TY - GEN
T1 - Towards a Phylogenetic Measure to Quantify HIV Incidence
AU - Libin, Pieter
AU - Versbraegen, Nassim
AU - Abecasis, Ana B.
AU - Gomes, Perpetua
AU - Lenaerts, Tom
AU - Nowé, Ann
N1 - Publisher Copyright:
© 2020, Springer Nature Switzerland AG.
PY - 2020
Y1 - 2020
N2 - One of the cornerstones in combating the HIV pandemic is the ability to assess the current state and evolution of local HIV epidemics. This remains a complex problem, as many HIV infected individuals remain unaware of their infection status, leading to parts of HIV epidemics being undiagnosed and under-reported. We first present a method to learn epidemiological parameters from phylogenetic trees, using approximate Bayesian computation (ABC). The epidemiological parameters learned as a result of applying ABC are subsequently used in epidemiological models that aim to simulate a specific epidemic. Secondly, we continue by describing the development of a tree statistic, rooted in coalescent theory, which we use to relate epidemiological parameters to a phylogenetic tree, by using the simulated epidemics. We show that the presented tree statistic enables differentiation of epidemiological parameters, while only relying on phylogenetic trees, thus enabling the construction of new methods to ascertain the epidemiological state of an HIV epidemic. By using genetic data to infer epidemic sizes, we expect to enhance our understanding of the portions of the infected population in which diagnosis rates are low.
AB - One of the cornerstones in combating the HIV pandemic is the ability to assess the current state and evolution of local HIV epidemics. This remains a complex problem, as many HIV infected individuals remain unaware of their infection status, leading to parts of HIV epidemics being undiagnosed and under-reported. We first present a method to learn epidemiological parameters from phylogenetic trees, using approximate Bayesian computation (ABC). The epidemiological parameters learned as a result of applying ABC are subsequently used in epidemiological models that aim to simulate a specific epidemic. Secondly, we continue by describing the development of a tree statistic, rooted in coalescent theory, which we use to relate epidemiological parameters to a phylogenetic tree, by using the simulated epidemics. We show that the presented tree statistic enables differentiation of epidemiological parameters, while only relying on phylogenetic trees, thus enabling the construction of new methods to ascertain the epidemiological state of an HIV epidemic. By using genetic data to infer epidemic sizes, we expect to enhance our understanding of the portions of the infected population in which diagnosis rates are low.
KW - Approximate bayesian computation
KW - Coalescent theory
KW - HIV incidence
KW - Phylogenetics
UR - http://www.scopus.com/inward/record.url?scp=85101841042&partnerID=8YFLogxK
U2 - 10.1007/978-3-030-65154-1_3
DO - 10.1007/978-3-030-65154-1_3
M3 - Conference contribution
AN - SCOPUS:85101841042
SN - 9783030651534
T3 - Communications in Computer and Information Science
SP - 34
EP - 50
BT - Artificial Intelligence and Machine Learning - 31st Benelux AI Conference, BNAIC 2019, and 28th Belgian-Dutch Machine Learning Conference, BENELEARN 2019, Revised Selected Papers
A2 - Bogaerts, Bart
A2 - Bontempi, Gianluca
A2 - Geurts, Pierre
A2 - Harley, Nick
A2 - Lebichot, Bertrand
A2 - Lenaerts, Tom
A2 - Louppe, Gilles
PB - Springer Science and Business Media Deutschland GmbH
T2 - 31st Benelux Conference on Artificial Intelligence, BNAIC 2019 and 28th Belgian Dutch Machine Learning Conference, BENELEARN 2019
Y2 - 6 November 2019 through 8 November 2019
ER -