References

James F. Leary

doi:10.1017/9781139012898.016

References

Published online by Cambridge University Press: 08 March 2022

James F. Leary

Show author details

James F. Leary: Affiliation:
Purdue University, Indiana

Book contents

Get access

Summary

A summary is not available for this content so a preview has been provided. Please use the Get access link above for information on how to access this content.

Image of the first page of this content. For PDF version, please use the ‘Save PDF’ preceeding this image.'

Type: Chapter
Information: Fundamentals of Nanomedicine , pp. 310 - 322

DOI: https://doi.org/10.1017/9781139012898.016 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2022

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

ADEREM, A., and UNDERHILL, D. M. 1999. Mechanisms of phagocytosis in macrophages. Annual Review of Immunology, 17, 593–623.Google Scholar

ANASTAS, P. T., and WARNER, J. C. 2000. Green Chemistry: Theory and Practice. New York: Oxford University Press.Google Scholar

ARYAL, S., PARK, H., LEARY, J. F., and KEY, J. 2019. Top-down fabrication-based nano/microparticles for molecular imaging and drug delivery. International Journal of Nanomedicine, 14, 6631–6644.Google Scholar

BABER, N., and PRITCHARD, D. 2003. Dose estimation for children. British Journal of Clinical Pharmacology, 56, 489–493.Google Scholar

BAEZ, A. 1967. The New College Physics: A Spiral Approach. New York: Freeman.Google Scholar

BAGASRA, O. 2007. Protocols for the in situ PCR-amplification and detection of mRNA and DNA sequences. Nature Protocols, 2, 2782–2795.CrossRef Google Scholar PubMed

BAGASRA, O. 2008. In situ polymerase chain reaction and hybridization to detect low-abundance nucleic acid targets. Current Protocols in Molecular Biology, 82, 14.1–14.28.Google Scholar

BAILEY, J. M., and HADDAD, W. M. 2005. Drug dosing control in clinical pharmacology. IEEE Control Systems Magazine, 25, 35–51.Google Scholar

BANDURA, D. M., BARANOV, V. I., ORNATSKY, O. I., et al. 2009. Mass cytometry: Technique for real time single cell multitarget immunoassay based on inductively coupled plasma time-of-flight mass spectrometry. Analytical Chemistry, 81, 6813–6822.Google Scholar

BARRAS, D., and WIDMANN, C. 2011. Promises of apoptosis-inducing peptides in cancer therapeutics. Current Pharmaceutical Biotechnology, 12, 1153–1165.CrossRef Google Scholar PubMed

BARTENEVA, N. S., and VOROBJEV, I. A. 2016. Imaging Flow Cytometry: Methods and Protocols. In Methods in Molecular Biology, vol. 1389. New York: Springer.Google Scholar

BATES, M., HUANG, B., and ZHUANG, X. 2008. Super-resolution microscopy by nanoscale localization of photo-switchable fluorescent probes. Current Opinion in Chemical Biology, 12, 505–514.Google Scholar

BAWA, R. 2011. Regulating nanomedicine: Can the FDA handle it? Current Drug Delivery, 8, 227–234.CrossRef Google Scholar

BAWA, R. 2013. FDA and nanotech: Baby steps lead to regulatory uncertainty. In DEBASIS BAGCHI, M. B., MORIYAMA, H., and SHAHIDI, F., eds., Bio-Nanotechnology: A Revolution in Food, Biomedical and Health Sciences. New York: John Wiley, pp. 720–732.Google Scholar

BENIHOUD, K., YEH, P., and PERRICAUDET, M. 1999. Adenovirus vectors for gene delivery. Current Opinion in Biotechnology, 10, 440–447.CrossRef Google Scholar PubMed

BENYUS, J. M. 1997. Biomimicry: Innovation Inspired by Nature. New York: HarperCollins.Google Scholar

BERGTROM, C. 2020. Endocytosis and Exocytosis. Libretexts Biology. https://bio.libretexts.org/@go/page/16523.Google Scholar

BETZIG, E., PATTERSON, G. H., SOUGRAT, R., et al. 2006. Imaging intracellular fluorescent proteins at nanometer resolution. Science, 313, 1643–1645.CrossRef Google Scholar PubMed

BHATTACHARJEE, S. 2016. DLS and zeta potential: What they are and what they are not? Journal of Controlled Release, 235, 337–351.Google Scholar

BISCHEL, L. L., BEEBE, D. J., and SUNG, K. E. 2015. Microfluidic model of ductal carcinoma in situ with 3D, organotypic structure. BMC Cancer, 15, 1–10.Google Scholar

BISSELL, M. J., RADISKY, D. C., RIZKI, A., WEAVER, V. M., and PETERSEN, O. W. 2002. The organizing principle: Microenvironmental influences in the normal and malignant breast. Differentiation, 70, 537–546.Google Scholar

BISWAS, D., GANESHALINGAM, J., and WAN, J. C. M. 2020. The future of liquid biopsy. The Lancet Oncology, 21, e550.Google Scholar

BLIND, M., and BLANK, M. 2015. Aptamer selection technology and recent advances. Molecular Therapy Nucleic Acids, 4, e223.Google Scholar

BURDA, C., CHEN, X., NARAYANAN, R., and EL-SAYED, M. A. 2005. Chemistry and properties of nanocrystals of different shapes. Chemistry Review, 105, 1025–1102.CrossRef Google Scholar PubMed

CAMPBELL, N. A., and REECE, J. B. 2002. Biology. San Francisco: Benjamin Cummings.Google Scholar PubMed

CERVADORO, A., CHO, M., KEY, J., et al. 2014. Synthesis of multifunctional magnetic nanoflakes for magnetic resonance imaging, hyperthermia, and targeting. ACS Applied Materials & Interfaces, 6, 12939–12946.Google Scholar

CHADWICK, A. C., and MUSUNURU, K. 2018. CRISPR-Cas9 genome editing for treatment of atherogenic dyslipidemia. Arteriosclerosis, Thrombosis, and Vascular Biology, 38, 12–18.CrossRef Google Scholar PubMed

CHAN, S. M., OLSON, J. A., and UTZ, P. J. 2006. Single-cell analysis of siRNA-mediated gene silencing using multiparameter flow cytometry. Cytometry A, 69, 59–65.Google Scholar

CHAN, W. H., SHIAO, N. H., and LU, P. Z. 2006. CdSe quantum dots induce apoptosis in human neuroblastoma cells via mitochondrial-dependent pathways and inhibition of survival signals. Toxicology Letters, 167, 191–200.Google Scholar

