Intravital microscopy of osteolytic progression and therapy response of cancer lesions in the bone

Eleonora Dondossola; Stephanie Alexander; Boris M. Holzapfel; Stefano Filippini; Michael W. Starbuck; Robert M. Hoffman; Nora Navone; Elena M. De-Juan-pardo; Christopher J. Logothetis; Dietmar W. Hutmacher; Peter Friedl

doi:10.1126/scitranslmed.aao5726

Intravital microscopy of osteolytic progression and therapy response of cancer lesions in the bone

Eleonora Dondossola, Stephanie Alexander, Boris M. Holzapfel, Stefano Filippini, Michael W. Starbuck, Robert M. Hoffman, Nora Navone, Elena M. De-Juan-pardo, Christopher J. Logothetis, Dietmar W. Hutmacher, Peter Friedl

Research output: Contribution to journal › Article › peer-review

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Abstract

Intravital multiphoton microscopy (iMPM) in mice provides access to cellular and molecular mechanisms of metastatic progression of cancers and the underlying interactions with the tumor stroma. Whereas iMPM of malignant disease has been performed for soft tissues, noninvasive iMPM of solid tumor in the bone is lacking. We combined miniaturized tissue-engineered bone constructs in nude mice with a skin window to noninvasively and repetitively monitor prostate cancer lesions by three-dimensional iMPM. In vivo ossicles developed large central cavities containing mature bone marrow surrounded by a thin cortex and enabled tumor implantation and longitudinal iMPM over weeks. Tumors grew inside the bone cavity and along the cortical bone interface and induced niches of osteoclast activation (focal osteolysis). Interventional bisphosphonate therapy reduced osteoclast kinetics and osteolysis without perturbing tumor growth, indicating dissociation of the tumor-stroma axis. The ossicle window, with its high cavity-to-cortex ratio and long-term functionality, thus allows for the mechanistic dissection of reciprocal epithelial tumor-bone interactions and therapy response.

Original language	English
Article number	eaao5726
Journal	Science Translational Medicine
Volume	10
Issue number	452
DOIs	https://doi.org/10.1126/scitranslmed.aao5726
Publication status	Published - 1 Aug 2018
Externally published	Yes

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Dondossola, E., Alexander, S., Holzapfel, B. M., Filippini, S., Starbuck, M. W., Hoffman, R. M., Navone, N., De-Juan-pardo, E. M., Logothetis, C. J., Hutmacher, D. W., & Friedl, P. (2018). Intravital microscopy of osteolytic progression and therapy response of cancer lesions in the bone. Science Translational Medicine, 10(452), Article eaao5726. https://doi.org/10.1126/scitranslmed.aao5726

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abstract = "Intravital multiphoton microscopy (iMPM) in mice provides access to cellular and molecular mechanisms of metastatic progression of cancers and the underlying interactions with the tumor stroma. Whereas iMPM of malignant disease has been performed for soft tissues, noninvasive iMPM of solid tumor in the bone is lacking. We combined miniaturized tissue-engineered bone constructs in nude mice with a skin window to noninvasively and repetitively monitor prostate cancer lesions by three-dimensional iMPM. In vivo ossicles developed large central cavities containing mature bone marrow surrounded by a thin cortex and enabled tumor implantation and longitudinal iMPM over weeks. Tumors grew inside the bone cavity and along the cortical bone interface and induced niches of osteoclast activation (focal osteolysis). Interventional bisphosphonate therapy reduced osteoclast kinetics and osteolysis without perturbing tumor growth, indicating dissociation of the tumor-stroma axis. The ossicle window, with its high cavity-to-cortex ratio and long-term functionality, thus allows for the mechanistic dissection of reciprocal epithelial tumor-bone interactions and therapy response.",

author = "Eleonora Dondossola and Stephanie Alexander and Holzapfel, {Boris M.} and Stefano Filippini and Starbuck, {Michael W.} and Hoffman, {Robert M.} and Nora Navone and De-Juan-pardo, {Elena M.} and Logothetis, {Christopher J.} and Hutmacher, {Dietmar W.} and Peter Friedl",

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AU - Hoffman, Robert M.

AU - Navone, Nora

AU - De-Juan-pardo, Elena M.

AU - Logothetis, Christopher J.

AU - Hutmacher, Dietmar W.

AU - Friedl, Peter

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Intravital microscopy of osteolytic progression and therapy response of cancer lesions in the bone

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