Use of multidimensional item response theory methods for dementia prevalence prediction: an example using the Health and Retirement Survey and the Aging, Demographics, and Memory Study

GBD 2019 Dementia Collaborators; Mohammad Hamiduzzaman

doi:10.1186/s12911-021-01590-y

Use of multidimensional item response theory methods for dementia prevalence prediction: an example using the Health and Retirement Survey and the Aging, Demographics, and Memory Study

GBD 2019 Dementia Collaborators, Mohammad Hamiduzzaman

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

4 Citations (Scopus)

21 Downloads (Pure)

Abstract

Background: Data sparsity is a major limitation to estimating national and global dementia burden. Surveys with full diagnostic evaluations of dementia prevalence are prohibitively resource-intensive in many settings. However, validation samples from nationally representative surveys allow for the development of algorithms for the prediction of dementia prevalence nationally. Methods: Using cognitive testing data and data on functional limitations from Wave A (2001–2003) of the ADAMS study (n = 744) and the 2000 wave of the HRS study (n = 6358) we estimated a two-dimensional item response theory model to calculate cognition and function scores for all individuals over 70. Based on diagnostic information from the formal clinical adjudication in ADAMS, we fit a logistic regression model for the classification of dementia status using cognition and function scores and applied this algorithm to the full HRS sample to calculate dementia prevalence by age and sex. Results: Our algorithm had a cross-validated predictive accuracy of 88% (86–90), and an area under the curve of 0.97 (0.97–0.98) in ADAMS. Prevalence was higher in females than males and increased over age, with a prevalence of 4% (3–4) in individuals 70–79, 11% (9–12) in individuals 80–89 years old, and 28% (22–35) in those 90 and older. Conclusions: Our model had similar or better accuracy as compared to previously reviewed algorithms for the prediction of dementia prevalence in HRS, while utilizing more flexible methods. These methods could be more easily generalized and utilized to estimate dementia prevalence in other national surveys.

Original language	English
Article number	241
Number of pages	10
Journal	BMC Medical Informatics and Decision Making
Volume	21
Issue number	1
DOIs	https://doi.org/10.1186/s12911-021-01590-y
Publication status	Published - 11 Aug 2021

Keywords

Algorithm
Dementia
Global health
Prevalence
Validity

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10.1186/s12911-021-01590-yLicence: CC BY

Published versionFinal published version, 1.14 MBLicence: CC BY

Cite this

@article{48cbef9aaead4e94ab85bb3a11575d0c,

title = "Use of multidimensional item response theory methods for dementia prevalence prediction: an example using the Health and Retirement Survey and the Aging, Demographics, and Memory Study",

abstract = "Background: Data sparsity is a major limitation to estimating national and global dementia burden. Surveys with full diagnostic evaluations of dementia prevalence are prohibitively resource-intensive in many settings. However, validation samples from nationally representative surveys allow for the development of algorithms for the prediction of dementia prevalence nationally. Methods: Using cognitive testing data and data on functional limitations from Wave A (2001–2003) of the ADAMS study (n = 744) and the 2000 wave of the HRS study (n = 6358) we estimated a two-dimensional item response theory model to calculate cognition and function scores for all individuals over 70. Based on diagnostic information from the formal clinical adjudication in ADAMS, we fit a logistic regression model for the classification of dementia status using cognition and function scores and applied this algorithm to the full HRS sample to calculate dementia prevalence by age and sex. Results: Our algorithm had a cross-validated predictive accuracy of 88% (86–90), and an area under the curve of 0.97 (0.97–0.98) in ADAMS. Prevalence was higher in females than males and increased over age, with a prevalence of 4% (3–4) in individuals 70–79, 11% (9–12) in individuals 80–89 years old, and 28% (22–35) in those 90 and older. Conclusions: Our model had similar or better accuracy as compared to previously reviewed algorithms for the prediction of dementia prevalence in HRS, while utilizing more flexible methods. These methods could be more easily generalized and utilized to estimate dementia prevalence in other national surveys.",