CHITHRANI, B. D., GHAZANI, A. A., and CHAN, W. C. 2006. Determining the size and shape dependence of gold nanoparticle uptake into mammalian cells. Nano Letters, 6, 662–668.Google Scholar

CHO, Y.-B., LEE, I.-G., JOO, Y.-H., HONG, S.-H., and SEO, Y.-J. 2020. TCR transgenic mice: A valuable tool for studying viral immunopathogenesis mechanisms. International Journal of Molecular Sciences, 21, 1–12.Google Scholar

CONG, L., RAN, F. A., COX, D., et al. 2013. Multiplex genome engineering using CRISPR/Cas systems. Science, 339, 819–823.Google Scholar

COOPER, C. L., and LEARY, J. F. 2014. High-speed flow cytometric analysis of nanoparticle targeting to rare leukemic stem cells in peripheral human blood: Preliminary in-vitro studies. SPIE Imaging, Manipulation, and Analysis of Biomolecules, Cells, and Tissues XII. Proceedings of SPIE.Google Scholar

COOPER, C. L., and LEARY, J. F. 2015. Advanced flow cytometric analysis of nanoparticle targeting to rare leukemic stem cells in peripheral human blood in a defined model system. SPIE Imaging, Manipulation, and Analysis of Biomolecules, Cells, and Tissues XIII. Proceedings of SPIE.Google Scholar

COOPER, C. L., REECE, L. M., KEY, J., BERGSTROM, D. E., and LEARY, J. F. 2008. Water-soluble iron oxide nanoparticles for nanomedicine. West Lafayette, IN: Purdue e-Pubs.Google Scholar

CORSETTI, J. P., COX, C., LEARY, J. F., et al. 1987. Comparison of quantitative acid-elution technique and flow cytometry for detecting fetomaternal hemorrhage. Annals of Clinical & Laboratory Science, 17, 197–206.Google Scholar PubMed

COVEY, S. 1989. The Seven Habits of Highly Effective People: Restoring the Character Ethic. New York: Simon & Schuster.Google Scholar

COWLING, T., and FREY, N. 2019. Macrocyclic and Linear Gadolinium Based Contrast Agents for Adults Undergoing Magnetic Resonance Imaging: A Review of Safety. Ottawa: Canadian Agency for Drugs and Technology in Health.Google Scholar PubMed

CRIBBS, A. P., and PERERA, S. M. W. 2017. Science and bioethics of CRISPR-Cas9 gene editing: An analysis towards separating facts and fiction. Yale Journal of Biology and Medicine, 90, 625–634.Google Scholar

CRISSMAN, H. A., and TOBEY, R. A. 1974. Cell-cycle analysis in 20 minutes. Science, 184, 1297–1298.CrossRef Google Scholar

CZERNIN, J., and PHELPS, M. E. 2002. Positron emission tomography scanning: Current and future applications. Annual Review of Medicine, 53, 89–112.Google Scholar

DARZYNKIEWICZ, Z., GALKOWSKI, D., and ZHAO, H. 2008. Analysis of apoptosis by cytometry using TUNEL assay. Methods, 44, 250–254.CrossRef Google Scholar PubMed

DARZYNKIEWICZ, Z., JUAN, G., LI, X., et al. 1997. Cytometry in cell necrobiology: Analysis of apoptosis and accidental cell death (necrosis). Cytometry, 27, 1–20.Google Scholar

DEAN, P. N., and Jett., J. H. 1974. Mathematical analysis of DNA distributions derived from flow microfluorometry. Cell Biology, 60, 523–527.CrossRef Google Scholar PubMed

DE JONGE, N., and PECKYS, D. B. 2016. Live cell electron microscopy is probably impossible. ACS Nano, 10, 9061–9063.CrossRef Google Scholar PubMed

DE LA RICA, R., PEJOUX, C., and MATSUI, H. 2011. Assemblies of functional peptides and their applications in building blocks for biosensors. Advanced Functional Materials, 21, 1018–1026.Google Scholar

DE LIMA, R., SEABRA, A. B., and DURAN, N. 2012. Silver nanoparticles: A brief review of cytotoxicity and genotoxicity of chemically and biogenically synthesized nanoparticles. Journal of Applied Toxicology, 32, 867–879.Google Scholar

DE SOUZA, D., NOGUEIRA, C. R., ROSTELATO, B., and ROSTELATO, M. E. C. M. 2019. Review of the methodologies used in the synthesis gold nanoparticles by chemical reduction. Journal of Alloys and Compounds, 798, 714–740.Google Scholar

DI NARDO, F., CAVALERA, S., BAGGIANI, C., GIOVANNOLI, C., and ANFOSSI, L. 2019. Direct vs. mediated coupling of antibodies to gold nanoparticles: The case of salivary cortisol detection by lateral flow immunoassay. ACS Applied Materials & Interfaces, 11, 32758–32768.Google Scholar

DOUDNA, J. A., and STERNBERG, S. H. 2018. A Crack in Creation: Gene Editing and the Unthinkable Power to Control Evolution. Boston: Marriner Books.Google Scholar

DREXLER, E. 1991. Molecular machinery and manufacturing with applications to computation. Unpublished PhD thesis, Massachusetts Institute of Technology.Google Scholar

DUAN, H., WANG, D., and LI, Y. 2015. Green chemistry for nanoparticle synthesis. Chemical Society Reviews, 44, 5778–5792.Google Scholar

DUVAL, A., AIDE, A., BELLEMAIN, A., et al. 2007. Anisotropic surface-plasmon resonance imaging biosensor. Proceedings of SPIE.Google Scholar

EATON, P., QUARESMA, P., SOARES, C., et al. 2017. A direct comparison of experimental methods to measure dimensions of synthetic nanoparticles. Ultramicroscopy, 182, 179–190.Google Scholar

EFRONI, I., IP, P. L., NAWY, T., MELLO, A., and BIRNBAUM, K. D. 2015. Quantification of cell identity from single-cell gene expression profiles. Genome Biology, 16, 1–12.Google Scholar

EUSTAQUIO, T., COOPER, C. L., and LEARY, J. F. 2011. Single-cell imaging detection of nanobarcoded nanoparticle biodistributions in tissues for nanomedicine. SPIE Reporters, Markers, Dyes, Nanoparticles, and Molecular Probes for Biomedical Applications III. Proceedings of SPIE, 7910, 791000-1–79100O-11.Google Scholar

EUSTAQUIO, T., and LEARY, J. F. 2011. Nanobarcoding: A novel method of single nanoparticle detection in cells and tissues for nanomedical biodistribution studies. SPIE Biosensing and Nanomedicine IV. Proceedings of SPIE, 8099, 80990V-1–80990V-13.Google Scholar

