Dynamic predictive probabilities to monitor rapid cystic fibrosis disease progression

Links

https://onlinelibrary.wiley.com/doi/full/10.1002/sim.8443
Final published version
Licence: CC BY-NC-ND: Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License

Text available via DOI:

https://doi.org/10.1002/sim.8443
Final published version
Available under license: CC BY-NC-ND: Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License

Keywords

longitudinal data analysis, medical monitoring, nonstationary process, nowcasting, predictive probability distributions

View graph of relations

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Published

Standard

Dynamic predictive probabilities to monitor rapid cystic fibrosis disease progression. / Szczesniak, R.D.; Su, W.; Brokamp, C. et al.
In: Statistics in Medicine, Vol. 39, No. 6, 15.03.2020, p. 740-756.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Harvard

Szczesniak, RD, Su, W, Brokamp, C, Keogh, RH, Pestian, JP, Seid, M, Diggle, PJ & Clancy, JP 2020, 'Dynamic predictive probabilities to monitor rapid cystic fibrosis disease progression', Statistics in Medicine, vol. 39, no. 6, pp. 740-756. https://doi.org/10.1002/sim.8443

APA

Szczesniak, R. D., Su, W., Brokamp, C., Keogh, R. H., Pestian, J. P., Seid, M., Diggle, P. J., & Clancy, J. P. (2020). Dynamic predictive probabilities to monitor rapid cystic fibrosis disease progression. Statistics in Medicine, 39(6), 740-756. https://doi.org/10.1002/sim.8443

Vancouver

Szczesniak RD, Su W, Brokamp C, Keogh RH, Pestian JP, Seid M et al. Dynamic predictive probabilities to monitor rapid cystic fibrosis disease progression. Statistics in Medicine. 2020 Mar 15;39(6):740-756. Epub 2019 Dec 9. doi: 10.1002/sim.8443

Author

Szczesniak, R.D. ; Su, W. ; Brokamp, C. et al. / Dynamic predictive probabilities to monitor rapid cystic fibrosis disease progression. In: Statistics in Medicine. 2020 ; Vol. 39, No. 6. pp. 740-756.

Bibtex

@article{cf24eeea475148b295c48aabc1ade522,

title = "Dynamic predictive probabilities to monitor rapid cystic fibrosis disease progression",

abstract = "Cystic fibrosis (CF) is a progressive, genetic disease characterized by frequent, prolonged drops in lung function. Accurately predicting rapid underlying lung‐function decline is essential for clinical decision support and timely intervention. Determining whether an individual is experiencing a period of rapid decline is complicated due to its heterogeneous timing and extent, and error component of the measured lung function. We construct individualized predictive probabilities for “nowcasting” rapid decline. We assume each patient's true longitudinal lung function, S(t), follows a nonlinear, nonstationary stochastic process, and accommodate between‐patient heterogeneity through random effects. Corresponding lung‐function decline at time t is defined as the rate of change, S′(t). We predict S′(t) conditional on observed covariate and measurement history by modeling a measured lung function as a noisy version of S(t). The method is applied to data on 30 879 US CF Registry patients. Results are contrasted with a currently employed decision rule using single‐center data on 212 individuals. Rapid decline is identified earlier using predictive probabilities than the center's currently employed decision rule (mean difference: 0.65 years; 95% confidence interval (CI): 0.41, 0.89). We constructed a bootstrapping algorithm to obtain CIs for predictive probabilities. We illustrate real‐time implementation with R Shiny. Predictive accuracy is investigated using empirical simulations, which suggest this approach more accurately detects peak decline, compared with a uniform threshold of rapid decline. Median area under the ROC curve estimates (Q1‐Q3) were 0.817 (0.814‐0.822) and 0.745 (0.741‐0.747), respectively, implying reasonable accuracy for both. This article demonstrates how individualized rate of change estimates can be coupled with probabilistic predictive inference and implementation for a useful medical‐monitoring approach.",

keywords = "longitudinal data analysis, medical monitoring, nonstationary process, nowcasting, predictive probability distributions",

author = "R.D. Szczesniak and W. Su and C. Brokamp and R.H. Keogh and J.P. Pestian and M. Seid and P.J. Diggle and J.P. Clancy",

year = "2020",

month = mar,

day = "15",

doi = "10.1002/sim.8443",

language = "English",

volume = "39",

pages = "740--756",

journal = "Statistics in Medicine",

issn = "0277-6715",

publisher = "John Wiley and Sons Ltd",

number = "6",

}

RIS

TY - JOUR

T1 - Dynamic predictive probabilities to monitor rapid cystic fibrosis disease progression

AU - Szczesniak, R.D.

