參考文獻 |
1.Fidler, I.J., The relationship of embolic homogeneity, number, size and viability to the incidence of experimental metastasis. European Journal of Cancer (1965), 1973. 9(3): p. 223-227.
2.Massagué, J. and A.C. Obenauf, Metastatic colonization by circulating tumour cells. Nature, 2016. 529: p. 298.
3.Cheung, K.J. and A.J. Ewald, A collective route to metastasis: Seeding by tumor cell clusters. Science, 2016. 352(6282): p. 167-169.
4.Fabisiewicz, A. and E. Grzybowska, CTC clusters in cancer progression and metastasis. Medical Oncology, 2017. 34(1): p. 12.
5.Pantel, K. and M. Speicher, The biology of circulating tumor cells. Oncogene, 2016. 35(10): p. 1216.
6.Plaks, V., C.D. Koopman, and Z. Werb, Circulating tumor cells. Science, 2013. 341(6151): p. 1186-1188.
7.Dive, C. and G. Brady, SnapShot: circulating tumor cells. Cell, 2017. 168(4): p. 742-742. e1.
8.Krebs, M.G., et al., Circulating tumour cells: their utility in cancer management and predicting outcomes. Therapeutic advances in medical oncology, 2010. 2(6): p. 351-365.
9.Meng, S., et al., Circulating tumor cells in patients with breast cancer dormancy. Clinical cancer research, 2004. 10(24): p. 8152-8162.
10.Au, S.H., et al., Clusters of circulating tumor cells: A biophysical and technological perspective. Current opinion in biomedical engineering, 2017. 3: p. 13-19.
11.Shen, Z., A. Wu, and X. Chen, Current detection technologies for circulating tumor cells. Chemical Society Reviews, 2017. 46(8): p. 2038-2056.
12.Jackson, J.M., et al., Materials and microfluidics: enabling the efficient isolation and analysis of circulating tumour cells. Chemical Society Reviews, 2017. 46(14): p. 4245-4280.
13.Patil, P., et al., Isolation of circulating tumour cells by physical means in a microfluidic device: a review. RSC Advances, 2015. 5(109): p. 89745-89762.
14.Zheng, S., et al., Membrane microfilter device for selective capture, electrolysis and genomic analysis of human circulating tumor cells. Journal of chromatography A, 2007. 1162(2): p. 154-161.
15.Mohamed, H., et al., Isolation of tumor cells using size and deformation. Journal of Chromatography A, 2009. 1216(47): p. 8289-8295.
16.Sarioglu, A.F., et al., A microfluidic device for label-free, physical capture of circulating tumor cell clusters. Nature methods, 2015. 12(7): p. 685.
17.Sajay, B.N.G., et al., Towards an optimal and unbiased approach for tumor cell isolation. Biomedical microdevices, 2013. 15(4): p. 699-709.
18.Hosokawa, M., et al., Microcavity array system for size-based enrichment of circulating tumor cells from the blood of patients with small-cell lung cancer. Analytical chemistry, 2013. 85(12): p. 5692-5698.
19.Qin, X., et al., Size and deformability based separation of circulating tumor cells from castrate resistant prostate cancer patients using resettable cell traps. Lab on a Chip, 2015. 15(10): p. 2278-2286.
20.Chen, H., et al., Highly-sensitive capture of circulating tumor cells using micro-ellipse filters. Scientific Reports, 2017. 7(1): p. 610.
21.Cheng, Y., et al., High-throughput and clogging-free microfluidic filtration platform for on-chip cell separation from undiluted whole blood. Biomicrofluidics, 2016. 10(1): p. 014118.
22.Park, J.-M., et al., Highly efficient assay of circulating tumor cells by selective sedimentation with a density gradient medium and microfiltration from whole blood. Analytical chemistry, 2012. 84(17): p. 7400-7407.
23.Hou, H.W., et al., Isolation and retrieval of circulating tumor cells using centrifugal forces. Scientific reports, 2013. 3: p. 1259.
24.Guan, G., et al. High throughput circulating tumor cell isolation using trapezoidal inertial microfluidics. in Proceedings of 17th International Conference on Miniaturized Systems for Chemistry and Life Sciences, Freiburg, Germany. 2013.
25.Lin, E., et al., High-Throughput Microfluidic Labyrinth for the Label-free Isolation of Circulating Tumor Cells. Cell systems, 2017. 5(3): p. 295-304. e4.