EUSTAQUIO, T., and LEARY, J. F. 2012a. Nanobarcoding: Detecting nanoparticles in biological samples using in situ polymerase chain reaction. International Journal of Nanomedicine, 7, 5625–5639.Google Scholar

EUSTAQUIO, T., and LEARY, J. F. 2012b. Single-cell nanotoxicity assays of superparamagnetic iron oxide nanoparticles. Methods in Molecular Biology, 926, 69–85.Google Scholar

FEYNMAN, R. 1960. There’s plenty of room at the bottom. Engineering Science, 23, 22–36.Google Scholar

FLANNIGAN, D. J., BARWICK, B., and ZEWAIL, A. H. 2010. Biological imaging with 4D ultrafast electron microscopy. Proceedings of the National Academy of Sciences of the United States of America, 107, 9933–9937.Google Scholar

FOTAKIS, G., and TIMBRELL, J. A. 2006. In vitro cytotoxicity assays: Comparison of LDH, neutral red, MTT and protein assay in hepatoma cell lines following exposure to cadmium chloride. Toxicology Letters, 160, 171–177.Google Scholar

FRANGOUL, H., ALTSHULER, D., CAPPELLINI, M. D., et al. 2021. CRISPR-Cas9 gene editing for sickle cell disease and β-thalassemia. New England Journal of Medicine, 384, 252–260.Google Scholar

FREITAS, R. A. 1999. Nanomedicine. Volume 1: Basic Capabilities. Georgetown, TX: Landes Bioscience.Google Scholar

FREITAS, R. A. Jr. 2005. What is nanomedicine? Nanomedicine, 1, 2–9.Google Scholar

FRIGERIO, B., BIZZONI, C., JANSEN, G., et al. 2019. Folate receptors and transporters: Biological role and diagnostic/therapeutic targets in cancer and other diseases. Journal of Experimental & Clinical Cancer Research, 38, 1–12.Google Scholar

FU, Z., and XIANG, J. 2020. Aptamer-functionalized nanoparticles in targeted delivery and cancer therapy. International Journal of Molecular Sciences, 21, https://doi.org/10.3390/ijms21239123.CrossRef Google Scholar PubMed

FULKERSON, C. M., DHAWAN, D., RATLIFF, T. L., HAHN, N. M., and KNAPP, D. W. 2017. Naturally occurring canine invasive urinary bladder cancer: A complementary animal model to improve the success rate in human clinical trials of new cancer drugs. International Journal of Genomics, 2017, 1–9.Google Scholar

GAJ, T., GERSBACH, C. A., and BARBAS, C. F. 2013. ZFN, TALEN, and CRISPR/Cas-based methods for genome engineering. Trends in Biotechnology, 31, 397–405.Google Scholar

GARTNER. 2020. Gartner hype cycle methodology. https://www.gartner.com/en/newsroom/press-releases/2020-08-18.Google Scholar

GETTS, D. R., GETTS, M. T., MCCARTHY, D. P., CHASTAIN, E. M. L., and MILLER, S. D. 2014. Have we overestimated the benefit of human(ized) antibodies? mAbs, 2, 682–694.Google Scholar

GIVAN, A. L. 2001. Flow Cytometry: First Principles. New York: Wiley-Liss.Google Scholar

GOETZ, C., HAMMERBECK, C., and BONNEVIER, J. 2018. Flow Cytometry Basics for the Non-Expert. New York: Springer.Google Scholar

GONG, J., TRAGANOS, F., and DARZYNKIEWICZ, Z. 1995. Growth imbalance and altered expression of cyclins B1, A, E, and D3 in MOLT-4 cells synchronized in the cell cycle by inhibitors of DNA replication. Cell Growth & Differentiation 6, 1485–1493.Google Scholar

GONZÁLEZ, A. L., NOGUEZ, C., BERÁNEK, J., and BARNARD, A. S. 2014. Size, shape, stability, and color of plasmonic silver nanoparticles. Journal of Physical Chemistry C, 118, 9128–9136.Google Scholar

GORCZYCA, W., BRUNO, S., DARZYNKIEWICZ, R. J., GONG, J., and DARZYNKIEWICZ, Z. 1992. DNA strand breaks occurring during apoptosis: Their early in situ detection by the terminal deoxynucleotidyl transferase and nick translation assays and prevention by serine protease inhibitors. International Journal of Oncology, 1, 639–648.Google Scholar

GRAFTON, M. M., WANG, L., VIDI, P. A., LEARY, J., and LELIEVRE, S. A. 2011. Breast on-a-chip: Mimicry of the channeling system of the breast for development of theranostics. Integrative Biology, 3, 451–459.CrossRef Google Scholar PubMed

GRATZNER, H. G., LEIF, R. C., INGRAHAM, D. J., and CASTRO, A. 1975. The use of antibody specific for bromodeoxyuridine for the immunofluorescent determination of DNA replication in single cells and chromosomes. Experimental Cell Research, 95, 88–94.Google Scholar

GURUNATHAN, S., KIM, E., HAN, J. W., PARK, J. H., and KIM, J. H. 2015. Green chemistry approach for synthesis of effective anticancer palladium nanoparticles. Molecules, 20, 22476–22498.Google Scholar

HAGLUND, E., SEALE, M.-M., and LEARY, J. F. 2009. Design of multifunctional nanomedical systems. Annals of Biomedical Engineering, 37, 2048–2063.Google Scholar

HAGLUND, E. M., SEALE-GOLDSMITH, M.-M., DHAWAN, D., et al. 2008. Peptide targeting of quantum dots to human breast cancer cells. Proceedings of SPIE, 6866, 68660S-1–68660S-8.Google Scholar

HAMID, R., ROTSHTEYN, Y., RABADI, L., PARIKH, R., and BULLOCK, P. 2004. Comparison of alamar blue and MTT assays for high through-put screening. Toxicology in Vitro, 18, 703–710.CrossRef Google Scholar PubMed

HAYFLICK, L. 1965. The limited in-vitro lifetime of human diploid cell strains. Experimental Cell Research, 37, 614–636.Google Scholar

HILDEBRANDT, C. C., and MARRON, J. M. 2018. Justice in CRISPR-Cas9 research and clinical applications. AMA Journal of Ethics, 20, E826–E833.Google Scholar

HONARY, S., and ZAHIR, F. 2013. Effect of zeta potential on the properties of nano-drug delivery systems: A review (part 2). Tropical Journal of Pharmaceutical Research, 12, 265–273.Google Scholar