AU - Su, W.

AU - Brokamp, C.

AU - Keogh, R.H.

AU - Pestian, J.P.

AU - Seid, M.

AU - Diggle, P.J.

AU - Clancy, J.P.

PY - 2020/3/15

Y1 - 2020/3/15

N2 - Cystic fibrosis (CF) is a progressive, genetic disease characterized by frequent, prolonged drops in lung function. Accurately predicting rapid underlying lung‐function decline is essential for clinical decision support and timely intervention. Determining whether an individual is experiencing a period of rapid decline is complicated due to its heterogeneous timing and extent, and error component of the measured lung function. We construct individualized predictive probabilities for “nowcasting” rapid decline. We assume each patient's true longitudinal lung function, S(t), follows a nonlinear, nonstationary stochastic process, and accommodate between‐patient heterogeneity through random effects. Corresponding lung‐function decline at time t is defined as the rate of change, S′(t). We predict S′(t) conditional on observed covariate and measurement history by modeling a measured lung function as a noisy version of S(t). The method is applied to data on 30 879 US CF Registry patients. Results are contrasted with a currently employed decision rule using single‐center data on 212 individuals. Rapid decline is identified earlier using predictive probabilities than the center's currently employed decision rule (mean difference: 0.65 years; 95% confidence interval (CI): 0.41, 0.89). We constructed a bootstrapping algorithm to obtain CIs for predictive probabilities. We illustrate real‐time implementation with R Shiny. Predictive accuracy is investigated using empirical simulations, which suggest this approach more accurately detects peak decline, compared with a uniform threshold of rapid decline. Median area under the ROC curve estimates (Q1‐Q3) were 0.817 (0.814‐0.822) and 0.745 (0.741‐0.747), respectively, implying reasonable accuracy for both. This article demonstrates how individualized rate of change estimates can be coupled with probabilistic predictive inference and implementation for a useful medical‐monitoring approach.

AB - Cystic fibrosis (CF) is a progressive, genetic disease characterized by frequent, prolonged drops in lung function. Accurately predicting rapid underlying lung‐function decline is essential for clinical decision support and timely intervention. Determining whether an individual is experiencing a period of rapid decline is complicated due to its heterogeneous timing and extent, and error component of the measured lung function. We construct individualized predictive probabilities for “nowcasting” rapid decline. We assume each patient's true longitudinal lung function, S(t), follows a nonlinear, nonstationary stochastic process, and accommodate between‐patient heterogeneity through random effects. Corresponding lung‐function decline at time t is defined as the rate of change, S′(t). We predict S′(t) conditional on observed covariate and measurement history by modeling a measured lung function as a noisy version of S(t). The method is applied to data on 30 879 US CF Registry patients. Results are contrasted with a currently employed decision rule using single‐center data on 212 individuals. Rapid decline is identified earlier using predictive probabilities than the center's currently employed decision rule (mean difference: 0.65 years; 95% confidence interval (CI): 0.41, 0.89). We constructed a bootstrapping algorithm to obtain CIs for predictive probabilities. We illustrate real‐time implementation with R Shiny. Predictive accuracy is investigated using empirical simulations, which suggest this approach more accurately detects peak decline, compared with a uniform threshold of rapid decline. Median area under the ROC curve estimates (Q1‐Q3) were 0.817 (0.814‐0.822) and 0.745 (0.741‐0.747), respectively, implying reasonable accuracy for both. This article demonstrates how individualized rate of change estimates can be coupled with probabilistic predictive inference and implementation for a useful medical‐monitoring approach.

KW - longitudinal data analysis

KW - medical monitoring

KW - nonstationary process

KW - nowcasting

KW - predictive probability distributions

U2 - 10.1002/sim.8443

DO - 10.1002/sim.8443

M3 - Journal article

VL - 39

SP - 740

EP - 756

JO - Statistics in Medicine

JF - Statistics in Medicine

SN - 0277-6715

IS - 6

ER -

Research

Links

Text available via DOI:

Keywords