26.Moon, H.-S., et al., Continuous separation of breast cancer cells from blood samples using multi-orifice flow fractionation (MOFF) and dielectrophoresis (DEP). Lab on a Chip, 2011. 11(6): p. 1118-1125.
27.Chen, W., et al., Nanoroughened surfaces for efficient capture of circulating tumor cells without using capture antibodies. ACS nano, 2012. 7(1): p. 566-575.
28.Dong, Y., et al., Microfluidics and circulating tumor cells. J Mol Diagn, 2013. 15(2): p. 149-57.
29.Seal, S., A sieve for the isolation of cancer cells and other large cells from the blood. Cancer, 1964. 17(5): p. 637-642.
30.Mohamed, H., et al., Development of a rare cell fractionation device: application for cancer detection. IEEE transactions on nanobioscience, 2004. 3(4): p. 251-256.
31.Nagrath, S., et al., Isolation of rare circulating tumour cells in cancer patients by microchip technology. Nature, 2007. 450(7173): p. 1235.
32.Hosokawa, M., et al., Size-selective microcavity array for rapid and efficient detection of circulating tumor cells. Analytical chemistry, 2010. 82(15): p. 6629-6635.
33.Sarioglu, A.F., et al., A microfluidic device for label-free, physical capture of circulating tumor cell clusters. Nature Methods, 2015. 12(7): p. 685-+.
34.Vona, G., et al., Isolation by size of epithelial tumor cells : a new method for the immunomorphological and molecular characterization of circulatingtumor cells. Am J Pathol, 2000. 156(1): p. 57-63.
35.Vona, G., et al., Isolation by size of epithelial tumor cells: a new method for the immunomorphological and molecular characterization of circulating tumor cells. The American journal of pathology, 2000. 156(1): p. 57-63.
36.Desitter, I., et al., A new device for rapid isolation by size and characterization of rare circulating tumor cells. Anticancer research, 2011. 31(2): p. 427-441.
37.Desitter, I., et al., A new device for rapid isolation by size and characterization of rare circulating tumor cells. Anticancer Res, 2011. 31(2): p. 427-41.
38.Adams, D.L., et al., The systematic study of circulating tumor cell isolation using lithographic microfilters. RSC advances, 2014. 4(9): p. 4334-4342.
39.Tang, C.-M., et al., Filtration and Analysis of Circulating Cancer Associated Cells from the Blood of Cancer Patients. Biosensors and Biodetection: Methods and Protocols, Volume 2: Electrochemical, Bioelectronic, Piezoelectric, Cellular and Molecular Biosensors, 2017: p. 511-524.
40.Riahi, R., et al., A novel microchannel-based device to capture and analyze circulating tumor cells (CTCs) of breast cancer. International Journal of Oncology, 2014. 44(6): p. 1870-1878.
41.Gogoi, P., et al., Development of an Automated and Sensitive Microfluidic Device for Capturing and Characterizing Circulating Tumor Cells (CTCs) from Clinical Blood Samples. Plos One, 2016. 11(1).
42.Gogoi, P., et al., Development of an automated and sensitive microfluidic device for capturing and characterizing circulating tumor cells (CTCs) from clinical blood samples. PloS one, 2016. 11(1): p. e0147400.
43.Chudziak, J., et al., Clinical evaluation of a novel microfluidic device for epitope-independent enrichment of circulating tumour cells in patients with small cell lung cancer. Analyst, 2016. 141(2): p. 669-678.
44.Xu, L., et al., Optimization and evaluation of a novel size based circulating tumor cell isolation system. PloS one, 2015. 10(9): p. e0138032.
45.Lewis, S.M., et al., Dacie and Lewis practical haematology. 10th ed. 2006, Philadelphia: Churchill Livingstone/Elsevier. xiii, 722 p.
46.Alvankarian, J., A. Bahadorimehr, and B. Yeop Majlis, A pillar-based microfilter for isolation of white blood cells on elastomeric substrate. Biomicrofluidics, 2013. 7(1): p. 14102.
47.Allard, W.J., et al., Tumor cells circulate in the peripheral blood of all major carcinomas but not in healthy subjects or patients with nonmalignant diseases. Clinical Cancer Research, 2004. 10(20): p. 6897-6904.
48.Park, J.M., et al., Highly efficient assay of circulating tumor cells by selective sedimentation with a density gradient medium and microfiltration from whole blood. Anal Chem, 2012. 84(17): p. 7400-7.