keywords = "Algorithm, Dementia, Global health, Prevalence, Validity",

author = "{GBD 2019 Dementia Collaborators} and Emma Nichols and Foad Abd-Allah and Amir Abdoli and Ahmed Abualhasan and Eman Abu-Gharbieh and Ashkan Afshin and Akinyemi, {Rufus Olusola} and Alanezi, {Fahad Mashhour} and Vahid Alipour and Amir Almasi-Hashiani and Jalal Arabloo and Amir Ashraf-Ganjouei and Getinet Ayano and Ayuso-Mateos, {Jose L.} and Baig, {Atif Amin} and Maciej Banach and Barboza, {Miguel A.} and Barker-Collo, {Suzanne Lyn} and Baune, {Bernhard T.} and Bhagavathula, {Akshaya Srikanth} and Krittika Bhattacharyya and Ali Bijani and Atanu Biswas and Archith Boloor and Carol Brayne and Hermann Brenner and Katrin Burkart and {Burugina Nagaraja}, Sharath and Felix Carvalho and Castro-de-Araujo, {Luis F.S.} and Ferr{\'a}n Catal{\'a}-L{\'o}pez and Ester Cerin and Nicolas Cherbuin and Chu, {Dinh Toi} and Xiaochen Dai and {de S{\'a}-Junior}, {Antonio Reis} and Shirin Djalalinia and Abdel Douiri and David Edvardsson and El-Jaafary, {Shaimaa I.} and Sharareh Eskandarieh and Andre Faro and Farshad Farzadfar and Feigin, {Valery L.} and Fereshtehnejad, {Seyed Mohammad} and Eduarda Fernandes and Pietro Ferrara and Irina Filip and Florian Fischer and Shilpa Gaidhane and Lucia Galluzzo and Gebremeskel, {Gebreamlak Gebremedhn} and Ahmad Ghashghaee and Alessandro Gialluisi and Gnedovskaya, {Elena V.} and Mahaveer Golechha and Rajeev Gupta and Vladimir Hachinski and Haider, {Mohammad Rifat} and Haile, {Teklehaimanot Gereziher} and Mohammad Hamiduzzaman and Hankey, {Graeme J.} and Hay, {Simon I.} and Golnaz Heidari and Reza Heidari-Soureshjani and Ho, {Hung Chak} and Mowafa Househ and Hwang, {Bing Fang} and Licia Iacoviello and Ilesanmi, {Olayinka Stephen} and Ilic, {Irena M.} and Ilic, {Milena D.} and Irvani, {Seyed Sina Naghibi} and Masao Iwagami and Iyamu, {Ihoghosa Osamuyi} and Jha, {Ravi Prakash} and Rizwan Kalani and Andr{\'e} Karch and Kasa, {Ayele Semachew} and Khader, {Yousef Saleh} and Khan, {Ejaz Ahmad} and Khatib, {Mahalaqua Nazli} and Kim, {Yun Jin} and Sezer Kisa and Adnan Kisa and Mika Kivim{\"a}ki and Ai Koyanagi and Manasi Kumar and Iv{\'a}n Landires and Savita Lasrado and Bingyu Li and Lim, {Stephen S.} and Xuefeng Liu and {Madhava Kunjathur}, Shilpashree and Azeem Majeed and Preeti Malik and Mehndiratta, {Man Mohan} and Menezes, {Ritesh G.} and Yousef Mohammad and Salahuddin Mohammed and Mokdad, {Ali H.} and Moni, {Mohammad Ali} and Gabriele Nagel and Muhammad Naveed and Nayak, {Vinod C.} and Nguyen, {Cuong Tat} and Nguyen, {Huong Lan Thi} and Virginia Nunez-Samudio and Olagunju, {Andrew T.} and Ostroff, {Samuel M.} and Nikita Otstavnov and Owolabi, {Mayowa O.} and {Pashazadeh Kan}, Fatemeh and Patel, {Urvish K.} and Phillips, {Michael R.} and Piradov, {Michael A.} and Pond, {Constance Dimity} and Pottoo, {Faheem Hyder} and Prada, {Sergio I.} and Amir Radfar and Fakher Rahim and Juwel Rana and Vahid Rashedi and Salman Rawaf and Rawaf, {David Laith} and Nickolas Reinig and Renzaho, {Andre M.N.} and Nima Rezaei and Aziz Rezapour and Michele Romoli and Gholamreza Roshandel and Sachdev, {Perminder S.} and Amirhossein Sahebkar and Sahraian, {Mohammad Ali} and Mehrnoosh Samaei and Mete Saylan and Feng Sha and Shaikh, {Masood Ali} and Kenji Shibuya and Mika Shigematsu and Shin, {Jae Il} and Rahman Shiri and Silva, {Diego Augusto Santos} and Singh, {Jasvinder A.} and Deepika Singhal and Skryabin, {Valentin Yurievich} and Skryabina, {Anna Aleksandrovna} and Amin Soheili and Houman Sotoudeh and Spurlock, {Emma Elizabeth} and Szoeke, {Cassandra E.I.} and Rafael Tabar{\'e}s-Seisdedos and Taddele, {Biruk Wogayehu} and Tovani-Palone, {Marcos Roberto} and Tsegaye, {Gebiyaw Wudie} and Marco Vacante and Narayanaswamy Venketasubramanian and Simone Vidale and Vasily Vlassov and Vu, {Giang Thu} and Wang, {Yuan Pang} and Jordan Weiss and Weldemariam, {Abrha Hailay} and Ronny Westerman and Anders Wimo and Winkler, {Andrea Sylvia} and Chenkai Wu and Ali Yadollahpour and Metin Yesiltepe and Naohiro Yonemoto and Chuanhua Yu and Zastrozhin, {Mikhail Sergeevich} and Anasthasia Zastrozhina and Zhang, {Zhi Jiang} and Murray, {Christopher J.L.} and Theo Vos",

