading to even more successful treatment with 90Y microspheres or combined internal radiation and chemotherapy.
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e-mail: ck@eos.ncsu.edu
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Research Papers
A New Catheter for Tumor Targeting With Radioactive Microspheres in Representative Hepatic Artery Systems. Part I: Impact of Catheter Presence on Local Blood Flow and Microsphere Delivery
C. Kleinstreuer,
C. Kleinstreuer
Department of Mechanical & Aerospace Engineering, Joint Department of Biomedical Engineering, North Carolina State University1, Raleigh, NC 27695;
e-mail: ck@eos.ncsu.edu
University of North Carolina at Chapel Hill
, Chapel Hill, NC 27599
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C. A. Basciano,
C. A. Basciano
Applied Research Associates, Physics-Based Computing Group, Southeast Division, Raleigh, NC 27615
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E. M. Childress,
E. M. Childress
Department of Mechanical & Aerospace Engineering,
North Carolina State University,
Raleigh, NC 27695
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A. S. Kennedy
A. S. Kennedy
Cancer Centers of North Carolina, Radiation Oncology, Cary, NC 27518
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C. Kleinstreuer
Department of Mechanical & Aerospace Engineering, Joint Department of Biomedical Engineering, North Carolina State University1, Raleigh, NC 27695;
University of North Carolina at Chapel Hill
, Chapel Hill, NC 27599e-mail: ck@eos.ncsu.edu
C. A. Basciano
Applied Research Associates, Physics-Based Computing Group, Southeast Division, Raleigh, NC 27615
E. M. Childress
Department of Mechanical & Aerospace Engineering,
North Carolina State University,
Raleigh, NC 27695
A. S. Kennedy
Cancer Centers of North Carolina, Radiation Oncology, Cary, NC 27518
J Biomech Eng. May 2012, 134(5): 051004 (10 pages)
Published Online: May 25, 2012
Article history
Received:
October 20, 2011
Revised:
April 11, 2012
Posted:
May 1, 2012
Published:
May 25, 2012
Online:
May 25, 2012
Citation
Kleinstreuer, C., Basciano, C. A., Childress, E. M., and Kennedy, A. S. (May 25, 2012). "A New Catheter for Tumor Targeting With Radioactive Microspheres in Representative Hepatic Artery Systems. Part I: Impact of Catheter Presence on Local Blood Flow and Microsphere Delivery." ASME. J Biomech Eng. May 2012; 134(5): 051004. https://doi.org/10.1115/1.4006684
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