Development and Calibration of a Dynamic HIV Transmission Model for 6 US Cities

Xiao Zang; Emanuel Krebs; Jeong E. Min; Ankur Pandya; Brandon D.L. Marshall; Bruce R. Schackman; Czarina N. Behrends; Daniel J. Feaster; Bohdan Nosyk; Czarina N. Behrends; Carlos Del Rio; Julia Dombrowski; Daniel J. Feaster; Kelly Gebo; Matthew Golden; Reuben Granich; Thomas Kerr; Gregory Kirk; Brandon D.L. Marshall; Shruti H. Mehta; Lisa Metsch; Julio Montaner; Bruce R. Schackman; Steven Shoptaw; William Small; Steffanie A. Strathdee

doi:10.1177/0272989X19889356

Development and Calibration of a Dynamic HIV Transmission Model for 6 US Cities

Xiao Zang, Emanuel Krebs, Jeong E. Min, Ankur Pandya, Brandon D.L. Marshall, Bruce R. Schackman, Czarina N. Behrends, Daniel J. Feaster, Bohdan Nosyk, Czarina N. Behrends, Carlos Del Rio, Julia Dombrowski, Daniel J. Feaster, Kelly Gebo, Matthew Golden, Reuben Granich, Thomas Kerr, Gregory Kirk, Brandon D.L. Marshall, Shruti H. MehtaLisa Metsch, Julio Montaner, Bruce R. Schackman, Steven Shoptaw, William Small, Steffanie A. Strathdee

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8 Scopus citations

Abstract

Background. Heterogeneity in HIV microepidemics across US cities necessitates locally oriented, combination implementation strategies to prioritize resources. We calibrated and validated a dynamic, compartmental HIV transmission model to establish a status quo treatment scenario, holding constant current levels of care for 6 US cities. Methods. Built off a comprehensive evidence synthesis, we adapted and extended a previously published model to replicate the transmission, progression, and clinical care for each microepidemic. We identified a common set of 17 calibration targets between 2012 and 2015 and used the Morris method to select the most influential parameters for calibration. We then applied the Nelder-Mead algorithm to iteratively calibrate the model to generate 2000 best-fitting parameter sets. Finally, model projections were internally validated with a series of robustness checks and externally validated against published estimates of HIV incidence, while the face validity of 25-year projections was assessed by a Scientific Advisory Committee (SAC). Results. We documented our process for model development, calibration, and validation to maximize its transparency and reproducibility. The projected outcomes demonstrated a good fit to calibration targets, with a mean goodness-of-fit ranging from 0.0174 (New York City [NYC]) to 0.0861 (Atlanta). Most of the incidence predictions were within the uncertainty range for 5 of the 6 cities (ranging from 21% [Miami] to 100% [NYC]), demonstrating good external validity. The face validity of the long-term projections was confirmed by our SAC, showing that the incidence would decrease or remain stable in Atlanta, Los Angeles, NYC, and Seattle while increasing in Baltimore and Miami. Discussion. This exercise provides a basis for assessing the incremental value of further investments in HIV combination implementation strategies tailored to urban HIV microepidemics.

Original language	English (US)
Pages (from-to)	3-16
Number of pages	14
Journal	Medical Decision Making
Volume	40
Issue number	1
DOIs	https://doi.org/10.1177/0272989X19889356
State	Published - Jan 1 2020

Keywords

HIV/AIDS
dynamic transmission model
epidemiological projection
model calibration
model validation

ASJC Scopus subject areas

Health Policy

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10.1177/0272989X19889356

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Zang, X., Krebs, E., Min, J. E., Pandya, A., Marshall, B. D. L., Schackman, B. R., Behrends, C. N., Feaster, D. J., Nosyk, B., Behrends, C. N., Del Rio, C., Dombrowski, J., Feaster, D. J., Gebo, K., Golden, M., Granich, R., Kerr, T., Kirk, G., Marshall, B. D. L., ... Strathdee, S. A. (2020). Development and Calibration of a Dynamic HIV Transmission Model for 6 US Cities. Medical Decision Making, 40(1), 3-16. https://doi.org/10.1177/0272989X19889356

