Accurate patient-specific machine learning models of glioblastoma invasion using transfer learning

L. S. Hu; H. Yoon; J. M. Eschbacher; L. C. Baxter; A. C. Dueck; A. Nespodzany; K. A. Smith; P. Nakaji; Y. Xu; L. Wang; J. P. Karis; A. J. Hawkins-Daarud; K. W. Singleton; P. R. Jackson; B. J. Anderies; B. R. Bendok; R. S. Zimmerman; C. Quarles; A. B. Porter-Umphrey; M. M. Mrugala; A. Sharma; J. M. Hoxworth; M. G. Sattur; N. Sanai; P. E. Koulemberis; C. Krishna; J. R. Mitchell; T. Wu; N. L. Tran; K. R. Swanson; J. Li

doi:10.3174/ajnr.A5981

Accurate patient-specific machine learning models of glioblastoma invasion using transfer learning

L. S. Hu, H. Yoon, J. M. Eschbacher, L. C. Baxter, A. C. Dueck, A. Nespodzany, K. A. Smith, P. Nakaji, Y. Xu, L. Wang, J. P. Karis, A. J. Hawkins-Daarud, K. W. Singleton, P. R. Jackson, B. J. Anderies, B. R. Bendok, R. S. Zimmerman, C. Quarles, A. B. Porter-Umphrey, M. M. MrugalaA. Sharma, J. M. Hoxworth, M. G. Sattur, N. Sanai, P. E. Koulemberis, C. Krishna, J. R. Mitchell, T. Wu, N. L. Tran, K. R. Swanson, J. Li

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

7 Scopus citations

Abstract

BACKGROUND AND PURPOSE: MR imaging–based modeling of tumor cell density can substantially improve targeted treatment of glioblastoma. Unfortunately, interpatient variability limits the predictive ability of many modeling approaches. We present a transfer learning method that generates individualized patient models, grounded in the wealth of population data, while also detecting and adjusting for interpatient variabilities based on each patient’s own histologic data. MATERIALS AND METHODS: We recruited patients with primary glioblastoma undergoing image-guided biopsies and preoperative imaging, including contrast-enhanced MR imaging, dynamic susceptibility contrast MR imaging, and diffusion tensor imaging. We calculated relative cerebral blood volume from DSC-MR imaging and mean diffusivity and fractional anisotropy from DTI. Following image coregistration, we assessed tumor cell density for each biopsy and identified corresponding localized MR imaging measurements. We then explored a range of univariate and multivariate predictive models of tumor cell density based on MR imaging measurements in a generalized one-model-fits-all approach. We then implemented both univariate and multivariate individualized transfer learning predictive models, which harness the available population-level data but allow individual variability in their predictions. Finally, we compared Pearson correlation coefficients and mean absolute error between the individualized transfer learning and generalized one-model-fits-all models. RESULTS: Tumor cell density significantly correlated with relative CBV (r 0.33, P .001), and T1-weighted postcontrast (r 0.36, P .001) on univariate analysis after correcting for multiple comparisons. With single-variable modeling (using relative CBV), transfer learning increased predictive performance (r 0.53, mean absolute error 15.19%) compared with one-model-fits-all (r 0.27, mean absolute error 17.79%). With multivariate modeling, transfer learning further improved performance (r 0.88, mean absolute error 5.66%) compared with one-model-fits-all (r 0.39, mean absolute error 16.55%). CONCLUSIONS: Transfer learning significantly improves predictive modeling performance for quantifying tumor cell density in glioblastoma.

Original language	English (US)
Pages (from-to)	418-425
Number of pages	8
Journal	American Journal of Neuroradiology
Volume	40
Issue number	3
DOIs	https://doi.org/10.3174/ajnr.A5981
State	Published - 2019

ASJC Scopus subject areas

Radiology Nuclear Medicine and imaging
Clinical Neurology

Access to Document

10.3174/ajnr.A5981

Cite this

Hu, L. S., Yoon, H., Eschbacher, J. M., Baxter, L. C., Dueck, A. C., Nespodzany, A., Smith, K. A., Nakaji, P., Xu, Y., Wang, L., Karis, J. P., Hawkins-Daarud, A. J., Singleton, K. W., Jackson, P. R., Anderies, B. J., Bendok, B. R., Zimmerman, R. S., Quarles, C., Porter-Umphrey, A. B., ... Li, J. (2019). Accurate patient-specific machine learning models of glioblastoma invasion using transfer learning. American Journal of Neuroradiology, 40(3), 418-425. https://doi.org/10.3174/ajnr.A5981

