1. Xie, D. et al. A novel near-infrared EGFR targeting probe for metastatic lymph node imaging in preclinical mouse models. Journal of Nanobiotechnology 21, 1–12 (2023).
2. Xiong, Y. et al. Improving drug discovery with a hybrid deep generative model using reinforcement learning trained on a Bayesian docking approximation. Journal of Computer-Aided Molecular Design 37, 507–517 (2023).
3. Li, L. et al. Bright Asymmetric Shielding Strategy-Based NIR-II Probes for Angiography and Localized Photothermal Therapy. ACS Applied Bio Materials 6, 1639–1649 (2023).
4. Guo, J. et al. An ascorbic acid-responsive chemo-chromic SERS sensing chip for synergistic dual-modal on-site analysis of alkaline phosphatase. Sensors and Actuators B: Chemical 371, 132527 (2022).
5. Wang, Y., Xiong, Y., Garcia, E. A. L., Wang, Y. & Butch, C. J. Drug Chemical Space as a Guide for New Herbicide Development: A Cheminformatic Analysis. Journal of Agricultural and Food Chemistry 70, 9625–9636 (2022).
6. He, X. et al. Carbon Nitride with Rationally Designed Pi-Conjugated Structure for Bright Blue-Violet Light-Emitting Diodes. Small 18, (2022).
7. Dai, B. et al. Unexpected detection of a submillimeter early hepatocellular carcinoma focus by intraoperative near-infrared fluorescence imaging—a case report. Annals of Translational Medicine 10, 617–617 (2022).
8. Song, Q. et al. Highly fluorescent functionalized nano-poly(para-phenylene ethynylene) by polymer modification. Polymer 245, 124701 (2022).
9. Li, Y. et al. A study on setting standards for near-infrared fluorescence-image guided surgery (NIRFGS) time lapse monitoring based on preoperative liver function assessment. Annals of Translational Medicine 10, 96–96 (2022).
10. Dai, B. et al. Advantages of using indocyanine green in liver transplantation: a narrative review. Annals of Translational Medicine 10, 110–110 (2022).
11. Zhao, Y. et al. Improving the photostability of fluorescent dyes by polymer nano-insulating layer. Journal of Applied Polymer Science 51625 (2021) doi:10.1002/app.51625.
12. Cao, Y. et al. A pilot study of near-infrared fluorescence guided surgery for primary tumor localization and lymph node mapping in colorectal cancer. Annals of Translational Medicine 9, 1342–1342 (2021).
13. Li, B., Chu, F., Lu, Q., Wang, Y. & Lane, L. A. Alternating stealth polymer coatings between administrations minimizes toxic and antibody immune responses towards nanomedicine treatment regimens. Acta Biomaterialia 121, 527–540 (2021).
14. Xie, M. et al. Ultracompact Iron Oxide Nanoparticles with a Monolayer Coating of Succinylated Heparin: A New Class of Renal-Clearable and Nontoxic T\lesssub\greater1\less/sub\greater Agents for High-Field MRI. ACS Applied Materials &amp\mathsemicolon Interfaces 12, 53994–54004 (2020).
15. Xie, M., Zhang, D., Wang, Y. & Zhao, Y. Facile fabrication of ZnO nanorods modified with RGO for enhanced photodecomposition of dyes. Colloids and Surfaces A: Physicochemical and Engineering Aspects 603, 125247 (2020).
16. He, X. et al. One-Pot Exfoliation of Graphitic C\lesssub\greater3\less/sub\greaterN\lesssub\greater4\less/sub\greater Quantum Dots for Blue QLEDs by Methylamine Intercalation. Small 15, (2019).
17. He, W. et al. Three-Dimensional Functionalized Carbon Nanotubes/Graphitic Carbon Nitride Hybrid Composite as the Sulfur Host for High-Performance Lithium–Sulfur Batteries. The Journal of Physical Chemistry C 123, 15924–15934 (2019).
18. Dai, B. et al. Encapsulating maytansinoid in pH-sensitive nanocarriers: The importance of using extremely potent cytotoxic agents and fast release for nanomedicine to achieve tumor elimination. Nano Research 12, 1959–1966 (2019).
19. Li, B., Wang, Y. & He, J. Gold Nanorods-Based Smart Nanoplatforms for Synergic Thermotherapy and Chemotherapy of Tumor Metastasis. ACS Applied Materials & Interfaces 11, 7800–7811 (2019).