Zang, X, Krebs, E, Min, JE, Pandya, A, Marshall, BDL, Schackman, BR, Behrends, CN, Feaster, DJ, Nosyk, B, Behrends, CN, Del Rio, C, Dombrowski, J, Feaster, DJ, Gebo, K, Golden, M, Granich, R, Kerr, T, Kirk, G, Marshall, BDL, Mehta, SH, Metsch, L, Montaner, J, Schackman, BR, Shoptaw, S, Small, W & Strathdee, SA 2020, 'Development and Calibration of a Dynamic HIV Transmission Model for 6 US Cities', Medical Decision Making, vol. 40, no. 1, pp. 3-16. https://doi.org/10.1177/0272989X19889356

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title = "Development and Calibration of a Dynamic HIV Transmission Model for 6 US Cities",

abstract = "Background. Heterogeneity in HIV microepidemics across US cities necessitates locally oriented, combination implementation strategies to prioritize resources. We calibrated and validated a dynamic, compartmental HIV transmission model to establish a status quo treatment scenario, holding constant current levels of care for 6 US cities. Methods. Built off a comprehensive evidence synthesis, we adapted and extended a previously published model to replicate the transmission, progression, and clinical care for each microepidemic. We identified a common set of 17 calibration targets between 2012 and 2015 and used the Morris method to select the most influential parameters for calibration. We then applied the Nelder-Mead algorithm to iteratively calibrate the model to generate 2000 best-fitting parameter sets. Finally, model projections were internally validated with a series of robustness checks and externally validated against published estimates of HIV incidence, while the face validity of 25-year projections was assessed by a Scientific Advisory Committee (SAC). Results. We documented our process for model development, calibration, and validation to maximize its transparency and reproducibility. The projected outcomes demonstrated a good fit to calibration targets, with a mean goodness-of-fit ranging from 0.0174 (New York City [NYC]) to 0.0861 (Atlanta). Most of the incidence predictions were within the uncertainty range for 5 of the 6 cities (ranging from 21% [Miami] to 100% [NYC]), demonstrating good external validity. The face validity of the long-term projections was confirmed by our SAC, showing that the incidence would decrease or remain stable in Atlanta, Los Angeles, NYC, and Seattle while increasing in Baltimore and Miami. Discussion. This exercise provides a basis for assessing the incremental value of further investments in HIV combination implementation strategies tailored to urban HIV microepidemics.",

keywords = "HIV/AIDS, dynamic transmission model, epidemiological projection, model calibration, model validation",

author = "Xiao Zang and Emanuel Krebs and Min, {Jeong E.} and Ankur Pandya and Marshall, {Brandon D.L.} and Schackman, {Bruce R.} and Behrends, {Czarina N.} and Feaster, {Daniel J.} and Bohdan Nosyk and Behrends, {Czarina N.} and {Del Rio}, Carlos and Julia Dombrowski and Feaster, {Daniel J.} and Kelly Gebo and Matthew Golden and Reuben Granich and Thomas Kerr and Gregory Kirk and Marshall, {Brandon D.L.} and Mehta, {Shruti H.} and Lisa Metsch and Julio Montaner and Schackman, {Bruce R.} and Steven Shoptaw and William Small and Strathdee, {Steffanie A.}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2019.",

year = "2020",

month = jan,

day = "1",

doi = "10.1177/0272989X19889356",

language = "English (US)",

volume = "40",

pages = "3--16",

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T1 - Development and Calibration of a Dynamic HIV Transmission Model for 6 US Cities

AU - Zang, Xiao

AU - Krebs, Emanuel

AU - Min, Jeong E.

AU - Pandya, Ankur

AU - Marshall, Brandon D.L.

AU - Schackman, Bruce R.

AU - Behrends, Czarina N.

AU - Feaster, Daniel J.

AU - Nosyk, Bohdan

AU - Behrends, Czarina N.

