<i>In Vivo</i> and <i>in Situ</i> Tracking Cancer Chemotherapy by Highly Photostable NIR Fluorescent Theranostic Prodrug

Wu, Xumeng; Sun, Xuanrong; Guo, Zhiqian; Tang, Jianbin; Shen, Youqing; James, Tony D.; Tian, He; Zhu, Weihong

doi:10.1021/ja412380j

Cited by 505 publications

(316 citation statements)

References 93 publications

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“…Zhu and Guo et al developed novel activatable theranostics (69a and 69b) based on the dicyanomethylene-4H-pyran NIR fluorophore for in vivo and in situ monitoring of drug delivery and cancer chemotherapy in living animals. 207 The biologically abundant thiols in tumor cells triggered cleavage of the View Article Online disulfide linker, leading to the release of camptothecin and emission of NIR fluorescence. These theranostics showed similar cytotoxicity with significant in vitro antitumor activity against several cell lines including BCap-37, HepG2, MCF-7, HeLa, KB, and KB200.…”

Section: Therapeutics Without Targeting Ligandsmentioning

confidence: 99%

Fluorescent chemical probes for accurate tumor diagnosis and targeting therapy

et al. 2017

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Surgical resection of solid tumors is currently the gold standard and preferred therapeutic strategy for cancer. Chemotherapy drugs also make a significant contribution by inhibiting the rapid growth of tumor cells and these two approaches are often combined to enhance treatment efficacy. However, surgery and chemotherapy inevitably lead to severe side effects and high systemic toxicity, which in turn results in poor prognosis. Precision medicine has promoted the development of treatment modalities that are developed to specifically target and kill tumor cells. Advances in in vivo medical imaging for visualizing tumor lesions can aid diagnosis, facilitate surgical resection, investigate therapeutic efficacy, and improve prognosis. In particular, the modality of fluorescence imaging has high specificity and sensitivity and has been utilized for medical imaging. Therefore, there are great opportunities for chemists and physicians to conceive, synthesize, and exploit new chemical probes that can image tumors and release chemotherapy drugs in vivo. This review focuses on small molecular ligand-targeted fluorescent imaging probes and fluorescent theranostics, including their design strategies and applications in clinical tumor treatment. The progress in chemical probes described here suggests that fluorescence imaging is a vital and rapidly developing field for interventional surgical imaging, as well as tumor diagnosis and therapy.

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Section: Therapeutics Without Targeting Ligandsmentioning

confidence: 99%

Fluorescent chemical probes for accurate tumor diagnosis and targeting therapy

et al. 2017

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“…For example, the NIR prodrug dicyanomethylene-disulfidecamptothecin and its derivative, PEG-polylactic acid, when loaded in nanoparticles, emitted NIRF signals. 107,108 These NIR-encapsulated nanoparticles showed higher antitumor activity and longer retention in the plasma than free camptothecin. 108 Additionally, the excellent fluorescence intensity and photostability of DCM chromophores with a large Stokes shift makes the in vivo and in situ tracking of drug release and therapeutic efficacy in live animals possible.…”

Section: Chemical Modificationmentioning

confidence: 99%

“…108 Additionally, the excellent fluorescence intensity and photostability of DCM chromophores with a large Stokes shift makes the in vivo and in situ tracking of drug release and therapeutic efficacy in live animals possible. 108 …”

Section: Chemical Modificationmentioning

confidence: 99%

“…110 Finally, crucial evaluations of pharmacokinetics, pharmacodynamics, and toxicity of dyes and dye-drug conjugates are also needed in mouse and dog models before this group of novel compounds can be moved into the clinic for improved cancer diagnosis, prognosis and therapy. 108 Taking into account the complexity of targeted drug development, the development of diagnostic NIRF agents for tumor imaging should give the priority to the selection conducted in preclinical experimental models, where both the PDX mouse model and dog spontaneous tumor model are obviously convenient tools for preclinical tests.…”

Section: Preclinical Experimentsmentioning

confidence: 99%

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Review on near-infrared heptamethine cyanine dyes as theranostic agents for tumor imaging, targeting, and photodynamic therapy

2016

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Review on near-infrared heptamethine cyanine dyes as theranostic agents for tumor imaging, targeting, and photodynamic therapy," J. Biomed. Opt. 21(5), 050901 (2016), doi: 10.1117/1.JBO.21.5.050901. Abstract. A class of near-infrared fluorescence (NIRF) heptamethine cyanine dyes that are taken up and accumulated specifically in cancer cells without chemical conjugation have recently emerged as promising tools for tumor imaging and targeting. In addition to their fluorescence and nuclear imagingbased tumor-imaging properties, these dyes can be developed as drug carriers to safely deliver chemotherapy drugs to tumors. They can also be used as effective agents for photodynamic therapy with remarkable tumoricidal activity via photodependent cytotoxic activity. The preferential uptake of dyes into cancer but not normal cells is co-operatively mediated by the prevailing activation of a group of organic aniontransporting polypeptides on cancer cell membranes, as well as tumor hypoxia and increased mitochondrial membrane potential in cancer cells. Such mechanistic explorations have greatly advanced the current application and future development of NIRF dyes and their derivatives as anticancer theranostic agents. This review summarizes current knowledge and emerging advances in NIRF dyes, including molecular characterization, photophysical properties, multimodal development and uptake mechanisms, and their growing potential for preclinical and clinical use.

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“…The reduced products were prepared by in situ reduction of the respective disulfides using TCEP and used immediately (using the same agent and a similar method to that reported by Baud et al 35 ). (C) Proposed mechanisms for the release of SAHA: the first is direct cleavage of the ester linkage to generate the parent drug by intracellular esterases; the second involves reduction of the disulfide linkage and intramolecular cyclization; (a similar reaction mechanism has been reported by Zhang et al 55 and Wu et al 56 ) the third is the reduction of the disulfide linkage, followed by cleavage of ester linkage. Abbreviations: compd, compound; DMsO, dimethyl sulphoxide; eq, equivalent; gsh, glutathione; PBs, phosphate-buffered saline; hDac, histone deacetylase; Ic 50 , half maximal inhibitory concentration; TceP, tris(2-carboxyethyl)phosphine hydrochloride; h, hours.…”

Section: ) (B)mentioning

confidence: 87%