20. Xie, M. et al. Succinylated heparin monolayer coating vastly increases superparamagnetic iron oxide nanoparticle T2 proton relaxivity. Nanoscale 11, 12905–12914 (2019).
21. Xie, D. et al. Kinetics analysis of indocyanine green based on a novel mouse model to distinguish between tumor and inflammation. Analytical Methods (2019) doi:10.1039/c9ay01906e.
22. Wang, Y. et al. Kinetics of indocyanine green: Optimizing tumor to normal tissue fluorescence in image-guided oral cancer surgery applications. Head &amp\mathsemicolon Neck 41, 1032–1038 (2018).
23. He, X. et al. Electron-rich heterocycle induced tunable emitting fluorescence of graphitic carbon nitride quantum dots. Applied Surface Science 462, 303–309 (2018).
24. Li, B., Jiang, Z., Xie, D., Wang, Y. & Lao, X. Cetuximab-modified CuS nanoparticles integrating near-infrared-II-responsive photothermal therapy and anti-vessel treatment. International Journal of Nanomedicine Volume 13, 7289–7302 (2018).
25. Zhang, X. et al. Downregulating Heparanase-Induced Vascular Normalization: A New Approach To Increase the Bioavailability of Chemotherapeutics in Solid Tumors. Molecular Pharmaceutics 15, 4303–4309 (2018).
26. Newton, A. D. et al. Intraoperative near-infrared imaging can identify sub-centimeter colorectal cancer lung metastases during pulmonary metastasectomy. Journal of Thoracic Disease 10, E544–E548 (2018).
27. Wang, Z. et al. Method for Real-Time Tissue Quantification of Indocyanine Green Revealing Optimal Conditions for Near Infrared Fluorescence Guided Surgery. Analytical Chemistry 90, 7922–7929 (2018).
28. Wang, J. et al. Quantitative Examination of the Active Targeting Effect: The Key Factor for Maximal Tumor Accumulation and Retention of Short-Circulated Biopolymeric Nanocarriers. Bioconjugate Chemistry 28, 1351–1355 (2017).
29. Lee, K. Y. J. et al. Functionalized, Long-Circulating, and Ultrasmall Gold Nanocarriers for Overcoming the Barriers of Low Nanoparticle Delivery Efficiency and Poor Tumor Penetration. Bioconjugate Chemistry 28, 244–252 (2016).
30. Quan, L. et al. Enhanced Detection Specificity and Sensitivity of Alzheimer’s Disease Using Amyloid-\upbeta-Targeted Quantum Dots. Bioconjugate Chemistry 27, 809–814 (2016).
31. Wang, J. et al. An unusual role of folate in the self-assembly of heparin–folate conjugates into nanoparticles. Nanoscale 7, 15185–15190 (2015).
32. Lee, K. Y. J., Wang, Y. & Nie, S. In vitro study of a pH-sensitive multifunctional doxorubicin–gold nanoparticle system: therapeutic effect and surface enhanced Raman scattering. RSC Advances 5, 65651–65659 (2015).
33. Quan, L. et al. Near-Infrared Emitting Fluorescent BODIPY Nanovesicles for in Vivo Molecular Imaging and Drug Delivery. ACS Applied Materials &amp\mathsemicolon Interfaces 6, 16166–16173 (2014).
34. Yue, C. et al. IR-780 dye loaded tumor targeting theranostic nanoparticles for NIR imaging and photothermal therapy. Biomaterials 34, 6853–6861 (2013).
35. Peng, X., Wang, Y., Chen, Z. (Georgia), Nie, S. & Shin, D. M. Abstract 4750: Overcoming DDP resistance using folic acid-heparin-DDP nanoparticles. Cancer Research 72, 4750–4750 (2012).
36. Wang, Y., Wang, Y., Lee, G. Y., Yang, L. & Nie, S. Nanoformulated maytansinoid: Nanotechnology for rescuing previously failed cancer drugs. Abstracts of Papers of the American Chemical Society (2012).
37. Wang, Y. Polyoxometalates with different structures as novel inorganic drugs for cancer therapy. Abstracts of Papers of the American Chemical Society (2012).