year = "2021",

month = aug,

day = "11",

doi = "10.1186/s12911-021-01590-y",

language = "English",

volume = "21",

journal = "BMC Medical Informatics and Decision Making",

issn = "1472-6947",

publisher = "BioMed Central Ltd.",

number = "1",

}

Use of multidimensional item response theory methods for dementia prevalence prediction: an example using the Health and Retirement Survey and the Aging, Demographics, and Memory Study. / GBD 2019 Dementia Collaborators; Hamiduzzaman, Mohammad.
In: BMC Medical Informatics and Decision Making, Vol. 21, No. 1, 241, 11.08.2021.

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

TY - JOUR

T1 - Use of multidimensional item response theory methods for dementia prevalence prediction

T2 - an example using the Health and Retirement Survey and the Aging, Demographics, and Memory Study

AU - GBD 2019 Dementia Collaborators

AU - Nichols, Emma

AU - Abd-Allah, Foad

AU - Abdoli, Amir

AU - Abualhasan, Ahmed

AU - Abu-Gharbieh, Eman

AU - Afshin, Ashkan

AU - Akinyemi, Rufus Olusola

AU - Alanezi, Fahad Mashhour

AU - Alipour, Vahid

AU - Almasi-Hashiani, Amir

AU - Arabloo, Jalal

AU - Ashraf-Ganjouei, Amir

AU - Ayano, Getinet

AU - Ayuso-Mateos, Jose L.

AU - Baig, Atif Amin

AU - Banach, Maciej

AU - Barboza, Miguel A.

AU - Barker-Collo, Suzanne Lyn

AU - Baune, Bernhard T.

AU - Bhagavathula, Akshaya Srikanth

AU - Bhattacharyya, Krittika

AU - Bijani, Ali

AU - Biswas, Atanu

AU - Boloor, Archith

AU - Brayne, Carol

AU - Brenner, Hermann

AU - Burkart, Katrin

AU - Burugina Nagaraja, Sharath

AU - Carvalho, Felix

AU - Castro-de-Araujo, Luis F.S.

AU - Catalá-López, Ferrán

AU - Cerin, Ester

AU - Cherbuin, Nicolas

AU - Chu, Dinh Toi

AU - Dai, Xiaochen

AU - de Sá-Junior, Antonio Reis

AU - Djalalinia, Shirin

AU - Douiri, Abdel

AU - Edvardsson, David

AU - El-Jaafary, Shaimaa I.

AU - Eskandarieh, Sharareh

AU - Faro, Andre

AU - Farzadfar, Farshad

AU - Feigin, Valery L.

