Tumor treating fields suppress tumor cell growth and neurologic decline in models of spinal metastases
Daniel Ledbetter, … , Claudio Tatsui, Christopher Alvarez-Breckenridge
Daniel Ledbetter, … , Claudio Tatsui, Christopher Alvarez-Breckenridge
Published March 21, 2024
Citation Information: JCI Insight. 2024;9(9):e176962. https://doi.org/10.1172/jci.insight.176962.
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Resource and Technical Advance Bone biology Neuroscience

Tumor treating fields suppress tumor cell growth and neurologic decline in models of spinal metastases

Abstract

Spinal metastases can result in severe neurologic compromise and decreased overall survival. Despite treatment advances, local disease progression is frequent, highlighting the need for novel therapies. Tumor treating fields (TTFields) impair tumor cell replication and are influenced by properties of surrounding tissue. We hypothesized that bone’s dielectric properties will enhance TTFields-mediated suppression of tumor growth in spinal metastasis models. Computational modeling of TTFields intensity was performed following surgical resection of a spinal metastasis and demonstrated enhanced TTFields intensity within the resected vertebral body. Additionally, luciferase-tagged human KRIB osteosarcoma and A549 lung adenocarcinoma cell lines were cultured in demineralized bone grafts and exposed to TTFields. Following TTFields exposure, the bioluminescence imaging (BLI) signal decreased to 10%–80% of baseline, while control cultures displayed a 4.48- to 9.36-fold increase in signal. Lastly, TTFields were applied in an orthotopic murine model of spinal metastasis. After 21 days of treatment, control mice demonstrated a 5-fold increase in BLI signal compared with TTFields-treated mice. TTFields similarly prevented tumor invasion into the spinal canal and development of neurologic symptoms. Our data suggest that TTFields can be leveraged as a local therapy within minimally conductive bone of spinal metastases. This provides the groundwork for future studies investigating TTFields for patients with treatment-refractory spinal metastases.

Authors

Daniel Ledbetter, Romulo Augusto Andrade de Almeida, Xizi Wu, Ariel Naveh, Chirag B. Patel, Queena Gonzalez, Thomas H. Beckham, Robert North, Laurence Rhines, Jing Li, Amol Ghia, David Aten, Claudio Tatsui, Christopher Alvarez-Breckenridge

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Figure 2

Effect of TTFields on tumor cell growth in 3D bone graft tumor model, with or without titanium screws in the treatment field.

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Effect of TTFields on tumor cell growth in 3D bone graft tumor model, wi...
KRIB-mLuc cells (AC) and A549-mLuc cells (DF) were 3D cultured in demineralized bone matrix scaffolds and exposed to 150 kHz TTFields for 14 days. Tumor cell growth was monitored by BLI on days 0 and 14 (A and D). Control groups had significantly higher BLI signal on day 14 relative to baseline (day 0) compared with TTFields-exposed cultures (B and E). Control groups also contained significantly more viable cells (CellTiter-Glo [CTG] assay) on day 14 than the TTFields-exposed groups (C and F). A549-mLuc cells were cultured in demineralized bone matrix scaffolds with or without titanium screws to model the pedicle screws implanted in patients (G) and exposed to 150 kHz TTFields or control for 14 days. Tumor cell growth was monitored by BLI on days 0 and 14 (H). Control groups had significantly higher BLI signal on day 14 than TTFields-exposed groups, relative to respective baseline values. Additionally, the close proximity of titanium screws had no effect on the antiproliferative effects of TTFields exposure (I). Values represent mean ± SEM from independent experiments (n = 3). *P < 0.05, ***P < 0.0005 by unpaired, 2-tailed t test.