HOOD, M. A., MARI, M., and MUNOZ-ESPI, R. 2014. Synthetic strategies in the preparation of polymer/inorganic hybrid nanoparticles. Materials (Basel), 7, 4057–4087.Google Scholar

HUH, D., MATTHEWS, B. D., MAMMOTO, A., et al. 2010. Reconstituting organ-level lung functions on a chip. Science, 328, 1662–1668.Google Scholar

IANNELLO, A., and AHMAD, A. 2005. Role of antibody-dependent cell-mediated cytotoxicity in the efficacy of therapeutic anti-cancer monoclonal antibodies. Cancer and Metastasis Reviews 24, 487–499.Google Scholar

INTERNATIONAL COUNCIL OF CHEMICAL ASSOCIATIONS. An Executive Guide: How to Know If and When It’s Time to Commission a Life Cycle Assessment. Amsterdam, Netherlands: ICCA.Google Scholar

JALILI, N., and LAXMINARAYANA, K. 2004. A review of atomic force microscopy imaging systems: Application to molecular metrology and biological sciences. Mechatronics, 14, 907–945.Google Scholar

JETT, J. H., STEVENSON, A. P., WARNER, N. L., and LEARY, J. F. 1980. Quantitation of cell surface antigen density by flow cytometry. In LAERUM, O. D., LINDMO, T., and THORUD, L., eds., Flow Cytometry and Sorting. New York: Columbia University Press.Google Scholar

JINEK, M., CHYLINSKI, K., FONFARA, I. E., et al. 2012. A programmable dual-RNA–guided DNA endonuclease in adaptive bacterial immunity. Science, 337, 816–821.Google Scholar

JOHNSON, W. R., WILSON, D. W., and BEARMAN, G. 2006. Spatial-spectral modulating snapshot hyperspectral imager. Applied Optics, 45, 1898–1908.Google Scholar

JULIANO, R. L. 2012. The future of nanomedicine: Promises and limitations. Science and Public Policy, 39, 99–104.Google Scholar

JUNGER, S. 1997. The Perfect Storm. New York: Norton.Google Scholar

KANG, H., MINTRI, S., MENON, A. V., et al. 2015. Pharmacokinetics, pharmacodynamics and toxicology of theranostic nanoparticles. Nanoscale, 7, 18848–18862.Google Scholar

KEEFE, A. D., PAI, S., and ELLINGTON, A. 2010. Aptamers as therapeutics. Nature Reviews Drug Discovery, 9, 537–550.Google Scholar

KEY, J., COOPER, C., KIM, A. Y., et al. 2012. In vivo NIRF and MR dual-modality imaging using glycol chitosan nanoparticles. Journal of Controlled Release, 163, 249–255.Google Scholar

KEY, J., DHAWAN, D., COOPER, C. L., et al. 2016. Multicomponent, peptide-targeted glycol chitosan nanoparticles containing ferrimagnetic iron oxide nanocubes for bladder cancer multimodal imaging. International Journal of Nanomedicine, 11, 4141–4155.CrossRef Google Scholar PubMed

KEY, J., DHAWAN, D., KNAPP, D. W., et al. 2012. Design of peptide-conjugated glycol chitosan nanoparticles for near infrared fluorescent (NIRF) in vivo imaging of bladder tumors. Proceedings of SPIE, 8233, 8233R1–8233R10.Google Scholar

KEY, J., KIM, K.., DHAWAN, D., et al. 2011. Dual-modality in vivo imaging for MRI detection of tumors and NIRF-guided surgery using multi-component nanoparticles. SPIE Nanoscale Imaging, Sensing, and Actuation for Biomedical Applications VIII. Proceedings of SPIE, 7908, 790805-1–790805-8.Google Scholar

KEY, J., and LEARY, J. F. 2014. Nanoparticles for multimodal in vivo imaging in nanomedicine. International Journal of Nanomedicine, 9, 711–726.Google Scholar

KIM, J. S., KUK, E., YU, K. N., et al. 2007. Antimicrobial effects of silver nanoparticles. Nanomedicine, 3, 95–101.Google Scholar

KLAUDE, M., ERIKSSON, S., NYGREN, J., and AHNSTRIJM, G. 1996. The comet assay: Mechanisms and technical considerations. Mutation Research, 363, 89–96.Google Scholar

KNAPP, D. W., RAMOS-VARA, J. A., MOORE, G. E., et al. 2014. Urinary bladder cancer in dogs, a naturally occurring model for cancer biology and drug development. ILAR Journal, 55, 100–118.CrossRef Google Scholar PubMed

KOHLER, G., and MILSTEIN, C. 1975. Continuous cultures of fused cells secreting antibody of predefined specificity. Nature, 256, 495–497.CrossRef Google Scholar PubMed

KRPETIC, Z., NATIVO, P., PRIOR, I. A., and BRUST, M. 2011. Acrylate-facilitated cellular uptake of gold nanoparticles. Small, 7, 1982–1986.Google Scholar

KRUTH, H. S. 2011. Receptor-independent fluid-phase pinocytosis mechanisms for induction of foam cell formation with native low-density lipoprotein particles. Current Opinion in Lipidology, 22, 386–393.Google Scholar

KRUTZIK, P. O., IRISH, J. M., NOLAN, G. P., and PEREZ, O. D. 2004. Analysis of protein phosphorylation and cellular signaling events by flow cytometry: Techniques and clinical applications. Clinical Immunology, 110, 206–221.Google Scholar

KRUTZIK, P. O., and NOLAN, G. P. 2003. Intracellular phospho-protein staining techniques for flow cytometry: Monitoring single cell signaling events. Cytometry A, 55, 61–70.Google Scholar

KUMAR, C. S. S. R., ed. 2005. Nanotechnologies for the Life Sciences. 1st ed. Weinheim: Wiley-VCH.Google Scholar

LAI, C.-Y., TREWYN, B. G., JEFTINIJA, D. M., et al. 2003. A mesoporous silica nanosphere-based carrier system with chemically removable CdS nanoparticle caps for stimuli-responsive controlled release of neurotransmitters and drug molecules. Journal of the American Chemical Society, 125, 4451–4459.Google Scholar

LEARY, J. F. 1994. Strategies for rare cell detection and isolation. Methods in Cell Biology, 42, 331–358.CrossRef Google Scholar PubMed

LEARY, J. F. 2005. Ultra high-speed sorting. Cytometry A, 67, 76–85.Google Scholar

LEARY, J. F. 2007. Invited Talk at FDA: “Single-Cell Nanotoxicity Measures of Nanomedical Systems.” March 7.Google Scholar

