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Acute particulate matter exposure diminishes executive cognitive
functioning after four hours regardless of inhalation pathway
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  * Open access
  * Published: 06 February 2025

Acute particulate matter exposure diminishes executive cognitive
functioning after four hours regardless of inhalation pathway

  * Thomas Faherty  ORCID: orcid.org/0000-0003-4064-9034^1,
  * Jane E. Raymond^2,
  * Gordon McFiggans  ORCID: orcid.org/0000-0002-3423-7896^3 &
  * ...
  * Francis D. Pope  ORCID: orcid.org/0000-0001-6583-8347^1 

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Nature Communications volume 16, Article number: 1339 (2025) Cite
this article

  * Metrics details

Subjects

  * Atmospheric chemistry
  * Human behaviour
  * Psychology and behaviour

Abstract

Recent evidence suggests short-term exposure to particulate matter
(PM) air pollution can impact brain function after a delay period. It
is unknown whether effects are predominantly due to the olfactory or
lung-brain pathways. In this study 26 adults (M[age] = 27.7, SD[age] 
= 10.6) participated in four conditions. They were exposed to either
high PM concentrations or clean air for one hour, using normal
inhalation or restricted nasal inhalation and olfaction with a nose
clip. Participants completed four cognitive tests before and four
hours after exposure, assessing working memory, selective attention,
emotion expression discrimination, and psychomotor vigilance. Results
showed significant reductions in selective attention and emotion
expression discrimination after enhanced PM versus clean air
exposure. Air quality did not significantly impact psychomotor
vigilance or working memory performance. Inhalation method did not
significantly mediate effects, suggesting that short-term PM
pollution affects cognitive function through lung-brain mechanisms,
either directly or indirectly.

Introduction

Globally, air pollution is the leading environmental risk factor to
human health, increasing premature mortality^1. The detrimental
impacts of poor air quality on cardiovascular and respiratory systems
are widely acknowledged^2,3. More recently a growing body of
literature suggests a relationship between lifetime exposure to
low-quality air with altered neurodevelopment^4 and incidence of
neurodegenerative diseases^5,6, such as multiple sclerosis and
Alzheimer's disease^7, Parkinson's disease^8, as well as
neuropsychological illnesses^9. Critically, these diseases are
characterised by decline in cognitive functioning due to the death of
cortical neurons.

Particulate matter (PM) air pollution in the PM[2.5] size range, PM
with diameters <= 2.5 mm, is the class of air pollutants most
responsible for human health effects. In 2015 ~4.2 million deaths
were attributed to PM[2.5] alone^10. Currently, the World Health
Organization (WHO) recommend that 24-h and annual limits of PM[2.5]
should not exceed 15 and 5 mgm^-3, respectively^11. Recent evidence
suggests that short-term exposure to particulate PM air pollution can
temporarily impair several key cognitive functions, including
selective attention^12,13,14, switch costs (which are relevant to
multitasking)^15, decision-making^16, processing speed^12,15,
functional connectivity^17, and even global cognitive functioning as
assessed by the Mini-Mental State Examination (MMSE)^18,19.

Cognitive functioning encompasses a diverse array of mental processes
crucial for everyday tasks. Supermarket shopping illustrates the
independence and interdependence of different cognitive functions.
Executive function, especially selective attention, aids in
decision-making and goal-directed behaviour^20, such as prioritising
items on your shopping list while filtering out distractions from
other products and avoiding impulse buys. Working memory serves as a
temporary workspace for holding and manipulating information, vital
for tasks requiring simultaneous processing and storage^21, like
comparing prices and/or brands to make informed purchases.
Socio-emotional cognition involves the ability to detect and
interpret emotions in oneself and others, facilitating social
interactions and empathy^22, enabling socially acceptable behaviour
during shopping. Although these skills are separate cognitive facets,
they work together to enable the successful completion of everyday
tasks. Considering each facet separately allows investigation into
the cognitive processes most vulnerable and susceptible to disruption
from air pollution exposure, essential for targeted interventions and
promoting resilience.

While the precise mechanism by which air pollution exerts acute and
chronic effects on the brain remains a topic of ongoing debate and
research, two main mechanistic models which are not mutually
exclusive, have been proposed. The first proposed model stipulates
that these effects stem from the direct impact of nasally inhaled
particles or chemical constituents with both neurons and non-neuronal
glial cells in the brain. This impact is thought to occur via
translocation along olfactory neurons to the olfactory bulb^23,24,25.
Olfactory sensory neurons have a diameter of ~200 nm^26, potentially
allowing ultrafine particles (<= 100 nm)^27 to translocate through
this process. However, direct impact could also occur via the
exchange of soluble particle components in the lungs^28 and for
particles fine enough, entry to the blood stream^29, leading to
eventual translocation across the blood-brain barrier from
circulation^30,31. The 'direct' model gains support from evidence of
combustion-like nanoparticles found in the brains of animals and
humans residing in polluted environments^32, with biomarkers
indicating features associated with early dementia, microglia immune
defence activation, and neuronal injury^33. The observation that the
olfactory bulb is a 'hot spot' for this type of neuronal damage^34
support the notion of a nasal route of impact. This suggests that
blocking nasal inhalation might lessen the direct effect of air
pollution on brain function. In summary, the direct model proposes
that the inhalation of air pollution via the olfactory and
respiratory pathways together converges toward cognitive impairments
through direct processes.