49.Brenner, H., M. Kloor, and C.P. Pox, Colorectal cancer. Lancet, 2014. 383(9927): p. 1490-1502.
50.Mu, L., et al., Small-sized colorectal cancer cells harbor metastatic tumor-initiating cells. Oncotarget, 2017. 8(64): p. 107907-107919.
51.M. Jackson, J., et al., Materials and microfluidics: Enabling the efficient isolation and analysis of circulating tumour cells. Vol. 46. 2017.
52.Wei, H.B., et al., Particle sorting using a porous membrane in a microfluidic device. Lab on a Chip, 2011. 11(2): p. 238-245.
53.Moon, H.S., et al., Continuous separation of breast cancer cells from blood samples using multi-orifice flow fractionation (MOFF) and dielectrophoresis (DEP). Lab on a Chip, 2011. 11(6): p. 1118-1125.
54.Gorbet, M.B. and M.V. Sefton, Biomaterial-associated thrombosis: roles of coagulation factors, complement, platelets and leukocytes. Biomaterials, 2004. 25(26): p. 5681-5703.
55.Courtney, J.M., et al., Biomaterials for blood-contacting applications. Biomaterials, 1994. 15(10): p. 737-744.
56.Brisbois, E.J., Novel Nitric Oxide (NO)-Releasing Polymers and Their Biomedical Applications. 2014, University of Michigan.
57.Coumans, F.A., et al., Filter characteristics influencing circulating tumor cell enrichment from whole blood. PLoS One, 2013. 8(4): p. e61770.
58.Coumans, F.A.W., et al., Filtration Parameters Influencing Circulating Tumor Cell Enrichment from Whole Blood. Plos One, 2013. 8(4).
59.Xu, L.-C., J. W Bauer, and C. A Siedlecki, Proteins, Platelets, and Blood Coagulation at Biomaterial Interfaces. Vol. 124. 2014. 49-68.
60.Hlady, V. and J. Buijs, Protein adsorption on solid surfaces. Current Opinion in Biotechnology, 1996. 7(1): p. 72-77.
61.Protein‐Surface Interactions, in An Introduction To Tissue‐Biomaterial Interactions.
62.Shaoyi, J. and C. Zhiqiang, Ultralow‐Fouling, Functionalizable, and Hydrolyzable Zwitterionic Materials and Their Derivatives for Biological Applications. Advanced Materials, 2010. 22(9): p. 920-932.
63.Jo, S. and K. Park, Surface modification using silanated poly(ethylene glycol)s. Biomaterials, 2000. 21(6): p. 605-616.
64.Xiao, X.-F., X.-Q. Jiang, and L.-J. Zhou, Surface Modification of Poly Ethylene Glycol to Resist Nonspecific Adsorption of Proteins. Chinese Journal of Analytical Chemistry, 2013. 41(3): p. 445-453.
65.Verhoef, J.J.F. and T.J. Anchordoquy, Questioning the use of PEGylation for drug delivery. Drug Delivery and Translational Research, 2013. 3(6): p. 499-503.
66.Lowe, A.B. and C.L. McCormick, Synthesis and Solution Properties of Zwitterionic Polymers. Chemical Reviews, 2002. 102(11): p. 4177-4190.
67.Yang, W., et al., Functionalizable and ultra stable nanoparticles coated with zwitterionic poly(carboxybetaine) in undiluted blood serum. Biomaterials, 2009. 30(29): p. 5617-5621.
68.Chen, S., et al., Surface hydration: Principles and applications toward low-fouling/nonfouling biomaterials. Polymer, 2010. 51(23): p. 5283-5293.
69.Genzer, J., Soft Matter Gradient Surfaces: Methods and Applications. 2012.
70.Zhao, X. and R. Kopelman, Mechanism of Organosilane Self-Assembled Monolayer Formation on Silica Studied by Second-Harmonic Generation. The Journal of Physical Chemistry, 1996. 100(26): p. 11014-11018.
71.Ulman, A., Formation and Structure of Self-Assembled Monolayers. Chemical Reviews, 1996. 96(4): p. 1533-1554.
72.Celestin, M., et al., A review of self-assembled monolayers as potential terahertz frequency tunnel diodes. Nano Research, 2014. 7(5): p. 589-625.
73.Nicosia, C. and J. Huskens, Reactive self-assembled monolayers: from surface functionalization to gradient formation. Materials Horizons, 2014. 1(1): p. 32-45.