LEARY, J. F. 2009. Molecular characterization of rare single tumor cells. In ANSELMETTI, D., ed., Single Cell Analysis: Technologies and Applications. Weinheim: WILEY-VCH, pp. 197–221.Google Scholar

LEARY, J. F. 2010. Nanotechnology: What is it and why is small so big? Canadian Journal of Ophthalmology, 45, 449–456.Google Scholar

LEARY, J. F. 2013. Nanomedicine: Reality will trump hype! Journal of Nanomedicine and Biotherapeutic Discovery, 4, e125.Google Scholar

LEARY, J. F. 2014. Quantitative Single-Cell Approaches to Assessing Nanotoxicity in Nanomedical Systems. Boca Raton, FL: CRC Press.Google Scholar

LEARY, J. F. 2019. Design of sophisticated shaped, multilayered, and multifunctional nanoparticles for combined in-vivo imaging and advanced drug delivery. Nanoscale Imaging, Sensing, and Actuation for Biomedical Applications XVI. Proceedings of SPIE, 10891, 108910R-1–108910R-9.Google Scholar

LEARY, J. F., TODD, P. W., WOOD, J. C. S., and JETT, J. H. 1979. Laser flow cytometric light scatter and fluorescence pulse-width and pulse rise-time sizing of mammalian cells. Journal of Histochemistry and Cytochemistry, 27, 315–320.Google Scholar

LEE, J. F., HESSELBERTH, J. R., MEYERS, L. A., and ELLINGTON, A. D. 2004. Aptamer database. Nucleic Acids Research, 32, D95–D100.Google Scholar

LELIEVRE, S. A., VIDI, P.-A., LEARY, J. F., and MALEKI, T. 2018. Disease on a Chip. US Patent 9,969,964.Google Scholar

LEONG, S. S., NG, W. M., LIM, J., and YEAP, S. P. 2018. Dynamic light scattering: effective sizing technique for characterization of magnetic nanoparticles. In SHARMA, S. K., ed., Handbook of Materials Characterization. New York: Springer, pp. 77–111.Google Scholar

LI, S.-D., and HUANG, L. 2008. Pharmacokinetics and biodistribution of nanoparticles. Molecular Pharmaceutics, 5, 496–504.Google Scholar

LIANG, X. W., XU, J. Z. P., GRICE, J., et al. 2013. Penetration of nanoparticles into human skin. Current Pharmaceutical Design, 19, 6353–6366.Google Scholar

LIAO, D. L., WU, G. S., and LIAO, B. Q. 2009. Zeta potential of shape-controlled TiO₂ nanoparticles with surfactants. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 348, 270–275.Google Scholar

LOAIZA, O. A., JUBETE, E., OCHOTECO, E., et al. 2011. Gold coated ferric oxide nanoparticles based disposable magnetic genosensors for the detection of DNA hybridization processes. Biosensors and Bioelectronics, 26, 2194–2200.Google Scholar

LOO, C., LIN, A., HIRSCH, L., et al. 2004. Nanoshell-enabled photonics-based imaging and therapy of cancer. Technology in Cancer Research & Treatment, 3, 33–40.Google Scholar

LOW, P. S., SINGHAL, S., and SRINIVASARAO, M. 2018. Fluorescence-guided surgery of cancer: Applications, tools and perspectives. Current Opinion in Chemical Biology, 45, 64–72.Google Scholar

LU, G., and FEI, B. 2014. Medical hyperspectral imaging: A review. Journal of Biomedical Optics, 19, 10901.Google Scholar

LU, Y., and LOW, P. S. 2002. Folate-mediated delivery of macromolecular anticancer therapeutic agents. Advanced Drug Delivery Reviews, 54, 675–693.Google Scholar

LUISONI, S., and GREBER, U. F. 2016. Biology of adenovirus cell entry: Receptors, pathways, mechanisms. In CURIEL, D. T., ed., Adenoviral Vectors for Gene Therapy. 2nd ed. New York: Academic Press, 27–58.Google Scholar

LVOV, Y., ARIGA, K., ICHINOSE, I., and KUNITAKE, T. 1995. Assembly of multicomponent protein films by means of electrostatic layer-by-layer adsorption. Journal of the American Chemical Society, 117, 6117–6123.Google Scholar

LVOV, Y., DECHER, G., and MOEHWALD, H. 1993. Assembly, structural characterization, and thermal behavior of layer-by-layer deposited ultrathin films of poly(vinyl sulfate) and poly(allylamine). Langmuir, 9, 481–486.CrossRef Google Scholar

MALIK, P., SHANKAR, R., MALIK, V., SHARMA, N., and MUKHERJEE, T. K. 2014. Green chemistry based benign routes for nanoparticle synthesis. Journal of Nanoparticles, 2014, 1–14.Google Scholar

MALIKOVA, H., and HOLESTA, M. 2017. Gadolinium contrast agents: Are they really safe? Journal of Vascular Access, 18, 1–7.Google Scholar

MCCOY, C. P., BRADY, C., , COWLEY, J. F., et al. 2010. Triggered drug delivery from biomaterials. Expert Opinion on Drug Delivery, 7, 605–616.Google Scholar

MCCOY, C. P., ROONEY, C., EDWARDS, C. R., JONES, D. S., and GORMAN, S. P. 2007. Light-triggered molecule-scale drug dosing devices. JACS Communications, 129, 9572–9573.Google Scholar

MCKELVEY-MARTIN, V. J., GREEN, M. H. L., SCHMEZER, P., et al. 1993. The single cell gel electrophoresis assay (comet assay): A European review. Mutation Research, 288, 47–63.Google Scholar

MENG, F., WANG, J., PING, Q., and YEO, Y. 2018. Quantitative assessment of nanoparticle biodistribution by fluorescence imaging, revisited. ACS Nano, 12, 6458–6468.Google Scholar

MONTANTE, S., and BRINKMAN, R. R. 2019. Flow cytometry data analysis: Recent tools and algorithms. International Journal of Laboratory Hematology, 41 Suppl 1, 56–62.Google Scholar

MONTEIRO-RIVIERE, N. A., and TRAN, C. L. 2014. Nanotoxicology: Progress toward Nanomedicine. Boca Raton, FL: CRC Press.Google Scholar

MORALES, C. S., VALENCIA, P. M., THAKKAR, A. B., SWANSON, E., and LANGER, R. 2012. Recent developments in multifunctional hybrid nanoparticles: Opportunities and challenges in cancer therapy. Frontiers in Bioscience, E4, 529–545.Google Scholar

MOURDIKOUDIS, S., PALLARES, R. M., and THANH, N. T. K. 2018. Characterization techniques for nanoparticles: Comparison and complementarity upon studying nanoparticle properties. Nanoscale, 10, 12871–12934.Google Scholar