Hu, LS, Yoon, H, Eschbacher, JM, Baxter, LC, Dueck, AC, Nespodzany, A, Smith, KA, Nakaji, P, Xu, Y, Wang, L, Karis, JP, Hawkins-Daarud, AJ, Singleton, KW, Jackson, PR, Anderies, BJ, Bendok, BR, Zimmerman, RS, Quarles, C, Porter-Umphrey, AB , Mrugala, MM, Sharma, A, Hoxworth, JM, Sattur, MG, Sanai, N, Koulemberis, PE, Krishna, C, Mitchell, JR, Wu, T, Tran, NL , Swanson, KR & Li, J 2019, 'Accurate patient-specific machine learning models of glioblastoma invasion using transfer learning', American Journal of Neuroradiology, vol. 40, no. 3, pp. 418-425. https://doi.org/10.3174/ajnr.A5981

@article{112edd98d76845ddbae9d2b5c26ef985,

title = "Accurate patient-specific machine learning models of glioblastoma invasion using transfer learning",

abstract = "BACKGROUND AND PURPOSE: MR imaging–based modeling of tumor cell density can substantially improve targeted treatment of glioblastoma. Unfortunately, interpatient variability limits the predictive ability of many modeling approaches. We present a transfer learning method that generates individualized patient models, grounded in the wealth of population data, while also detecting and adjusting for interpatient variabilities based on each patient{\textquoteright}s own histologic data. MATERIALS AND METHODS: We recruited patients with primary glioblastoma undergoing image-guided biopsies and preoperative imaging, including contrast-enhanced MR imaging, dynamic susceptibility contrast MR imaging, and diffusion tensor imaging. We calculated relative cerebral blood volume from DSC-MR imaging and mean diffusivity and fractional anisotropy from DTI. Following image coregistration, we assessed tumor cell density for each biopsy and identified corresponding localized MR imaging measurements. We then explored a range of univariate and multivariate predictive models of tumor cell density based on MR imaging measurements in a generalized one-model-fits-all approach. We then implemented both univariate and multivariate individualized transfer learning predictive models, which harness the available population-level data but allow individual variability in their predictions. Finally, we compared Pearson correlation coefficients and mean absolute error between the individualized transfer learning and generalized one-model-fits-all models. RESULTS: Tumor cell density significantly correlated with relative CBV (r 0.33, P .001), and T1-weighted postcontrast (r 0.36, P .001) on univariate analysis after correcting for multiple comparisons. With single-variable modeling (using relative CBV), transfer learning increased predictive performance (r 0.53, mean absolute error 15.19%) compared with one-model-fits-all (r 0.27, mean absolute error 17.79%). With multivariate modeling, transfer learning further improved performance (r 0.88, mean absolute error 5.66%) compared with one-model-fits-all (r 0.39, mean absolute error 16.55%). CONCLUSIONS: Transfer learning significantly improves predictive modeling performance for quantifying tumor cell density in glioblastoma.",

author = "Hu, {L. S.} and H. Yoon and Eschbacher, {J. M.} and Baxter, {L. C.} and Dueck, {A. C.} and A. Nespodzany and Smith, {K. A.} and P. Nakaji and Y. Xu and L. Wang and Karis, {J. P.} and Hawkins-Daarud, {A. J.} and Singleton, {K. W.} and Jackson, {P. R.} and Anderies, {B. J.} and Bendok, {B. R.} and Zimmerman, {R. S.} and C. Quarles and Porter-Umphrey, {A. B.} and Mrugala, {M. M.} and A. Sharma and Hoxworth, {J. M.} and Sattur, {M. G.} and N. Sanai and Koulemberis, {P. E.} and C. Krishna and Mitchell, {J. R.} and T. Wu and Tran, {N. L.} and Swanson, {K. R.} and J. Li",

