Optimization of site-targeted perfluorocarbon nanoparticle contrast in whole blood for molecular imaging applications

@inproceedings{citeulike:2336147, abstract = {The ability to enhance specifically molecular markers of pathology with ultrasound has been previously demonstrated by our group employing a nanoparticle contrast agent. One of the advantages of this agent is it's relative non-echogenicity in the blood pool that allows increased contrast-to-noise between the blood pool and the bound, site-targeted agent. We sought to define the contrast agent concentration and acoustic parameters necessary to detect contrast enhancement in the blood so that molecular contrast enhancement could be more precisely defined. This study addresses two potential mechanisms that have been proposed for backscatter from the nanoparticle contrast agent in the blood pool - concentration-related scattering and phase conversion from liquid to gaseous perfluorocarbon. The nanoparticles were produced by methods currently standard in our laboratory using perfluorooctyl bromide (PFOB: b.p. 142/spl deg/C) as the major component. Particle size was measured at 200/spl plusmn/30nm. Attenuation coefficient and backscatter of the agent were measured in whole porcine blood (hct 40\%) and porcine plasma maintained at 37/spl deg/C. Specimens were insonified using a broadband, single element transducer (5 MHz, 2.54 cm diameter, 5.08 cm focal length). Acoustic pulses with usable bandwidth of 1.5 to 10 MHz, a repetition rate of 1kHz, and peak negative pressure of 3.9, 2.7, 1.5, and 0.8MPa (equivalent to M.I. of: 1.7, 1.2, 0.67, 0.36) were used to measure of attenuation coefficient and backscatter of nanoparticles at concentrations of 0.26, 0.51, 1.02, 2.04, 4.08/spl times/10/sup 14/ particles/mL while suspended in either whole porcine blood or porcine plasma. The attenuation coefficient was linear at all concentrations and power levels and shows no evidence of a resonant peak characteristic of liquid-to-gas phase conversion. The back-scatter coefficient in plasma increased with concentration. However, in blood, backscatter was only significantly different from baseline at 2.04/spl times/l0/sup 14/ particles/mL and above (8x the maximum anticipated dose). These data indicate that phase conversion of PFOB to gas is not the source of the contrast in molecular imaging with site targeted nanoparticles.}, author = {Hughes, M. S. and Marsh, J. N. and Hall, C. S. and Fuhrhop, R. W. and Lanza, G. M. and Wickline, S. A. }, booktitle = {Ultrasonics, 2003 IEEE Symposium on}, citeulike-article-id = {2336147}, doi = {10.1109/ULTSYM.2003.1293460}, journal = {Ultrasonics, 2003 IEEE Symposium on}, keywords = {imaging, nanotech, sccne, ultrasound}, pages = {536--539 Vol.1}, posted-at = {2008-03-03 12:31:05}, priority = {0}, title = {Optimization of site-targeted perfluorocarbon nanoparticle contrast in whole blood for molecular imaging applications}, url = {http://dx.doi.org/10.1109/ULTSYM.2003.1293460}, volume = {1}, year = {2003} }

TY - CONF ID - citeulike:2336147 L3 - citeulike-article-id:2336147 TI - Optimization of site-targeted perfluorocarbon nanoparticle contrast in whole blood for molecular imaging applications T2 - Ultrasonics, 2003 IEEE Symposium on JF - Ultrasonics, 2003 IEEE Symposium on VL - 1 SP - 536 EP - 539 Vol.1 N2 - The ability to enhance specifically molecular markers of pathology with ultrasound has been previously demonstrated by our group employing a nanoparticle contrast agent. One of the advantages of this agent is it's relative non-echogenicity in the blood pool that allows increased contrast-to-noise between the blood pool and the bound, site-targeted agent. We sought to define the contrast agent concentration and acoustic parameters necessary to detect contrast enhancement in the blood so that molecular contrast enhancement could be more precisely defined. This study addresses two potential mechanisms that have been proposed for backscatter from the nanoparticle contrast agent in the blood pool - concentration-related scattering and phase conversion from liquid to gaseous perfluorocarbon. The nanoparticles were produced by methods currently standard in our laboratory using perfluorooctyl bromide (PFOB: b.p. 142/spl deg/C) as the major component. Particle size was measured at 200/spl plusmn/30nm. Attenuation coefficient and backscatter of the agent were measured in whole porcine blood (hct 40%) and porcine plasma maintained at 37/spl deg/C. Specimens were insonified using a broadband, single element transducer (5 MHz, 2.54 cm diameter, 5.08 cm focal length). Acoustic pulses with usable bandwidth of 1.5 to 10 MHz, a repetition rate of 1kHz, and peak negative pressure of 3.9, 2.7, 1.5, and 0.8MPa (equivalent to M.I. of: 1.7, 1.2, 0.67, 0.36) were used to measure of attenuation coefficient and backscatter of nanoparticles at concentrations of 0.26, 0.51, 1.02, 2.04, 4.08/spl times/10/sup 14/ particles/mL while suspended in either whole porcine blood or porcine plasma. The attenuation coefficient was linear at all concentrations and power levels and shows no evidence of a resonant peak characteristic of liquid-to-gas phase conversion. The back-scatter coefficient in plasma increased with concentration. However, in blood, backscatter was only significantly different from baseline at 2.04/spl times/l0/sup 14/ particles/mL and above (8x the maximum anticipated dose). These data indicate that phase conversion of PFOB to gas is not the source of the contrast in molecular imaging with site targeted nanoparticles. KW - imaging KW - nanotech KW - sccne KW - ultrasound AU - Hughes, MS AU - Marsh, JN AU - Hall, CS AU - Fuhrhop, RW AU - Lanza, GM AU - Wickline, SA PY - 2003/// UR - http://dx.doi.org/10.1109/ULTSYM.2003.1293460 ER -