AU - Fereshtehnejad, Seyed Mohammad

AU - Fernandes, Eduarda

AU - Ferrara, Pietro

AU - Filip, Irina

AU - Fischer, Florian

AU - Gaidhane, Shilpa

AU - Galluzzo, Lucia

AU - Gebremeskel, Gebreamlak Gebremedhn

AU - Ghashghaee, Ahmad

AU - Gialluisi, Alessandro

AU - Gnedovskaya, Elena V.

AU - Golechha, Mahaveer

AU - Gupta, Rajeev

AU - Hachinski, Vladimir

AU - Haider, Mohammad Rifat

AU - Haile, Teklehaimanot Gereziher

AU - Hamiduzzaman, Mohammad

AU - Hankey, Graeme J.

AU - Hay, Simon I.

AU - Heidari, Golnaz

AU - Heidari-Soureshjani, Reza

AU - Ho, Hung Chak

AU - Househ, Mowafa

AU - Hwang, Bing Fang

AU - Iacoviello, Licia

AU - Ilesanmi, Olayinka Stephen

AU - Ilic, Irena M.

AU - Ilic, Milena D.

AU - Irvani, Seyed Sina Naghibi

AU - Iwagami, Masao

AU - Iyamu, Ihoghosa Osamuyi

AU - Jha, Ravi Prakash

AU - Kalani, Rizwan

AU - Karch, André

AU - Kasa, Ayele Semachew

AU - Khader, Yousef Saleh

AU - Khan, Ejaz Ahmad

AU - Khatib, Mahalaqua Nazli

AU - Kim, Yun Jin

AU - Kisa, Sezer

AU - Kisa, Adnan

AU - Kivimäki, Mika

AU - Koyanagi, Ai

AU - Kumar, Manasi

AU - Landires, Iván

AU - Lasrado, Savita

AU - Li, Bingyu

AU - Lim, Stephen S.

AU - Liu, Xuefeng

AU - Madhava Kunjathur, Shilpashree

AU - Majeed, Azeem

AU - Malik, Preeti

AU - Mehndiratta, Man Mohan

AU - Menezes, Ritesh G.

AU - Mohammad, Yousef

AU - Mohammed, Salahuddin

AU - Mokdad, Ali H.

AU - Moni, Mohammad Ali

AU - Nagel, Gabriele

AU - Naveed, Muhammad

AU - Nayak, Vinod C.

AU - Nguyen, Cuong Tat

AU - Nguyen, Huong Lan Thi

AU - Nunez-Samudio, Virginia

AU - Olagunju, Andrew T.

AU - Ostroff, Samuel M.

AU - Otstavnov, Nikita

AU - Owolabi, Mayowa O.

AU - Pashazadeh Kan, Fatemeh

AU - Patel, Urvish K.

AU - Phillips, Michael R.

AU - Piradov, Michael A.

AU - Pond, Constance Dimity

AU - Pottoo, Faheem Hyder

AU - Prada, Sergio I.

AU - Radfar, Amir

AU - Rahim, Fakher

AU - Rana, Juwel

AU - Rashedi, Vahid

AU - Rawaf, Salman

AU - Rawaf, David Laith

AU - Reinig, Nickolas

AU - Renzaho, Andre M.N.

AU - Rezaei, Nima

AU - Rezapour, Aziz

AU - Romoli, Michele

AU - Roshandel, Gholamreza

AU - Sachdev, Perminder S.

AU - Sahebkar, Amirhossein

AU - Sahraian, Mohammad Ali

AU - Samaei, Mehrnoosh

AU - Saylan, Mete

AU - Sha, Feng

AU - Shaikh, Masood Ali

AU - Shibuya, Kenji

AU - Shigematsu, Mika

AU - Shin, Jae Il

AU - Shiri, Rahman

AU - Silva, Diego Augusto Santos

AU - Singh, Jasvinder A.

AU - Singhal, Deepika

AU - Skryabin, Valentin Yurievich

AU - Skryabina, Anna Aleksandrovna

AU - Soheili, Amin

AU - Sotoudeh, Houman

AU - Spurlock, Emma Elizabeth

AU - Szoeke, Cassandra E.I.

