npj Systems Biology and Applications (Jul 2023)

Growth exponents reflect evolutionary processes and treatment response in brain metastases

  • Beatriz Ocaña-Tienda,
  • Julián Pérez-Beteta,
  • Juan Jiménez-Sánchez,
  • David Molina-García,
  • Ana Ortiz de Mendivil,
  • Beatriz Asenjo,
  • David Albillo,
  • Luis A. Pérez-Romasanta,
  • Manuel Valiente,
  • Lucía Zhu,
  • Pedro García-Gómez,
  • Elisabet González-Del Portillo,
  • Manuel Llorente,
  • Natalia Carballo,
  • Estanislao Arana,
  • Víctor M. Pérez-García

DOI
https://doi.org/10.1038/s41540-023-00298-1
Journal volume & issue
Vol. 9, no. 1
pp. 1 – 11

Abstract

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Abstract Tumor growth is the result of the interplay of complex biological processes in huge numbers of individual cells living in changing environments. Effective simple mathematical laws have been shown to describe tumor growth in vitro, or simple animal models with bounded-growth dynamics accurately. However, results for the growth of human cancers in patients are scarce. Our study mined a large dataset of 1133 brain metastases (BMs) with longitudinal imaging follow-up to find growth laws for untreated BMs and recurrent treated BMs. Untreated BMs showed high growth exponents, most likely related to the underlying evolutionary dynamics, with experimental tumors in mice resembling accurately the disease. Recurrent BMs growth exponents were smaller, most probably due to a reduction in tumor heterogeneity after treatment, which may limit the tumor evolutionary capabilities. In silico simulations using a stochastic discrete mesoscopic model with basic evolutionary dynamics led to results in line with the observed data.