note = "Funding Information: This work was supported by R21-NS082609, R01-CA221938, U01-CA220378, P50-CA108961, R01-CA158079 of the National Cancer Institute; the Mayo Clinic Foundation; the James S. McDonnell Foundation; the Ivy Foundation; and the Arizona Biomedical Research Commission. Please address correspondence to Leland S. Hu, MD, Department of Radiology, Mayo Clinic, 5777 E. Mayo Blvd., Phoenix, AZ 85054; e-mail: Hu.Leland@Mayo.Edu Indicates open access to non-subscribers at www.ajnr.org Funding Information: Disclosures: Leland S. Hu—RELATED: Grant: National Institutes of Health, Comments: National Institutes of Health/National Institute of Neurological Disorders and Stroke: R21-NS082609, National Institutes of Health/National Cancer Institute: U01-CA220378, R01-CA221938, P50-CA108961*; UNRELATED: Grants/Grants Pending: National Institutes of Health, Comments: National Institutes of Health/National Institute of Neurological Disorders and Stroke: R21NS082609, National Institutes of Health/National Cancer Institute: U01-CA220378*; Patents (Planned, Pending or Issued): patent application title: Methods for Using Machine Learning and Mechanistic Models for Cell Density Mapping of Glioblastoma with Multiparametric MRI, Patent Application No. 62/684,096, application type: Provisional, Country: USA, filing date: June 12, 2018, Mayo Clinic Case No. 2017–498. Hyunsoo Yoon—RELATED: Grant: National Institutes of Health U01.* Leslie C. Baxter—RELATED: Grant: several grants from the National Cancer Institute (National Institutes of Health).* Amylou C. Dueck—RELATED: Grant: National Institutes of Health, Comments: R21-NS082609 and U01-CA220378.* Peter Nakaji—UNRELATED: Consultancy: Carl Zeiss Meditec, Comments: microscope company that does tumor imaging and fluorescence work; Payment for Lectures Including Service on Speakers Bureaus: Carl Zeiss Meditec, Comments: microscope company that does tumor imaging and fluorescence work, for which I sometimes lecture; Patents (Planned, Pending or Issued): GT Medical Technologies, Comments: creates brachytherapy solutions for recurrent brain tumors, not related to current work. I was a founder and inventor; Stock/Stock Options: GT Medical Technologies, Comments: creates brachytherapy solutions for recurrent brain tumors, not related to current work; *Money paid to the individual (P.N.). Other: Stryker, SpiWay, Thieme. Yanzhe Xu—RELATED: Grant: National Institutes of Health U01.* Lujia Wang—RELATED: Grant: National Institutes of Health U01.* Andrea J. Hawkins-Daarud—RELATED: Grant: National Institutes of Health.* Pamela R. Jackson—RELATED: Grant: National Institutes of Health.* Jing Li—RELATED: Grant: R21-NS082609, U01-CA220378.* Teresa Wu— RELATED: Grant: R21-NS082609, U01-CA220378.* Chad Quarles—RELATED: Grant: National Institutes of Health.* Kristin R. Swanson—RELATED: Grant: National Institutes of Health, James S. McDonnell Foundation, Ivy Foundation, Arabidopsis Biological Resource Center.* Mithun G. Sattur—UNRELATED: Stock/ Stock Options: MRI interventions. *Money paid to the institution. Publisher Copyright: {\textcopyright} 2019 American Society of Neuroradiology. All rights reserved.",

year = "2019",

doi = "10.3174/ajnr.A5981",

language = "English (US)",

volume = "40",

pages = "418--425",

journal = "American Journal of Neuroradiology",

issn = "0195-6108",

publisher = "American Society of Neuroradiology",

number = "3",

}

TY - JOUR

T1 - Accurate patient-specific machine learning models of glioblastoma invasion using transfer learning

AU - Hu, L. S.

AU - Yoon, H.

AU - Eschbacher, J. M.

AU - Baxter, L. C.

AU - Dueck, A. C.

AU - Nespodzany, A.

AU - Smith, K. A.

AU - Nakaji, P.

AU - Xu, Y.

AU - Wang, L.

AU - Karis, J. P.

AU - Hawkins-Daarud, A. J.

AU - Singleton, K. W.