AU - Tabarés-Seisdedos, Rafael

AU - Taddele, Biruk Wogayehu

AU - Tovani-Palone, Marcos Roberto

AU - Tsegaye, Gebiyaw Wudie

AU - Vacante, Marco

AU - Venketasubramanian, Narayanaswamy

AU - Vidale, Simone

AU - Vlassov, Vasily

AU - Vu, Giang Thu

AU - Wang, Yuan Pang

AU - Weiss, Jordan

AU - Weldemariam, Abrha Hailay

AU - Westerman, Ronny

AU - Wimo, Anders

AU - Winkler, Andrea Sylvia

AU - Wu, Chenkai

AU - Yadollahpour, Ali

AU - Yesiltepe, Metin

AU - Yonemoto, Naohiro

AU - Yu, Chuanhua

AU - Zastrozhin, Mikhail Sergeevich

AU - Zastrozhina, Anasthasia

AU - Zhang, Zhi Jiang

AU - Murray, Christopher J.L.

AU - Vos, Theo

PY - 2021/8/11

Y1 - 2021/8/11

N2 - Background: Data sparsity is a major limitation to estimating national and global dementia burden. Surveys with full diagnostic evaluations of dementia prevalence are prohibitively resource-intensive in many settings. However, validation samples from nationally representative surveys allow for the development of algorithms for the prediction of dementia prevalence nationally. Methods: Using cognitive testing data and data on functional limitations from Wave A (2001–2003) of the ADAMS study (n = 744) and the 2000 wave of the HRS study (n = 6358) we estimated a two-dimensional item response theory model to calculate cognition and function scores for all individuals over 70. Based on diagnostic information from the formal clinical adjudication in ADAMS, we fit a logistic regression model for the classification of dementia status using cognition and function scores and applied this algorithm to the full HRS sample to calculate dementia prevalence by age and sex. Results: Our algorithm had a cross-validated predictive accuracy of 88% (86–90), and an area under the curve of 0.97 (0.97–0.98) in ADAMS. Prevalence was higher in females than males and increased over age, with a prevalence of 4% (3–4) in individuals 70–79, 11% (9–12) in individuals 80–89 years old, and 28% (22–35) in those 90 and older. Conclusions: Our model had similar or better accuracy as compared to previously reviewed algorithms for the prediction of dementia prevalence in HRS, while utilizing more flexible methods. These methods could be more easily generalized and utilized to estimate dementia prevalence in other national surveys.

AB - Background: Data sparsity is a major limitation to estimating national and global dementia burden. Surveys with full diagnostic evaluations of dementia prevalence are prohibitively resource-intensive in many settings. However, validation samples from nationally representative surveys allow for the development of algorithms for the prediction of dementia prevalence nationally. Methods: Using cognitive testing data and data on functional limitations from Wave A (2001–2003) of the ADAMS study (n = 744) and the 2000 wave of the HRS study (n = 6358) we estimated a two-dimensional item response theory model to calculate cognition and function scores for all individuals over 70. Based on diagnostic information from the formal clinical adjudication in ADAMS, we fit a logistic regression model for the classification of dementia status using cognition and function scores and applied this algorithm to the full HRS sample to calculate dementia prevalence by age and sex. Results: Our algorithm had a cross-validated predictive accuracy of 88% (86–90), and an area under the curve of 0.97 (0.97–0.98) in ADAMS. Prevalence was higher in females than males and increased over age, with a prevalence of 4% (3–4) in individuals 70–79, 11% (9–12) in individuals 80–89 years old, and 28% (22–35) in those 90 and older. Conclusions: Our model had similar or better accuracy as compared to previously reviewed algorithms for the prediction of dementia prevalence in HRS, while utilizing more flexible methods. These methods could be more easily generalized and utilized to estimate dementia prevalence in other national surveys.

KW - Algorithm

KW - Dementia

KW - Global health

KW - Prevalence

KW - Validity

UR - http://www.scopus.com/inward/record.url?scp=85112536036&partnerID=8YFLogxK

U2 - 10.1186/s12911-021-01590-y

DO - 10.1186/s12911-021-01590-y

M3 - Article

AN - SCOPUS:85112536036

SN - 1472-6947

VL - 21

JO - BMC Medical Informatics and Decision Making

JF - BMC Medical Informatics and Decision Making

IS - 1

M1 - 241

ER -

Use of multidimensional item response theory methods for dementia prevalence prediction: an example using the Health and Retirement Survey and the Aging, Demographics, and Memory Study

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Keywords

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