MOUSAVI, S. M., ZAREI, M., HASHEMI, S. A., et al. 2020. Gold nanostars-diagnosis, bioimaging and biomedical applications. Drug Metabolism Reviews, 52, 299–318.Google Scholar

MURCIA, M. J., and NAUMANN, C. A. 2005. Biofunctionalization of fluorescent nanoparticles. In KUMAR, C. S. S. R., ed., Biofunctionalization of Nanomaterials. Weinheim: Wiley-VCH, pp. 1–40.Google Scholar

MURPHY, R. F. 2005. Location proteomics: A systems approach to subcellular location. Biochemical Society Transactions, 33, 535–538.Google Scholar

NARAYAN, R., NAYAK, U. Y., RAICHUR, A. M., and GARG, S. 2018. Mesoporous silica nanoparticles: A comprehensive review on synthesis and recent advances. Pharmaceutics, 10, 1–49.Google Scholar

NATIONAL RESEARCH COUNCIL. 1983. Risk Assessment in the Federal Government: Managing the Process. Washington, DC: National Academies Press. https://doi.org/10.17226/366.Google Scholar

NIE, S., and EMORY, S. R. 1997. Probing single molecules and single nanoparticles by surface-enhanced Raman scattering. Science, 275, 1102–1106.Google Scholar

NOLAN, J. P., and SEBBA, D. S. 2011. Surface-enhanced Raman scattering (SERS) cytometry. Methods in Cell Biology, 102, 515–532.Google Scholar

OBERDORSTER, G., OBERDORSTER, E., and OBERDORSTER, J. 2005. Nanotoxicology: An emerging discipline evolving from studies of ultrafine particles. Environmental Health Perspectives, 113, 823–839.Google Scholar

OKSEL, C., SUBRAMANIAN, V., SEMENZIN, E., et al. 2016. Evaluation of existing control measures in reducing health and safety risks of engineered nanomaterials. Environmental Science: Nano, 3, 869–882.Google Scholar

OSTLING, D., and JOHANSON, K. J. 1984. Micro-electrophoretic study of radiation-induced DNA damages in individual mammalian cells. Biochemical and Biophysical Research Communications, 123, 291–298.Google Scholar

PARDI, N., HOGAN, M. J., PORTER, F. W., and WEISSMAN, D. 2018. mRNA vaccines: A new era in vaccinology. Nature Reviews Drug Discovery, 17, 261–279.Google Scholar

PARK, S.-J., SEUNGSOO, K. S., LEE, S., et al. 2000. Synthesis and magnetic studies of uniform iron nanorods and nanospheres. Journal of the American Chemical Society, 122, 8581–8582.Google Scholar

PEDNEKAR, P. P., GODIYAL, S. C., JADHAV, K. R., and KADAM, V. J. 2017. Mesoporous silica nanoparticles: A promising multifunctional drug delivery system. In FICAI, A. and GRUMEZESCU, A. M., eds., Nanostructures for Cancer Therapy. New York: Elsevier, pp. 593–621Google Scholar

PENNISI, E. 2013. The CRISPR craze. Science, 341, 833–836.Google Scholar

PEREZJUSTE, J., PASTORIZASANTOS, I., LIZMARZAN, L., and MULVANEY, P. 2005. Gold nanorods: Synthesis, characterization and applications. Coordination Chemistry Reviews, 249, 1870–1901.Google Scholar

PERFETTO, S. P., CHATTOPADHYAY, P. K., and ROEDERER, M. 2004. Seventeen-colour flow cytometry: Unravelling the immune system. Nature Reviews Immunology, 4, 648–655.Google Scholar

PIERPONT, T. M., LIMPER, C. B., and RICHARDS, K. L. 2018. Past, present, and future of rituximab: The world’s first oncology monoclonal antibody therapy. Frontiers in Oncology, 8, 1–23.Google Scholar

PONS, T., PIC, E., LEQUEUX, N., et al. 2010. Cadmium-free CuInS₂/ZnS quantum dots for sentinel lymph node imaging with reduced toxicity. ACS Nano, 4, 2531–2538.Google Scholar

PREVO, B. G., ESAKOFF, S. A., MIKHAILOVSKY, A., and ZASADZINSKI, J. A. 2008. Scalable routes to gold nanoshells with tunable sizes and response to near-infrared pulsed-laser irradiation. Small, 4, 1183–1195.Google Scholar

PROW, T., GREBE, R., MERGES, C., et al. 2006. Nanoparticle tethered antioxidant response element as a biosensor for oxygen induced toxicity in retinal endothelial cells. Molecular Vision, 12, 616–625.Google Scholar

PROW, T., SMITH, J. N., GREBE, R., et al. 2006. Construction, gene delivery, and expression of DNA tethered nanoparticles. Molecular Vision, 12, 606–615.Google Scholar

PROW, T. W. 2004. Nanomedicine: Targeted nanoparticles for the delivery of biosensors and therapeutic genes. PhD dissertation, University of Texas Medical Branch.Google Scholar

PROW, T. W., ROSE, W. A., WANG, N., et al. 2005. Biosensor-controlled gene therapy/drug delivery with nanoparticles for nanomedicine. SPIE Advanced Biomedical and Clinical Diagnostic Systems III. Proceedings of SPIE, 5692, 199–208.Google Scholar

PROW, T. W., SALAZAR, J. H., ROSE, W. A., et al. 2004. Nanomedicine: Nanoparticles, molecular biosensors, and targeted gene/drug delivery for combined single-cell diagnostics and therapeutics. SPIE Advanced Biomedical and Clinical Diagnostic Systems II. Proceedings of SPIE.Google Scholar

PUTNAM, W. P., and YANIK, M. F. 2009. Noninvasive electron microscopy with interaction-free quantum measurements. Physical Review A, 80, 1–4.Google Scholar

RASTINEHAD, A. R., ANASTOS, H., WAJSWOL, E., et al. 2019. Gold nanoshell-localized photothermal ablation of prostate tumors in a clinical pilot device study. Proceedings of the National Academy of Sciences of the Unites States of America, 116, 18590–18596.Google Scholar

ROSENBLATT, J. I., HOKANSON, J. A., MCLAUGHLIN, S. R., and LEARY, J. F. 1997. Theoretical basis for sampling statistics useful for detecting and isolating rare cells using flow cytometry and cell sorting. Cytometry, 27, 233–238.Google Scholar

ROSENBLUM, D., GUTKIN, A., KEDMI, R., et al. 2020. CRISPR-Cas9 genome editing using targeted lipid nanoparticles for cancer therapy. Science Advances, 6, 1–12.Google Scholar