38. Wang, L., Wang, Y. & Ragauskas, A. J. Determination of cellulase colocalization on cellulose fiber with quantitative FRET measured by acceptor photobleaching and spectrally unmixing fluorescence microscopy. The Analyst 137, 1319 (2012).
39. Peng, X.-H. et al. Targeted Delivery of Cisplatin to Lung Cancer Using ScFvEGFR-Heparin-Cisplatin Nanoparticles. ACS Nano 5, 9480–9493 (2011).
40. Huang, X. et al. A Reexamination of Active and Passive Tumor Targeting by Using Rod-Shaped Gold Nanocrystals and Covalently Conjugated Peptide Ligands. ACS Nano 5, 6765–6765 (2011).
41. Peng, X. et al. Abstract 4451: Targeted therapy of lung cancer using ScFvEGFR-Heparin-Cisplatin nanoparticles. Cancer Research 71, 4451–4451 (2011).
42. Wang, Y., Wang, Y., Xiang, J. & Yao, K. Target-Specific Cellular Uptake of Taxol-Loaded Heparin-PEG-Folate Nanoparticles. Biomacromolecules 11, 3531–3538 (2010).
43. Huang, X. et al. A Reexamination of Active and Passive Tumor Targeting by Using Rod-Shaped Gold Nanocrystals and Covalently Conjugated Peptide Ligands. ACS Nano 4, 5887–5896 (2010).
44. Wang, L., Wang, Y. & Ragauskas, A. J. A novel FRET approach for in situ investigation of cellulase–cellulose interaction. Analytical and Bioanalytical Chemistry 398, 1257–1262 (2010).
45. Peng, X. et al. Abstract 3678: Reducing non-specific toxicity of cisplatin in head and neck cancer by targeted therapy using cisplatin-heparin-folic acid nanoparticles. Cancer Research 70, 3678–3678 (2010).
46. Wang, Y. et al. CONVECTION ENHANCED DELIVERY OF MAYTANSINOID NANOPARTICLES FOR TREATMENT OF GLIOBLASTOMA MULTIFORME. Neuro-Oncology (2010).
47. Wang, X. et al. HFT-T, a Targeting Nanoparticle, Enhances Specific Delivery of Paclitaxel to Folate Receptor-Positive Tumors. ACS Nano 3, 3165–3174 (2009).
48. Wang, Y. et al. A novel folate receptor-targeted nanoparticle minimizes drug resistance in a human cancer model. Cancer Research (2009).
49. Wang, Y. et al. Biodistribution of cisplatinloaded magnetic iron oxide nanoparticles in nude mice bearing human head and neck cancer. Cancer Research (2009).
50. Wang, Y. et al. Biodistribution of cisplatin-loaded magnetic iron oxide nanoparticles in nude mice bearing human head and neck cancer. Proceedings of the American Association For Cancer Research (AACR) Annual Meeting (2009).
51. Wang, X., Wang, Y., Chen, Z. G. & Shin, D. M. Advances of Cancer Therapy by Nanotechnology. Cancer Research and Treatment 41, 1 (2009).
52. Wang, Y. et al. Highly Porous Crosslinkable PLA-PNB Block Copolymer Scaffolds. Advanced Functional Materials 18, 3638–3644 (2008).
53. Wang, Y. et al. Optical Spectroscopy of Grafted Poly(\lessi\greaterp-\less/i\greaterphenyleneethynylene)s in Water and Water-DMF Mixtures. Macromolecules 41, 1112–1117 (2008).
54. Wang, Y., Park, J. S., Leech, J. P., Miao, S. & Bunz, U. H. F. Poly(aryleneethynylene)s with Orange, Yellow, Green, and Blue Solid-State Fluorescence. Macromolecules 40, 1843–1850 (2007).
55. Jiang, Y., Perahia, D., Wang, Y. & Bunz, U. H. F. Side Chain vs Main Chain. Who Dominates? A Polyester-Grafted Poly(\lessi\greaterp-\less/i\greaterphenyleneethynylene) with Two Different Morphologies. Macromolecules 39, 4941–4944 (2006).
56. Sun, S., Fan, Z., Wang, Y. & Haliburton, J. Organic solar cell optimizations. Journal of Materials Science 40, 1429–1443 (2005).
