Amar Aganovic
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Explore the profile of Amar Aganovic including associated specialties, affiliations and a list of published articles.
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11
Citations
49
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Recent Articles
1.
Aganovic A, Buonanno G, Cao G, Delmaar C, Kurnitski J, Mikszewski A, et al.
Infect Dis Model
. 2024 Dec;
10(1):338-352.
PMID: 39703817
The COVID-19 pandemic, caused by SARS-CoV-2, highlighted the importance of understanding transmission modes and implementing effective mitigation strategies. Recognizing airborne transmission as a primary route has reshaped public health measures,...
2.
Aganovic A, Kurnitski J, Wargocki P
Sci Total Environ
. 2024 Apr;
927:172278.
PMID: 38583631
The Wells-Riley model is extensively used for retrospective and prospective modelling of the risk of airborne transmission of infection in indoor spaces. It is also used when examining the efficacy...
3.
Aganovic A, Kadric E
Risk Anal
. 2023 Jun;
44(3):631-640.
PMID: 37317640
The risk assessments during the COVID-19 pandemic were primarily based on dose-response models derived from the pooled datasets for infection of animals susceptible to SARS-CoV. Despite similarities, differences in susceptibility...
4.
Aganovic A
Front Microbiol
. 2023 May;
14:1190463.
PMID: 37234537
The ongoing SARS-CoV-2 pandemic and the influenza epidemics have revived the interest in understanding how these highly contagious enveloped viruses respond to alterations in the physicochemical properties of their microenvironment....
5.
Aganovic A, Cao G, Kurnitski J, Wargocki P
Build Environ
. 2022 Dec;
228:109924.
PMID: 36531865
Predictive models for airborne infection risk have been extensively used during the pandemic, but there is yet still no consensus on a common approach, which may create misinterpretation of results...
6.
Zonal modeling of air distribution impact on the long-range airborne transmission risk of SARS-CoV-2
Aganovic A, Cao G, Kurnitski J, Melikov A, Wargocki P
Appl Math Model
. 2022 Sep;
112:800-821.
PMID: 36060304
A widely used analytical model to quantitatively assess airborne infection risk is the Wells-Riley model which is limited to complete air mixing in a single zone. However, this assumption tends...
7.
Aganovic A, Bi Y, Cao G, Kurnitski J, Wargocki P
Sci Rep
. 2022 Jul;
12(1):11481.
PMID: 35798789
With a modified version of the Wells-Riley model, we simulated the size distribution and dynamics of five airborne viruses (measles, influenza, SARS-CoV-2, human rhinovirus, and adenovirus) emitted from a speaking...
8.
Bi Y, Aganovic A, Mathisen H, Cao G
Build Environ
. 2022 Apr;
217:109091.
PMID: 35469260
The purpose of this study was to reveal the exposure level of surgical staff to severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) from the patient's nose and wound during operations...
9.
Aganovic A, Bi Y, Cao G, Drangsholt F, Kurnitski J, Wargocki P
Build Environ
. 2021 Aug;
205:108278.
PMID: 34456454
Practical Implications: The present results show that humidification to moderate levels of 40%-60% RH should not be expected to provide a significant reduction in infection risk caused by SARS-CoV-2, hence...
10.
Cheng Z, Aganovic A, Cao G, Bu Z
Environ Sci Pollut Res Int
. 2021 Feb;
28(24):30642-30663.
PMID: 33587275
The traditional mixing ventilation is not an energy effective approach to remove indoor air pollutants, maintain breath zone air quality, and control the airborne transmission. This study investigated the potential...