ROSI, N. L., and MIRKIN, C. A. 2005. Nanostructures in biodiagnostics. Chemical Reviews, 105, 1547–1562.Google Scholar

RUDOLPH, N. S., OHLSSON-WILHELM, B. M., LEARY, J. F., and ROWLEY, P. T. 1985. Single-cell analysis of the relationship among transferrin receptors, proliferation, and cell cycle phase in K562 cells. Cytometry, 6, 151–158.CrossRef Google Scholar PubMed

SACHS, K., SARVER, A. L., NOBLE-ORCUTT, K. E., et al. 2020. Single-cell gene expression analyses reveal distinct self-renewing and proliferating subsets in the leukemia stem cell compartment in acute myeloid leukemia. Cancer Research, 80, 458–470.Google Scholar

SARGENT, J. F. 2010. The National Nanotechnology Initiative: Overview, reauthorization, and appropriations issues. CRS Report for Congress. Washington, DC: Congressional Research Service.Google Scholar

SCHLAKE, T., THESS, A., FOTIN-MLECZEK, M., and KALLEN, K. J. 2012. Developing mRNA-vaccine technologies. RNA Biology, 9, 1319–1330.Google Scholar

SCHWARTZBERG, A. M., OLSON, T. Y., TALLEY, C. E., and ZHANG, J. Z. 2006. Synthesis, characterization, and tunable optical properties of hollow gold nanospheres. Journal of Physical Chemistry B, 110, 19935–19944.Google Scholar

SEALE-GOLDSMITH, M.-M., and LEARY, J. F. 2009. Nanobiosystems. WIREs Nanomedicine and Nanobiotechnology, 1, 553–567.Google Scholar

SEALE, M.-M., HAGLUND, E., COOPER, C. L., REECE, L. M., and LEARY, J. F. 2007. Design of programmable multilayered nanoparticles with in situ manufacture of therapeutic genes for nanomedicine. SPIE: Advanced Biomedical and Clinical Diagnostic Systems V. Proceedings of SPIE, 6430, 643003-1–643003-7.Google Scholar

SEALE, M.-M., and LEARY, J. F. 2009. Nanobiosystems. In BAKER, J. R., ed., Wiley Interdisciplinary Reviews: Nanomedicine and Nanobiotechnology. New York: Wiley, pp. 553–567.Google Scholar

SEALE, M.-M., ZEMLYANOV, D., COOPER, C. L., et al. 2007. Multifunctional nanoparticles for drug/gene delivery in nanomedicine. SPIE: Nanoscale Imaging, Spectroscopy, Sensing, and Actuation for Biomedical Applications IV. Proceedings of SPIE, 6447, 64470E-1–64470E-9.Google Scholar

SHADIDI, M., and SIOUD, M. 2003. Identification of novel carrier peptides for the specific delivery of therapeutics into cancer cells. FASEB Journal, 17, 256–258.Google Scholar

SHAPIRO, H. M. 2001. Practical Flow Cytometry. Hoboken, NJ: John Wiley & Sons.Google Scholar

SIKULU, M., DOWELL, K. M., HUGO, L. E., et al. 2011. Evaluating RNAlater® as a preservative for using near-infrared spectroscopy to predict Anopheles gambiae age and species. Malaria Journal, 10, 1–7.Google Scholar

SLOWING, I. I., TREWYN, B. G., GIRI, S., and LIN, V. S. Y. 2007. Mesoporous silica nanoparticles for drug delivery and biosensing applications. Advanced Functional Materials, 17, 1225–1236.Google Scholar

SRIDHAR, V., GAUD, R., BAJAJ, A., and WAIRKAR, S. 2018. Pharmacokinetics and pharmacodynamics of intranasally administered selegiline nanoparticles with improved brain delivery in Parkinson’s disease. Nanomedicine, 14, 2609–2618.Google Scholar

STETEFELD, J., MCKENNA, S. A., and PATEL, T. R. 2016. Dynamic light scattering: A practical guide and applications in biomedical sciences. Biophysical Reviews, 8, 409–427.Google Scholar

SUN, X., ROSSIN, R., TURNER, J. L., et al. 2005. An assessment of the effects of shell cross-linked nanoparticle size, core composition, and surface PEGylation on in vivo biodistribution. Biomacromolecules, 6, 2541–2554.Google Scholar

SUSI, T., PICHLER, T., and AYALA, P. 2015. X-ray photoelectron spectroscopy of graphitic carbon nanomaterials doped with heteroatoms. Beilstein Journal of Nanotechnology, 6, 177–192.Google Scholar

SZANISZLO, P. 2007. Gene Expression Microarray Analysis of Small, Purified Cell Subsets. PhD dissertation, University of Texas Medical Branch.Google Scholar

SZANISZLO, P., WANG, N., SINHA, M., et al. 2004. Getting the right cells to the array: Gene expression microarray analysis of cell mixtures and sorted cells. Cytometry A, 59, 191–202.Google Scholar

SZOLLOSI, J., DAMJANOVICH, S., and LASZLO, M. 1998. Application of fluorescence resonance energy transfer in the clinical laboratory: Routine and research. Cytometry (Communications in Clinical Cytometry), 34, 159–179.Google Scholar

TEKADE, R. K. 2019. Basic Fundamentals of Drug Delivery. New York: Academic Press.Google Scholar

THOMAS, C. R., FERRIS, D. P., LEE, J.-H., et al. 2010. Noninvasive remote-controlled release of drug molecules in vitro using magnetic actuation of mechanized nanoparticles. Journal of the American Chemical Society, 132, 10623–10625.Google Scholar

TOY, R., and KARATHANASIS, E. 2016. Paramagnetic nanoparticles. In LU, Z.-R. and SAKUMA, S., eds., Nanomaterials in Pharmacology. New York: Springer, pp. 113–136.Google Scholar

TRON, L., SZOLLOSI, J., and DAMJANOVICH, S. 1984. Flow cytometric measurement of fluorescence resonance energy transfer. Biophysical Journal, 45, 939–946.Google Scholar

TSIEN, R. Y. 1998. The green fluorescent protein. Annual Review of Biochemistry, 67, 509–544.Google Scholar

TUCHIN, V. V., TARNOK, A., and ZHAROV, V. P. 2009. Towards in vivo flow cytometry. Journal of Biophotonics, 2, 457–460.Google Scholar