57. Sun, S.-S., Fan, Z., Wang, Y., Winston, K. & Bonner, C. E. Morphological effects to carrier mobility in a RO-PPV/SF-PPV donor/acceptor binary thin film opto-electronic device. Materials Science and Engineering: B 116, 279–282 (2005).
58. Sun, S.-S. et al. Optimizing organic optoelectronic materials in both space and energy/time domains. in SPIE Proceedings (eds. Zah, C.-E., Luo, Y. & Tsuji, S.) (SPIE, 2005). doi:10.1117/12.577180.
59. Wang, Y., Wilson, J. N., Smith, M. D. & Bunz, U. H. F. TEMPO-Substituted PPEs:\hspace0.167em Polystyrene-PPE Graft Copolymers and Double Graft Copolymers. Macromolecules 37, 9701–9708 (2004).
60. Sun, S.-S. et al. Block copolymers for opto-electronics. in Materials, Active Devices, and Optical Amplifiers (SPIE, 2004). doi:10.1117/12.520570.
61. Sun, S. et al. Conjugated Block Copolymers for Opto-Electronic Functions. Synthetic Metals 137, 883–884 (2003).
62. Sun, S.-S. et al. Synthesis and characterization of a novel -D-B-A-B- block copolymer system for potential light harvesting applications. in Organic Photovoltaics III (ed. Kafafi, Z. H.) (SPIE, 2003). doi:10.1117/12.452414.
63. Wilson, J. N., Wang, Y., Lavigne, J. J. & Bunz, U. H. F. A biosensing model system: selective interaction of biotinylated PPEs with streptavidin-coated polystyrene microspheresElectronic supplementary information (ESI) available: experimental, including details of preparation and spectroscopic characterization of all new compounds and biotinylation assay of 3 by streptavidin. See http://www.rsc.org/suppdata/cc/b3/b303700m/. Chemical Communications 1626 (2003) doi:10.1039/b303700m.
64. Wilson, J. N., Josowicz, M., Wang, Y. & Bunz, U. H. F. Cruciform \uppi-systems: hybrid phenylene-ethynylene/phenylene-vinylene oligomers. Chem. Commun. 2962–2963 (2003) doi:10.1039/b312156a.
65. Wang, Y., Erdogan, B., Wilson, J. N. & Bunz, U. H. F. Grafted conjugated polymers: synthesis and characterization of a polyester side chain substituted poly(paraphenyleneethynylene)Electronic supplementary information (ESI) available: experimental, including details of preparation and spectroscopic characterization of all new compounds. See http://www.rsc.org/suppdata/cc/b3/b303699p/. Chemical Communications 1624 (2003) doi:10.1039/b303699p.
66. Sun, S.-S. et al. &lt\mathsemicolontitle&gt\mathsemicolonDesign and synthesis of novel block copolymers for efficient optoelectronic applications&lt\mathsemicolon/title&gt\mathsemicolon. in SPIE Proceedings (eds. Kafafi, Z. H. & Fichou, D.) (SPIE, 2002). doi:10.1117/12.456932.
67. Wang, Y., Wang, Y., Fan, Z., Taft, C. & Sun, S. Synthesis and characterization of SF-PPV-I. Abstracts of Papers of the American Chemical Society (2002).
68. Wang, Y. et al. Synthesis and characterization of a novel block copolymer. Abstracts of Papers of the American Chemical Society (2002).
69. Sun, S.-S. et al. Recent development of crosslinked NLO polymers for large bandwidth electro-optical modulations. in SPIE Proceedings (eds. Lee, T. P. & Wang, Q.) (SPIE, 2001). doi:10.1117/12.444977.
70. Wang, Y. et al. Design and synthesis of novel block copolymers for efficient optoelectronic applications. in Proceedings of SPIE - The International Society for Optical Engineering (2001).
71. Wang, Y. et al. Synthesis and characterization of fumaryl type functional crosslinked polyesters. Abstracts of Papers of the American Chemical Society (2001).
72. Sun, S.-S. et al. Synthesis and characterization of maleic anhydride derived crosslinkable polymers for nonlinear optical applications. in SPIE Proceedings (SPIE, 2000). doi:10.1117/12.408504.
73. Wang, Y. A Reexamination of Active and Passive Tumor Targeting by Using Rod-Shaped Gold Nanocrystals and Covalently Conjugated Peptide Ligands.

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