Biomedical Engineering Reference
In-Depth Information
[124] Cho EC, Kim C, Zhou F, Cobley CM, Song KH, Chen JY, Li ZY, Wang LHV, Xia Yn.
Measuring the optical absorption cross sections of Au-Ag nanocages and Au nanorods
by photoacoustic imaging. J Phys Chem C 2009;
113
:9023-9028.
[125] Lovell JF, Jin CS, Huynh E, Macdonald Td, Cao W, Zheng g. Enzymatic regioselec-
tion for the synthesis and biodegradation of porphysome nanovesicles. Angew Chem Int
Ed Engl 2012;
51
:2429-2433.
[126] Lovell JF, Jin CS, Huynh E, Jin H, Kim C, rubinstein JL, Chan WC, Cao W, Wang LV,
Zheng g. Porphysome nanovesicles generated by porphyrin bilayers for use as multi-
modal biophotonic contrast agents. nat Mater 2011;
10
:324-332.
[127] Chen J, glaus C, Laforest r, Zhang Q, Yang M, gidding M, Welch MJ, Xia Y. gold
nanocages as photothermal transducers for cancer treatment. Small 2010;
6
:811-817.
[128] Cobley CM, Au L, Chen J, Xia Y. Targeting gold nanocages to cancer cells for photo-
thermal destruction and drug delivery. Expert opin drug deliv 2010;
7
:577-587.
[129] Peer d, Karp JM, Hong S, FaroKHzad oC, Margalit r, Langer r. nanocarriers as an
emerging platform for cancer therapy. nat nanotechnol 2007;
2
:751-760.
[130] Avti PK, Hu S, Favazza C, Mikos Ag, Jansen JA, Shroyer Kr, Wang LV, Sitharaman B.
detection, mapping, and quantification of single walled carbon nanotubes in histolog-
ical specimens with photoacoustic microscopy. PLoS one 2012;
7
:e35064.
[131] de la Zerda A, Zavaleta C, Keren S, Vaithilingam S, Bodapati S, Liu Z, Levi J, Smith
Br, Ma TJ, oralkan o, Cheng Z, Chen X, dai H, Khuri-Yakub BT, gambhir SS.
Carbon nanotubes as photoacoustic molecular imaging agents in living mice. nat
nanotechnol 2008;
3
:557-562.
[132] Kang B, Yu d, dai Y, Chang S, Chen d, ding Y. Cancer-cell targeting and photoacoustic
therapy using carbon nanotubes as “bomb” agents. Small 2009;
5
:1292-1301.
[133] Kim JW, galanzha EI, Shashkov EV, Moon HM, Zharov VP. golden carbon nanotubes
as multimodal photoacoustic and photothermal high-contrast molecular agents. nat
nanotechnol 2009;
4
:688-694.
[134] Pramanik M, Swierczewska M, green d, Sitharaman B, Wang LV. Single-walled
carbon nanotubes as a multimodal-thermoacoustic and photoacoustic-contrast agent.
J Biomed opt 2009;
14
:034018.
[135] Xiang L, Yuan Y, Xing d, ou Z, Yang S, Zhou F. Photoacoustic molecular imaging with
antibody-functionalized single-walled carbon nanotubes for early diagnosis of tumor.
J Biomed opt 2009;
14
:021008.
[136] Zhou F, Wu S, Yuan Y, Chen Wr, Xing d. Mitochondria-targeting photoacoustic
therapy using single-walled carbon nanotubes. Small 2012;
8
:1543-1550.
[137] de la Zerda A, Liu Z, Bodapati S, Teed r, Vaithilingam S, Khuri-Yakub BT, Chen X,
dai H, gambhir SS. Ultrahigh sensitivity carbon nanotube agents for photoacoustic
molecular imaging in living mice. nano Lett 2010;
10
:2168-2172.
[138] Kim C, Qin r, Xu JS, Wang LV, Xu r. Multifunctional microbubbles and nanobubbles
for photoacoustic and ultrasound imaging. J Biomed opt 2010;
15
:010510.
[139] Wang YH, Liao AH, Chen JH, Chris Wang Cr, Li PC. Photoacoustic/ultrasound
dual-modality contrast agent and its application to thermotherapy. J Biomed opt 2012;
17
:
045001.
[140] Miller dL. Frequency relationships for ultrasonic activation of free microbubbles,
encapsulated microbubbles, and gas-filled micropores. J Acoust Soc Am 1998;
104
:
2498-2505.
Search WWH ::
Custom Search