AU - Del Rio, Carlos

AU - Dombrowski, Julia

AU - Feaster, Daniel J.

AU - Gebo, Kelly

AU - Golden, Matthew

AU - Granich, Reuben

AU - Kerr, Thomas

AU - Kirk, Gregory

AU - Marshall, Brandon D.L.

AU - Mehta, Shruti H.

AU - Metsch, Lisa

AU - Montaner, Julio

AU - Schackman, Bruce R.

AU - Shoptaw, Steven

AU - Small, William

AU - Strathdee, Steffanie A.

PY - 2020/1/1

Y1 - 2020/1/1

N2 - Background. Heterogeneity in HIV microepidemics across US cities necessitates locally oriented, combination implementation strategies to prioritize resources. We calibrated and validated a dynamic, compartmental HIV transmission model to establish a status quo treatment scenario, holding constant current levels of care for 6 US cities. Methods. Built off a comprehensive evidence synthesis, we adapted and extended a previously published model to replicate the transmission, progression, and clinical care for each microepidemic. We identified a common set of 17 calibration targets between 2012 and 2015 and used the Morris method to select the most influential parameters for calibration. We then applied the Nelder-Mead algorithm to iteratively calibrate the model to generate 2000 best-fitting parameter sets. Finally, model projections were internally validated with a series of robustness checks and externally validated against published estimates of HIV incidence, while the face validity of 25-year projections was assessed by a Scientific Advisory Committee (SAC). Results. We documented our process for model development, calibration, and validation to maximize its transparency and reproducibility. The projected outcomes demonstrated a good fit to calibration targets, with a mean goodness-of-fit ranging from 0.0174 (New York City [NYC]) to 0.0861 (Atlanta). Most of the incidence predictions were within the uncertainty range for 5 of the 6 cities (ranging from 21% [Miami] to 100% [NYC]), demonstrating good external validity. The face validity of the long-term projections was confirmed by our SAC, showing that the incidence would decrease or remain stable in Atlanta, Los Angeles, NYC, and Seattle while increasing in Baltimore and Miami. Discussion. This exercise provides a basis for assessing the incremental value of further investments in HIV combination implementation strategies tailored to urban HIV microepidemics.

AB - Background. Heterogeneity in HIV microepidemics across US cities necessitates locally oriented, combination implementation strategies to prioritize resources. We calibrated and validated a dynamic, compartmental HIV transmission model to establish a status quo treatment scenario, holding constant current levels of care for 6 US cities. Methods. Built off a comprehensive evidence synthesis, we adapted and extended a previously published model to replicate the transmission, progression, and clinical care for each microepidemic. We identified a common set of 17 calibration targets between 2012 and 2015 and used the Morris method to select the most influential parameters for calibration. We then applied the Nelder-Mead algorithm to iteratively calibrate the model to generate 2000 best-fitting parameter sets. Finally, model projections were internally validated with a series of robustness checks and externally validated against published estimates of HIV incidence, while the face validity of 25-year projections was assessed by a Scientific Advisory Committee (SAC). Results. We documented our process for model development, calibration, and validation to maximize its transparency and reproducibility. The projected outcomes demonstrated a good fit to calibration targets, with a mean goodness-of-fit ranging from 0.0174 (New York City [NYC]) to 0.0861 (Atlanta). Most of the incidence predictions were within the uncertainty range for 5 of the 6 cities (ranging from 21% [Miami] to 100% [NYC]), demonstrating good external validity. The face validity of the long-term projections was confirmed by our SAC, showing that the incidence would decrease or remain stable in Atlanta, Los Angeles, NYC, and Seattle while increasing in Baltimore and Miami. Discussion. This exercise provides a basis for assessing the incremental value of further investments in HIV combination implementation strategies tailored to urban HIV microepidemics.

KW - HIV/AIDS

KW - dynamic transmission model

KW - epidemiological projection

KW - model calibration

KW - model validation

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Development and Calibration of a Dynamic HIV Transmission Model for 6 US Cities

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