ADVANCED ULTRASOUND IN DIAGNOSIS AND THERAPY >
Research Advances in Ultrasound Imaging for Tumor in Situ
Online published: 2020-08-21
Known for being highly sensitive and noninvasive, ultrasound imaging using microbubble contrast agents is widely used in the clinic. To use ultrasound to image tissue beyond the vasculature, researchers have developed strategies that include nanobubbles, ultrasound contrast agents generated in situ, and gene expression of ultrasound contrast agents in situ. All of these strategies offer the capability of targeting tumor cells, intratumoral imaging tumor cells and require just a small incision or no incision. In this review, we will first describe the application of nanobubbles acting as ultrasound contrast agents. Then, we will briefly introduce the stimuli-responsive formulations to generate ultrasound contrast agents in situ. Finally, we will provide an overview of the use of state-of-the-art of gene expression of ultrasound contrast agents in situ to monitor cellular location and function inside living organisms.
Key words: Ultrasound contrast agents; Nanobubbles; Gene expression; Ultrasound
Wang, MD Ping , Sun, PhD Lihong , Sun, MD Suhui , Xu, MD Menghong , Zhang, MD Lulu , Zhang, MD Jinxia , Gao, PhD Liquan , Chen, PhD Qingfeng , Liang, PhD Xiaolong . Research Advances in Ultrasound Imaging for Tumor in Situ[J]. ADVANCED ULTRASOUND IN DIAGNOSIS AND THERAPY, 2020 , 4(3) : 169 -175 . DOI: 10.37015/AUDT.2020.190040
[1] | Gramiak R. Echocardiography of the aortic root. Investigative Radiology. 1968; 3:356-66. |
[2] | Sponheim N, Hoff L, A. Waaler A, Muan B, Morris H, Holm S.Albunex-a new ultrasound contrast agent. International Conference on Acoustic Sensing & Imaging 1993; 1:103-8. |
[3] | Li G, Wang Q, Zhao X. Introduction of ultrasound microbubble technology aided tumor imaging and treatment. IEEE International Conference on Medical Imaging Physics and Engineering 2014; 4:192-5. |
[4] | Perera RH, Hernandez C, Zhou H, Kota P, Burke A, Exner AA. Ultrasound imaging beyond the vasculature with new generation contrast agents. Wiley Interdisciplinary Reviews Nanomedicine & Nanobiotechnology 2015; 7:593-608. |
[5] | Ferrara KW, Borden MA, Zhang H. Lipid-shelled vehicles: engineering for ultrasound molecular imaging and drug delivery. Accounts of Chemical Research 2009; 42:881-892. |
[6] | Sheeran PS, Luois S, Matsunaga TO. Submicron decafluorobutane phase-change contrast agents generated by microbubble condensation. Ultrasonics Symposium (IUS) 2011; pp:636-9. |
[7] | Jian J, Liu C, Gong Y, Su L, Zhang B, Wang Z. India ink incorporated multifunctional phase-transition nanodroplets for photoacoustic/ultrasound dual-modality imaging and photoacoustic effect based tumor therapy. Theranostics 2014; 4:1026-1038. |
[8] | Liu J, Zhang B, Li M, Zhou M, Li F, Huang X, et al. Preparation and characterization of a novel silicon-modified nanobubble. Plos one 2017; 12:31-44. |
[9] | Yu H, Wang W, He X, Zhou Q, Ding M. Novel fluorescence nanobubbles for contrast-enhanced ultrasound imaging in rabbit VX2 hepatocellular carcinoma model. International Society for Optics and Photonics 2017; 10139:1-10. |
[10] | Jin Q, Lin CY, Kang ST, Chang YC, Zheng H, Yang CM, et al, Superhydrophobic silica nanoparticles as ultrasound contrast agents. Ultrasonics Sonochemistry 2017; 36:262-269. |
[11] | Lakshmanan A, Lu GJ, Farhadi A, Nety SP, Kunth M, Lee-Gosselin A, et al. Preparation of biogenic gas vesicle nanostructures for use as contrast agents for ultrasound and MRI. Nature Protocols 2017; 12:2050-2080. |
[12] | Shapiro MG. Genetically encoded gas nanostructures as biophyically tunable molecular reporters for mri and ultrasound. Biophysical Journal 2014; 106:19. |