AU - Jackson, P. R.

AU - Anderies, B. J.

AU - Bendok, B. R.

AU - Zimmerman, R. S.

AU - Quarles, C.

AU - Porter-Umphrey, A. B.

AU - Mrugala, M. M.

AU - Sharma, A.

AU - Hoxworth, J. M.

AU - Sattur, M. G.

AU - Sanai, N.

AU - Koulemberis, P. E.

AU - Krishna, C.

AU - Mitchell, J. R.

AU - Wu, T.

AU - Tran, N. L.

AU - Swanson, K. R.

AU - Li, J.

N1 - Funding Information: This work was supported by R21-NS082609, R01-CA221938, U01-CA220378, P50-CA108961, R01-CA158079 of the National Cancer Institute; the Mayo Clinic Foundation; the James S. McDonnell Foundation; the Ivy Foundation; and the Arizona Biomedical Research Commission. Please address correspondence to Leland S. Hu, MD, Department of Radiology, Mayo Clinic, 5777 E. Mayo Blvd., Phoenix, AZ 85054; e-mail: Hu.Leland@Mayo.Edu Indicates open access to non-subscribers at www.ajnr.org Funding Information: Disclosures: Leland S. Hu—RELATED: Grant: National Institutes of Health, Comments: National Institutes of Health/National Institute of Neurological Disorders and Stroke: R21-NS082609, National Institutes of Health/National Cancer Institute: U01-CA220378, R01-CA221938, P50-CA108961*; UNRELATED: Grants/Grants Pending: National Institutes of Health, Comments: National Institutes of Health/National Institute of Neurological Disorders and Stroke: R21NS082609, National Institutes of Health/National Cancer Institute: U01-CA220378*; Patents (Planned, Pending or Issued): patent application title: Methods for Using Machine Learning and Mechanistic Models for Cell Density Mapping of Glioblastoma with Multiparametric MRI, Patent Application No. 62/684,096, application type: Provisional, Country: USA, filing date: June 12, 2018, Mayo Clinic Case No. 2017–498. Hyunsoo Yoon—RELATED: Grant: National Institutes of Health U01.* Leslie C. Baxter—RELATED: Grant: several grants from the National Cancer Institute (National Institutes of Health).* Amylou C. Dueck—RELATED: Grant: National Institutes of Health, Comments: R21-NS082609 and U01-CA220378.* Peter Nakaji—UNRELATED: Consultancy: Carl Zeiss Meditec, Comments: microscope company that does tumor imaging and fluorescence work; Payment for Lectures Including Service on Speakers Bureaus: Carl Zeiss Meditec, Comments: microscope company that does tumor imaging and fluorescence work, for which I sometimes lecture; Patents (Planned, Pending or Issued): GT Medical Technologies, Comments: creates brachytherapy solutions for recurrent brain tumors, not related to current work. I was a founder and inventor; Stock/Stock Options: GT Medical Technologies, Comments: creates brachytherapy solutions for recurrent brain tumors, not related to current work; *Money paid to the individual (P.N.). Other: Stryker, SpiWay, Thieme. Yanzhe Xu—RELATED: Grant: National Institutes of Health U01.* Lujia Wang—RELATED: Grant: National Institutes of Health U01.* Andrea J. Hawkins-Daarud—RELATED: Grant: National Institutes of Health.* Pamela R. Jackson—RELATED: Grant: National Institutes of Health.* Jing Li—RELATED: Grant: R21-NS082609, U01-CA220378.* Teresa Wu— RELATED: Grant: R21-NS082609, U01-CA220378.* Chad Quarles—RELATED: Grant: National Institutes of Health.* Kristin R. Swanson—RELATED: Grant: National Institutes of Health, James S. McDonnell Foundation, Ivy Foundation, Arabidopsis Biological Resource Center.* Mithun G. Sattur—UNRELATED: Stock/ Stock Options: MRI interventions. *Money paid to the institution. Publisher Copyright: © 2019 American Society of Neuroradiology. All rights reserved.