The second proposed mechanism, the 'indirect' model, stipulates that
neuronal damage arises from adverse effects of systemic inflammation
caused by the presence of air pollution in the lungs. It is well
known that both chronic and acute systemic inflammation can lead to
deleterious effects on central nervous system functions, such as
cognition and motivation, via glial-neurovascular activity^23,35. In
this view, neuronal impacts are considered an indirect result of
inflammatory mediators activated in the lungs, which trigger an
immune response that subsequently induces oxidative stress and
neuroinflammation^36,37,38,39. The effect of inflammation on
cognition is widely observed within the literature^40,41,42,43,44,45,
46. As with other instigators of systemic inflammation, this view
suggests that air pollution exposure should take several hours to
induce effects on neuronal activity and cognition. It further
suggests that any effects would be unaffected by the presence or
absence of nasal inhalation.

Whilst the two models propose distinct processes, a time-lag is
expected between inhalation and the manifestation of cognitive or
behavioural effects resulting from an inflammatory response. This
expectation aligns with evidence from studies where inflammation is
induced via vaccination^47,48. In these studies, a transient decline
in cognitive functioning becomes apparent several hours after the
vaccination process^41,42.

Indeed, there is evidence that exposure to PM air pollution requires
a delay of several hours before cognitive, behavioural, or
neurophysiological changes become evident. One cognitive behavioural
study identified an association between recent PM air quality and
Visual Information Processing in school children^12.
Electroencephalography research reveals changes in frontal lobe brain
activity within 30-60 min of exposure to PM pollution from cooking
and diesel exhaust^49,50. Although activity was not measured beyond
this time frame, a separate follow-up study demonstrated that frontal
lobe brainwave alterations persist for up to 4 h after exposure^51.
Another behavioural study found that anti-inflammatory medication
protected against an identified association between modelled recent
PM air pollution exposure and cognitive impairment^19. Individuals
taking anti-inflammatory medication showed no association, but others
showed impaired cognitive function from recent PM pollution exposure.
Integrating across cognitive, behavioural, and neurophysiological
evidence, there is support for the concept that short-term exposure
to PM air pollution triggers inflammation, subsequently leading to
measurable cognitive impairment after a delay period.

Regardless of the model, isolating the respiratory tract may result
in a reduction of cognitive effects across various cognitive domains.
This reduction could arise from the impact on different brain areas
through distinct routes of exposure, or the mediation of cognitive
effects via a global dose reduction following the suppression of the
olfactory pathway. Although direct study of this remains challenging,
a behavioural experimental paradigm can still offer valuable insights
into the investigation of acute PM air pollution exposure on crucial
cognitive functions, and of the comparative negative consequences of
the olfactory pathway.

This study aims to identify if exposure to high PM concentrations
negatively impacts cognitive functioning after 4 h, comparative to
cleaner air. Furthermore, the study aims to identify whether
inhalation route mediates an effect of air quality on cognitive
function. It is the first study to our knowledge to experimentally
manipulate inhalation routes of particulate matter air pollution,
investigating pathway-dependent effects on key cognitive functions.

Results

All participants completed four sessions comprised of (1) a round of
four cognitive tests, (2) a 1-h period of air exposure, (3) a 4-h
delay period, and (4) another round of cognitive tests. Half the
sessions had clean air during the participant exposure period and
half had PM pollution induced by burning and extinguishing a candle
in the exposure room prior to the start of the exposure period.
Pollutant concentration was monitored through the exposure period in
all conditions. In a fully crossed, within-subjects design, half of
each participant's sessions had nasal inhalation restricted (using a
swimming nose clip) during the air exposure period and half did not.
Cognitive tests assessed selective attention, emotion expression
recognition, working memory, and psychomotor vigilance.