[13] | Hobbs SK, Monsky WL, Yuan F, Roberts WG, Griffith L, Torchilin VP. Regulation of transport pathways in tumor vessels: role of tumor type and microenvironment. Biomaterials 2012; 33:5854-5864. |
[14] | Zhou Y, Wang Z, Chen Y, Shen H, Luo Z, Li A, et al. Microbubbles from gas-generating perfluorohexane nanoemulsions for targeted temperature-sensitive ultrasonography and synergistic HIFU ablation of tumors.' Advanced Materials 2013; 25:4123-30. |
[15] | Guo R, Tian Y, Wang Y, Yang W. Near‐infrared laser‐triggered nitric oxide nanogenerators for the reversal of multidrug resistance in cancer. Advanced Functional Materials 2017; 27:160398-404. |
[16] | Hobbs SK, Monsky WL, Yuan F, Roberts WG, Griffith L, Torchilin VP. Regulation of transport pathways in tumor vessels: Role of tumor type and microenvironment. Proceedings of the National Academy of Sciences of the United States of America 1998; 95:4607-12. |
[17] | Li C, Wu K, Jing L, Liu H, Zhou Q, Ding M, et al. A preliminary evaluation of self-made nanobubble in contrast-enhanced ultrasound imaging. The International Society for Optical Engineering 2014; 9038:11-18. |
[18] | Zheng R, Yin T, Wang P, Zheng B, Cheng D. Nanobubbles for enhanced ultrasound imaging of tumor. Int J Nanomedicine 2012; 7:895-904. |
[19] | Yang H, Cai W, Xu L, Lv X, Qiao Y, Li P, et al. Nanobubble-Affibody: Novel ultrasound contrast agents for targeted molecular ultrasound imaging of tumor. Biomaterials 2014; 37:279-88. |
[20] | Zhang X, Zheng Y, Wang Z, Huang S, Chen Y, Jiang W, et al. Methotrexate-loaded PLGA nanobubbles for ultrasound imaging and Synergistic Targeted therapy of residual tumor during HIFU ablation. Biomaterials 2014; 35:5148-61. |
[21] | Bloch SH, Wan M, Dayton PA. Optical observation of lipid- and polymer-shelled ultrasound microbubble contrast agents. Applied Physics Letters 2004; 84:631-33. |
[22] | Min HS, Kang E, Koo H, Lee J, Kim K, Park RW, et al. Gas-generating polymeric microspheres for long-term and continuous in vivo ultrasound imaging. Biomaterials 2012; 33:936-44. |
[23] | Nieves L, Hernandez C, Nittayacharn P, Lilly J, Coyne R, et al. Effect of the surfactant pluronic on the stability of lipid-stabilized perfluorocarbon nanobubbles. International Ultrasonics Symposium (IUS) 2017; pp:1-4 |
[24] | Browning RJ, Bian S, Reardon PJ. Ultrasound enhanced delivery of cisplatin loaded nanoparticles. Journal of the Acoustical Society of America 2017,141:3459-60. |
[25] | Sloun RJGV, Solomon O, Eldar YC. Sparsity-driven super-resolution in clinical contrast-enhanced ultrasound. International Ultrasonics Symposium (IUS) 2017; pp:236-9. |
[26] | Min KH, Min HS, Lee HJ, Park DJ, Yhee JY, Kim K, et al. pH-controlled gas-generating mineralized nanoparticles: a theranostic agent for ultrasound imaging and therapy of Cancers. Acs Nano 2015; 9:134-45. |
[27] | Zhang N, Li J, Hou R, Zhang J, Wang P, Liu X, et al. Bubble-generating nano-lipid carriers for ultrasound/CT imaging-guided efficient tumor therapy. Int J Pharm 2017; 20:251-62. |
[28] | Liu Y, Yang F, Yuan C, Li M, Wang T, Chen B, et al. Magnetic nanoliposomes as in situ microbubble bombers for multimodality image-guided cancer theranostics. Acs Nano 2017; 11:1509-19. |
[29] | Kashfi K, Olson KR. Biology and therapeutic potential of hydrogen sulfide and hydrogen sulfide-releasing chimeras. Biochemical Pharmacology 2013; 85:689-703. |
[30] | Mikhail G, Shapiro, Patrick W. he, Arkosnato Neogy, Melissa Yin, F.Stuart Foster, David V. Schaffer. Biogenic gas nanostructures as ultrasonic molecular reporters. Nature Nanotechnology 2014; 9:311-316. |
[31] | Farhadi A, Ho GH, Sawyer DP, Bourdeau RW, Shapiro MG. Ultrasound imaging of gene expression in mammalian cells. Science 2019; 365:1469-75. |
/
〈 | 〉 |