PY - 2019

Y1 - 2019

N2 - BACKGROUND AND PURPOSE: MR imaging–based modeling of tumor cell density can substantially improve targeted treatment of glioblastoma. Unfortunately, interpatient variability limits the predictive ability of many modeling approaches. We present a transfer learning method that generates individualized patient models, grounded in the wealth of population data, while also detecting and adjusting for interpatient variabilities based on each patient’s own histologic data. MATERIALS AND METHODS: We recruited patients with primary glioblastoma undergoing image-guided biopsies and preoperative imaging, including contrast-enhanced MR imaging, dynamic susceptibility contrast MR imaging, and diffusion tensor imaging. We calculated relative cerebral blood volume from DSC-MR imaging and mean diffusivity and fractional anisotropy from DTI. Following image coregistration, we assessed tumor cell density for each biopsy and identified corresponding localized MR imaging measurements. We then explored a range of univariate and multivariate predictive models of tumor cell density based on MR imaging measurements in a generalized one-model-fits-all approach. We then implemented both univariate and multivariate individualized transfer learning predictive models, which harness the available population-level data but allow individual variability in their predictions. Finally, we compared Pearson correlation coefficients and mean absolute error between the individualized transfer learning and generalized one-model-fits-all models. RESULTS: Tumor cell density significantly correlated with relative CBV (r 0.33, P .001), and T1-weighted postcontrast (r 0.36, P .001) on univariate analysis after correcting for multiple comparisons. With single-variable modeling (using relative CBV), transfer learning increased predictive performance (r 0.53, mean absolute error 15.19%) compared with one-model-fits-all (r 0.27, mean absolute error 17.79%). With multivariate modeling, transfer learning further improved performance (r 0.88, mean absolute error 5.66%) compared with one-model-fits-all (r 0.39, mean absolute error 16.55%). CONCLUSIONS: Transfer learning significantly improves predictive modeling performance for quantifying tumor cell density in glioblastoma.

AB - BACKGROUND AND PURPOSE: MR imaging–based modeling of tumor cell density can substantially improve targeted treatment of glioblastoma. Unfortunately, interpatient variability limits the predictive ability of many modeling approaches. We present a transfer learning method that generates individualized patient models, grounded in the wealth of population data, while also detecting and adjusting for interpatient variabilities based on each patient’s own histologic data. MATERIALS AND METHODS: We recruited patients with primary glioblastoma undergoing image-guided biopsies and preoperative imaging, including contrast-enhanced MR imaging, dynamic susceptibility contrast MR imaging, and diffusion tensor imaging. We calculated relative cerebral blood volume from DSC-MR imaging and mean diffusivity and fractional anisotropy from DTI. Following image coregistration, we assessed tumor cell density for each biopsy and identified corresponding localized MR imaging measurements. We then explored a range of univariate and multivariate predictive models of tumor cell density based on MR imaging measurements in a generalized one-model-fits-all approach. We then implemented both univariate and multivariate individualized transfer learning predictive models, which harness the available population-level data but allow individual variability in their predictions. Finally, we compared Pearson correlation coefficients and mean absolute error between the individualized transfer learning and generalized one-model-fits-all models. RESULTS: Tumor cell density significantly correlated with relative CBV (r 0.33, P .001), and T1-weighted postcontrast (r 0.36, P .001) on univariate analysis after correcting for multiple comparisons. With single-variable modeling (using relative CBV), transfer learning increased predictive performance (r 0.53, mean absolute error 15.19%) compared with one-model-fits-all (r 0.27, mean absolute error 17.79%). With multivariate modeling, transfer learning further improved performance (r 0.88, mean absolute error 5.66%) compared with one-model-fits-all (r 0.39, mean absolute error 16.55%). CONCLUSIONS: Transfer learning significantly improves predictive modeling performance for quantifying tumor cell density in glioblastoma.

UR - http://www.scopus.com/inward/record.url?scp=85063005062&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85063005062&partnerID=8YFLogxK

U2 - 10.3174/ajnr.A5981

DO - 10.3174/ajnr.A5981

M3 - Article

C2 - 30819771

AN - SCOPUS:85063005062

SN - 0195-6108

VL - 40

SP - 418

EP - 425

JO - American Journal of Neuroradiology

JF - American Journal of Neuroradiology

IS - 3

ER -

Accurate patient-specific machine learning models of glioblastoma invasion using transfer learning

Abstract

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Cite this