Integrated PM–MOX–thermal sensing for monitoring bioaerosol dynamics in controlled indoor environments

Barbosa, Maria Inês; Roxo, Hugo; Ribeiro, Pedro; Menezes, José; Vieira, Eduarda; Moreira, Patrícia; Rodrigues, Pedro Miguel

Publicação

Integrated PM–MOX–thermal sensing for monitoring bioaerosol dynamics in controlled indoor environments

2026-06-01Artigo de investigação

dc.contributor.author	Barbosa, Maria Inês
dc.contributor.author	Roxo, Hugo
dc.contributor.author	Ribeiro, Pedro
dc.contributor.author	Menezes, José
dc.contributor.author	Vieira, Eduarda
dc.contributor.author	Moreira, Patrícia
dc.contributor.author	Rodrigues, Pedro Miguel
dc.date.accessioned	2026-06-23T16:11:37Z
dc.date.available	2026-06-23T16:11:37Z
dc.date.issued	2026-06-01
dc.description.abstract	Indoor monitoring of biological contamination is essential for protecting cultural heritage and public health. However, conventional culture-based methods limit timely intervention. This study presents an affordable modular multisensor system for indirectly detecting airborne fungal contamination using Penicillium chrysogenum as a representative model organism and its environmental signatures. The proposed prototype integrates PMSA003I, BME688 and AMG8833 sensors and was evaluated under controlled environmental conditions. Biological ground truth was established using a volumetric inertial-impaction sampling protocol (SAS sampler), validating four contamination levels (~6 to 165, CFU/m3). A total of 1989 observations were analyzed. Non-parametric statistical tests (Kruskal–Wallis and Mann–Whitney U) confirmed significant differences between all the exposure conditions (𝑝<0.001). Supervised machine learning (ML) models showed strong performance across all the classification tasks, with accuracy and AUC values near 100%. In most cases, pressure alone was sufficient. The statistical and ML analyses consistently identified pressure, particulate-related variables, gas resistance and humidity as the most informative features. Overall, the results indicate that the proposed approach can reliably capture indirect environmental signatures associated with airborne fungal presence under controlled conditions. The study supports the feasibility of low-cost multisensor systems for continuous indoor bioaerosol monitoring while highlighting the need for further optimization and validation in real-world environments.	eng
dc.identifier.doi	10.3390/s26113521
dc.identifier.eid	105041422134
dc.identifier.other	3d25b160-fa3f-4173-ba70-0ea2d01796a0
dc.identifier.pmid	42281036
dc.identifier.uri	http://hdl.handle.net/10400.14/58237
dc.identifier.wos	001790672600001
dc.language.iso	eng
dc.peerreviewed	yes
dc.publisher	MDPI
dc.rights.uri	http://creativecommons.org/licenses/by/4.0/
dc.subject	Bioaerosols	eng
dc.subject	Indoor contamination monitoring	eng
dc.subject	Multisensor systems	eng
dc.subject	MOX	eng
dc.subject	mVOCs	eng
dc.subject	Particulate matter sensing	eng
dc.subject	Thermographic sensing	eng
dc.subject	Penicillium chrysogenum	eng
dc.title	Integrated PM–MOX–thermal sensing for monitoring bioaerosol dynamics in controlled indoor environments
dc.type	research article
dspace.entity.type	Publication
oaire.citation.issue	11
oaire.citation.volume	26
oaire.version	http://purl.org/coar/version/c_970fb48d4fbd8a85

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