VALENCIA, L. C., GARCÍA, A., RAMÍREZ-PINILLA, M. P., and FUENTES, J. L. 2011. Estimates of DNA damage by the comet assay in the direct-developing frog Eleutherodactylus johnstonei (Anura, Eleutherodactylidae). Genetics and Molecular Biology, 34, 681–688.Google Scholar

VAN DAM, G. M., THEMELIS, G., CRANE, L. M., et al. 2011. Intraoperative tumor-specific fluorescence imaging in ovarian cancer by folate receptor-alpha targeting: First in-human results. Nature Medicine, 17, 1315–1319.Google Scholar

VAN DER MEER, A. D., and VAN DEN BERG, A. 2012. Organs-on-chips: Breaking the in vitro impasse. Integrative Biology, 4, 461–470.Google Scholar

VAN ENGELAND, M., NIELAND, L. J. W., RAMAEKERS, F. C. S., SCHUTTE, B., and REUTELINGSPERGER, C. P. M. 1998. Annexin V-affinity assay: A review on an apoptosis detection system based on phosphatidylserine exposure. Cytometry, 31, 1–9.Google Scholar

VIDI, P. A., MALEKI, T., OCHOA, M., et al. 2014. Disease-on-a-chip: Mimicry of tumor growth in mammary ducts. Lab on a Chip, 14, 172–177.Google Scholar

WAJIMA, T., YANO, Y., FUKUMURA, K., and OGUMA, T. 2004. Prediction of human pharmacokinetic profile in animal scale up based on normalizing time course profiles. Journal of Pharmaceutical Sciences, 93, 1890–1900.Google Scholar

WANG, L., WANG, K., SANTRA, S., et al. 2006. Watching silica nanoparticles glow in the biological world. Analytical Chemistry, 646–654. https://pubs.acs.org/doi/pdf/10.1021/ac0693619.Google Scholar

WANI, M. Y., HASHIM, M. A., NABI, F., and MALIK, M. A. 2011. Nanotoxicity: Dimensional and morphological concerns. Advances in Physical Chemistry, 2011, 1–15.Google Scholar

WEI, Q., SONG, H. M., LEONOV, A. P., et al. 2009. Gyromagnetic imaging: Dynamic optical contrast using gold nanostars with magnetic cores. Journal of the American Chemical Society, 131, 9728–9734.Google Scholar

WHEELESS, L., REEDER, J. E., and O’CONNELL, M. J. 1990. Slit-scan flow analysis of cytologic specimens from the female genital tract. Methods in Cell Biology, 33, 501–507.Google Scholar

WHITE-SCHENK, D., SHI, R., and LEARY, J. F. 2015. Nanomedicine strategies for treatment of secondary spinal cord injury. International Journal of Nanomedicine, 10, 923–938.Google Scholar

WORLD HEALTH ORGANIZATION. 2019. International nonproprietary names (INN) for biological and biotechnological substances: A review. In WHO, ed., WHO/EMP/RHT/TSN/2019.1. Geneva, Switzerland: WHO.Google Scholar

XIAO, Y., FORRY, S. P., GAO, X., et al. 2010. Dynamics and mechanisms of quantum dot nanoparticle cellular uptake. Journal of Nanobiotechnology, 8, 1–9.Google Scholar

YADAV, K. S., RAJPUROHIT, R., and SHARMA, S. 2019. Glaucoma: Current treatment and impact of advanced drug delivery systems. Life Sciences, 221, 362–376.Google Scholar

YANG, X., BASSETT, S. E., LI, X., et al. 2002. Construction and selection of bead-bound combinatorial oligonucleoside phosphorothioate and phosphorodithioate aptamer libraries designed for rapid PCR-based sequencing. Nucleic Acids Research, 30, 1–8.Google Scholar

YANG, X., LI, N., and GORENSTEIN, D. G. 2011. Strategies for the discovery of therapeutic aptamers. Expert Opinion on Drug Discovery, 6, 75–87.Google Scholar

YANG, X., LI, X., PROW, T. W., et al. 2003. Immunofluorescence assay and flow-cytometry selection of bead-bound aptamers. Nucleic Acids Research, 31, e54.Google Scholar

YU, Q., YAO, Y., ZHU, X., et al. 2020. In vivo flow cytometric evaluation of circulating metastatic pancreatic tumor cells after high-intensity focused ultrasound therapy. Cytometry A, 97, 900–908.Google Scholar

YU, W. W., CHANG, E., DREZEK, R., and COLVIN, V. L. 2006. Water-soluble quantum dots for biomedical applications. Biochemical and Biophysical Research Communications, 348, 781–786.Google Scholar

ZARBIN, M., MONTEMAGNO, C., LEARY, J., and RITCH, R. 2011. Artificial vision. Panminerva Medica, 53, 167–177.Google Scholar

ZARBIN, M. A., MONTEMAGNO, C., LEARY, J. F., and RITCH, R. 2010a. Nanotechnology in ophthalmology. Canadian Journal of Ophthalmology, 45, 457–476.Google Scholar

ZARBIN, M. A., MONTEMAGNO, C., LEARY, J. F., and RITCH, R. 2010b. Nanomedicine in ophthalmology: The new frontier. American Journal of Ophthalmology, 150, 144–162.Google Scholar

ZARBIN, M. A., MONTEMAGNO, C., LEARY, J. F., and RITCH, R. 2012. Regenerative nanomedicine and the treatment of degenerative retinal diseases. WIREs Nanomedicine and Nanobiotechnology, 4, 113–137.Google Scholar

ZEISS. 2019. Zeiss Super Resolution Microscopy. Essential Knowledge Briefings. 3rd ed. Jena, Germany: Zeiss.Google Scholar

ZHANG, L. W., and MONTEIRO-RIVIERE, N. A. 2009. Mechanisms of quantum dot nanoparticle cellular uptake. Toxicological Sciences, 110, 138–155.Google Scholar

ZHAO, Z., ZHOU, Z., BAO, J., et al. 2013. Octapod iron oxide nanoparticles as high-performance T(2) contrast agents for magnetic resonance imaging. Nature Communications, 4, 2266.Google Scholar

Zhou, J., and Rossi, J.J. 2014. Cell-type-specific, aptamer-functionalized agents for targeted disease therapy. Molecular Therapy–Nucleic Acids, 3, e169.Google Scholar

ZHOU, Y., PENG, Z., SEVEN, E. S., and LEBLANC, R. M. 2018. Crossing the blood-brain barrier with nanoparticles. Journal of Controlled Release, 270, 290–303.Google Scholar

ZWEIFEL, D. A., and WEI, A. 2005. Sulfide-arrested growth of gold nanorods. Chemistry of Materials, 17, 4256–4261.Google Scholar

Book contents

References

Summary

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive