Share Email Print
cover

Proceedings Paper

Assessment of intratumor non-antibody directed iron oxide nanoparticle hyperthermia cancer therapy and antibody directed IONP uptake in murine and human cells
Author(s): P. J. Hoopes; J. A. Tate; J. A. Ogden; R. R. Strawbridge; S. N. Fiering; A. A. Petryk; S. M. Cassim; A. J. Giustini; E. Demidenko; R. Ivkov; S. Barry; P. Chinn; A. Foreman
Format Member Price Non-Member Price
PDF $14.40 $18.00
cover GOOD NEWS! Your organization subscribes to the SPIE Digital Library. You may be able to download this paper for free. Check Access

Paper Abstract

Hyperthermia, as an independent modality or in combination with standard cancer treatments such as chemotherapy and radiation, has been established in vitro and in vivo as an effective cancer treatment. However, despite efforts over the past 25 years, such therapies have never been optimized or widelyaccepted clinically. Although methods continue to improve, conventionally-delivered heat (RF, ultrasound, microwave etc) can not be delivered in a tumor selective manner. The development of antibody-targeted, or even nontargeted, biocompatible iron oxide nanoparticles (IONP) now allows delivery of cytotoxic heat to individual cancer cells. Using a murine mouse mammary adenocarcinoma (MTGB) and human colon carcinoma (HT29) cells, we studied the biology and treatment of IONP hyperthermia tumor treatment. Methods: Cancer cells (1 x 106) with or without iron oxide nanoparticles (IONP) were studied in culture or in vivo via implanted subcutaneously in female C3H mice, Tumors were grown to a treatment size of 150 mm3 and tumors volumes were measured using standard 3-D caliper measurement techniques. Mouse tumors were heated via delivery of an alternating magnetic field, which activated the nanoparticles, using a cooled 36 mm diameter square copper tube induction coil which provided optimal heating in 1.5 cm wide region of the coil. The IONPs were dextran coated and had a hydrodynamic radius of approximately 100 nm. For the in vivo studies, intra-tumor, peritumor and rectal (core body) temperatures were continually measured throughout the treatment period. Results: Although some eddy current heating was generated in non-target tissues at the higher field strengths, our preliminary IONP hyperthermia studies show that whole mouse AMF exposure @160 KHz and 400 or 550 Oe, for a 20 minutes (heat-up and protocol heating), provides a safe and efficacious tumor treatment. Initial electron and light microscopic studies (in vitro and in vivo) showed the 100 nm used in our studies are rapidly taken up and retained by the tumor cells. Additional in vitro studies suggest antibodies can significantly enhance the cellular uptake of IONPs.

Paper Details

Date Published: 24 February 2009
PDF: 12 pages
Proc. SPIE 7181, Energy-based Treatment of Tissue and Assessment V, 71810P (24 February 2009); doi: 10.1117/12.812056
Show Author Affiliations
P. J. Hoopes, Dartmouth College (United States)
Dartmouth Medical School (United States)
J. A. Tate, Dartmouth College (United States)
J. A. Ogden, Dartmouth College (United States)
R. R. Strawbridge, Dartmouth Medical School (United States)
S. N. Fiering, Dartmouth Medical School (United States)
A. A. Petryk, Dartmouth College (United States)
S. M. Cassim, Dartmouth College (United States)
A. J. Giustini, Dartmouth College (United States)
Dartmouth Medical School (United States)
E. Demidenko, Dartmouth Medical School (United States)
R. Ivkov, Johns Hopkins Univ. School of Medicine (United States)
S. Barry, Aduro Botech (United States)
P. Chinn, Aduro Botech (United States)
A. Foreman, Aduro Botech (United States)


Published in SPIE Proceedings Vol. 7181:
Energy-based Treatment of Tissue and Assessment V
Thomas P. Ryan, Editor(s)

© SPIE. Terms of Use
Back to Top