74.Gooding, J.J. and S. Ciampi, The molecular level modification of surfaces: from self-assembled monolayers to complex molecular assemblies. Chemical Society Reviews, 2011. 40(5): p. 2704-2718.
75.Gilles, S., Chemical Modification of Silicon Surfaces for the Application in Soft Lithography. 2007: Forschungszentrum, Zentralbibliothek.
76.Arkles, B., Tailoring Surfaces with Silanes. Vol. 7. 1977. 766-778.
77.Mittal, K.L., Silanes and Other Coupling Agents, Volume 3. 2004: CRC Press.
78.Wu, L., et al., Synthesis of a Zwitterionic Silane and Its Application in the Surface Modification of Silicon-Based Material Surfaces for Improved Hemocompatibility. ACS Applied Materials & Interfaces, 2010. 2(10): p. 2781-2788.
79.Bagwe, R.P., L.R. Hilliard, and W. Tan, Surface Modification of Silica Nanoparticles to Reduce Aggregation and Nonspecific Binding. Langmuir, 2006. 22(9): p. 4357-4362.
80.Hailin, C., et al., Synthesis of monodisperse silica microspheres and modification with diazoresin for mixed‐mode ultra high performance liquid chromatography separations. Journal of Separation Science, 2017. 40(22): p. 4320-4328.
81.Nanda, D., et al., Self-assembled monolayer of functionalized silica microparticles for self-cleaning applications. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2017. 529: p. 231-238.
82.Grama, S. and D. Horák, Preparation of Monodisperse Porous Silica Particles Using Poly(Glycidyl Methacrylate) Microspheres as a Template. Vol. 64. 2015. S11-S17.
83.Demir, A. and A. Serpengüzel, Silica microspheres for biomolecular detection applications. Vol. 152. 2005. 105-8.
84.Huang, K.-T., S.-B. Yeh, and C.-J. Huang, Surface Modification for Superhydrophilicity and Underwater Superoleophobicity: Applications in Antifog, Underwater Self-Cleaning, and Oil–Water Separation. ACS Applied Materials & Interfaces, 2015. 7(38): p. 21021-21029.
85.Wenten, I.G., et al., Chapter 11 - The Bubble Gas Transport Method, in Membrane Characterization. 2017, Elsevier. p. 199-218.
86.Estephan, Z.G., J.A. Jaber, and J.B. Schlenoff, Zwitterion-Stabilized Silica Nanoparticles: Toward Nonstick Nano. Langmuir, 2010. 26(22): p. 16884-16889.
87.Stolnik, S., et al., The effect of surface coverage and conformation of poly(ethylene oxide) (PEO) chains of poloxamer 407 on the biological fate of model colloidal drug carriers. Biochimica et Biophysica Acta (BBA) - Biomembranes, 2001. 1514(2): p. 261-279.
88.Zhao, C., et al., Effect of Film Thickness on the Antifouling Performance of Poly(hydroxy-functional methacrylates) Grafted Surfaces. Langmuir, 2011. 27(8): p. 4906-4913.
89.Lankoff, A., et al., Effect of surface modification of silica nanoparticles on toxicity and cellular uptake by human peripheral blood lymphocytes in vitro. Vol. 7. 2012.
90.Sahu, D., et al., In Vitro Cytotoxicity of Nanoparticles: A Comparison between Particle Size and Cell Type. Vol. 2016. 2016.
91.Bimbo, L.M., et al., Cellular interactions of surface modified nanoporous silicon particles. Nanoscale, 2012. 4(10): p. 3184-3192.
92.Kettiger, H., et al., Interactions between silica nanoparticles and phospholipid membranes. Biochimica et Biophysica Acta (BBA) - Biomembranes, 2016. 1858(9): p. 2163-2170.
93.Aprioku, J.S., Pharmacology of free radicals and the impact of reactive oxygen species on the testis. J Reprod Infertil, 2013. 14(4): p. 158-72.
94.Kettiger, H.E., Silica nanoparticles and their interaction with cells: a multidisciplinary approach. 2014, University_of_Basel.
95.H., d.B.P.P., The amoeboid movement of the mammalian leukocyte in tissue culture. The Anatomical Record, 1946. 95(2): p. 177-191.
96.Jack, R.M., et al., Ultra‐Specific Isolation of Circulating Tumor Cells Enables Rare‐Cell RNA Profiling. Adv Sci (Weinh), 2016. 3(9).
97.de Wit, S., et al., The detection of EpCAM(+) and EpCAM(-) circulating tumor cells. Vol. 5. 2015. 12270. |