Optimal control of HIV resistance and tuberculosis co-infection using treatment intervention

Optimal control of HIV resistance and tuberculosis co-infection using treatment intervention

In this paper we presented a mathematical model of the spread of HIV and tuberculosis (TB) co-infection considering the resistance of HIV to antiretroviral (ARV) drugs. The model also included anti-TB and ARV treatments as system control variables. For the model without controls, we investigated the...

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Main Authors: Fatmawati, .-, Hengki Tasman, .-
Format: Article PeerReviewed
Language:English
English
English
English
Published: Asian Pacific Journal of Tropical Disease 2017
Subjects:
Q Science
QA Mathematics
QA370-387 Differential Equations
Online Access:https://repository.unair.ac.id/114281/1/C16.%20Fulltext.pdf
https://repository.unair.ac.id/114281/2/C16.%20Reviewer%20dan%20validasi.pdf
https://repository.unair.ac.id/114281/3/C16.%20Similarity.pdf
https://repository.unair.ac.id/114281/4/C16.%20Submission.pdf
https://repository.unair.ac.id/114281/
https://oaji.net/articles/2017/3556-1496971582.pdf
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Institution: Universitas Airlangga
Language: English
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spelling id-langga.1142812022-03-22T15:03:50Z https://repository.unair.ac.id/114281/ Optimal control of HIV resistance and tuberculosis co-infection using treatment intervention Fatmawati, .- Hengki Tasman, .- Q Science QA Mathematics QA370-387 Differential Equations In this paper we presented a mathematical model of the spread of HIV and tuberculosis (TB) co-infection considering the resistance of HIV to antiretroviral (ARV) drugs. The model also included anti-TB and ARV treatments as system control variables. For the model without controls, we investigated the existence and stability of equilibria based on three basic reproduction numbers corresponding to the TB and two strains HIV infection. We also performed sensitivity analysis to determine the dominant factor controlling the spread. Then, the optimal control condition was derived using Pontryagin Maximum Principle on the model to achieve the goal of minimizing the number of infected population. The numerical simulations of the optimal control were also performed to illustrate the results. Asian Pacific Journal of Tropical Disease 2017 Article PeerReviewed text en https://repository.unair.ac.id/114281/1/C16.%20Fulltext.pdf text en https://repository.unair.ac.id/114281/2/C16.%20Reviewer%20dan%20validasi.pdf text en https://repository.unair.ac.id/114281/3/C16.%20Similarity.pdf text en https://repository.unair.ac.id/114281/4/C16.%20Submission.pdf Fatmawati, .- and Hengki Tasman, .- (2017) Optimal control of HIV resistance and tuberculosis co-infection using treatment intervention. Asian Pacific Journal of Tropical Disease, 7 (6). pp. 366-373. ISSN 22221808 https://oaji.net/articles/2017/3556-1496971582.pdf
institution Universitas Airlangga
building Universitas Airlangga Library
continent Asia
country Indonesia
Indonesia
content_provider Universitas Airlangga Library
collection UNAIR Repository
language English
English
English
English
topic Q Science
QA Mathematics
QA370-387 Differential Equations
spellingShingle Q Science
QA Mathematics
QA370-387 Differential Equations
Fatmawati, .-
Hengki Tasman, .-
Optimal control of HIV resistance and tuberculosis co-infection using treatment intervention
description In this paper we presented a mathematical model of the spread of HIV and tuberculosis (TB) co-infection considering the resistance of HIV to antiretroviral (ARV) drugs. The model also included anti-TB and ARV treatments as system control variables. For the model without controls, we investigated the existence and stability of equilibria based on three basic reproduction numbers corresponding to the TB and two strains HIV infection. We also performed sensitivity analysis to determine the dominant factor controlling the spread. Then, the optimal control condition was derived using Pontryagin Maximum Principle on the model to achieve the goal of minimizing the number of infected population. The numerical simulations of the optimal control were also performed to illustrate the results.
format Article
PeerReviewed
author Fatmawati, .-
Hengki Tasman, .-
author_facet Fatmawati, .-
Hengki Tasman, .-
author_sort Fatmawati, .-
title Optimal control of HIV resistance and tuberculosis co-infection using treatment intervention
title_short Optimal control of HIV resistance and tuberculosis co-infection using treatment intervention
title_full Optimal control of HIV resistance and tuberculosis co-infection using treatment intervention
title_fullStr Optimal control of HIV resistance and tuberculosis co-infection using treatment intervention
title_full_unstemmed Optimal control of HIV resistance and tuberculosis co-infection using treatment intervention
title_sort optimal control of hiv resistance and tuberculosis co-infection using treatment intervention
publisher Asian Pacific Journal of Tropical Disease
publishDate 2017
url https://repository.unair.ac.id/114281/1/C16.%20Fulltext.pdf
https://repository.unair.ac.id/114281/2/C16.%20Reviewer%20dan%20validasi.pdf
https://repository.unair.ac.id/114281/3/C16.%20Similarity.pdf
https://repository.unair.ac.id/114281/4/C16.%20Submission.pdf
https://repository.unair.ac.id/114281/
https://oaji.net/articles/2017/3556-1496971582.pdf
_version_ 1728422290785304576

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