Cognitive function

Selective attention

Exposure to PM pollution significantly reduced participant selective
attention performance comparative to clean air exposure, as evidenced
by a significant two-way interaction between pollution exposure and
session time [F(1, 25)  = 6.446, p  = 0.018, ep^2 = 0.205, 1-b =
0.685]. See Fig. 1a. Participants demonstrated an increase in
cognitive control score (DRT) between the PM pollution pre-exposure
(Mean DRT  = 0 ms, s.d.,  = 21) and post-exposure (Mean DRT  = 13 ms,
s.d.,  = 19) measures, indicating a decline in selective attention
performance, as evidenced by an increase in cognitive control scores;
the opposite pattern was identified pre- (Mean DRT  = 5 ms, s.d.,  =
15) and post- (Mean DRT  = -1 ms, s.d.,  = 12) clean air exposure. T
-tests revealed no significant performance differences pre- versus
post- clean air exposure [t(25) = 1.252, p = 0.111], whereas
selective attention performance significantly declined between pre-
and post- PM pollution exposure [t(25) = -2.082, p = 0.024].

Fig. 1: Selective attention performance before and after exposure
sessions.
figure 1

Changes in selective attention performance pre- and post-exposure (a)
for the two pollution exposure conditions (averaged across both
inhalation conditions); and (b) across all four exposure/inhalation
condition combinations. Selective attention performance deteriorated
following PM pollution exposure, indicated by an increase in DRT
values (a: red line). In contrast, performance improved after clean
air exposure, reflected by a decrease in DRT (a: blue line). This
interaction was statistically significant, as determined by a
repeated measures ANOVA with Bonferroni corrections for multiple
comparisons [F(1, 25) = 6.446, p = 0.018]. Inhalation pathway did not
mediate any changes in selective attention performance (b), as no
significant three-way interaction was identified using a repeated
measures ANOVA with Bonferroni corrections [F(1, 25) = 0.526, p =
0.475]. n = 26 independent human participants (biological
replicates), within a fully repeated measures design. a Data are
presented as mean values +/- SEM; (b) Median represented by the
horizontal line, box indicates interquartile range (25th-75th
percentiles), whiskers show full data range between minimum and
maximum; white circles indicate individual data points; black
diamonds indicate condition means; *p < 0.05. Source data are
provided as a Source Data file.

Full size image

There was no significant three-way interaction identified between
inhalation pathway, pollution exposure, and session time (F  < 1).
See Fig. 1b. No other significant main effects or interactions were
identified: main effect of session time [F(1, 25)  = 1.064, p  =
0.312]; inhalation*pollution interaction [F(1, 25)  = 1.118, p  =
0.300]; other F's  < 1.

This indicates that exposure to air pollution via candle burning
reduced participant selective attention performance comparative to
after exposure to clean air, regardless of inhalation pathway. This
provides evidence that control over selective visual attention, a
critical cognitive function, is impaired in clinically healthy adults
4 h after acute PM air pollution exposure.

Emotion discrimination

Exposure to PM pollution significantly reduced participant emotion
expression discrimination performance comparative to clean air, as
evidenced by a significant two-way interaction between pollution
exposure and session time [F(1, 25)  = 5.552, p  = 0.027, ep^2 =
0.182, 1-b = 0.620]. Whilst emotion expression recognition
performance was reduced in the clean air condition between pre- (Mean
d\({}^{{\prime} }=\) 2.75, s.d.,  = 0.50) and post-exposure (Mean d\
({}^{{\prime} }=\) 2.66, s.d.,  = 0.54), there was a more severe
reduction between pre- (Mean d\({}^{{\prime} }=\) 2.78, s.d.,  =
0.47) and post- (Mean d\({}^{{\prime} }=\) 2.56, s.d.,  = 0.56) PM
pollution exposure. See Fig. 2a. This provides possible evidence that
emotion expression recognition is impaired in clinically healthy
adults 4 h after acute PM air pollution exposure. T-tests revealed no
significant performance differences pre- versus post- clean air
exposure [t(25) = 1.550, p = 0.067], whereas expression recognition
performance significantly declined between pre- and post- PM
pollution exposure [t(25) = 3.271, p = 0.002]. There was no three-way
interaction between inhalation pathway, pollution exposure, and
session time (All F's  < 1). See Fig. 2b. However, there was a main
effect of session time identified [F(1, 25)  = 8.167, p  = 0.008, ep^
2 = 0.246, 1-b = 0.784], such that participants performed better
pre-exposure (Mean d\({}^{{\prime} }=\) 2.77, s.d., = 0.46) compared
to post-exposure (Mean d\({}^{{\prime} }=\) 2.61, s.d.,  = 0.53)
irrespective of emotion, pollution, or inhalation condition.

Fig. 2: Emotion expression discrimination performance before and
after exposure sessions.
figure 2

Changes in expression discrimination performance pre- and
post-exposure (a) for the two pollution exposure conditions (averaged
across both inhalation conditions); and (b) across all four exposure/
inhalation condition combinations. Average expression discrimination
performance, measured as \({{{{\rm{d}}}}}^{{\prime} }\), declined
significantly after exposure compared to before exposure (a). A
repeated measures ANOVA with Bonferroni corrections revealed a
statistically significant main effect of time [F(1, 25)  = 8.167, p  
= 0.008]. Critically a greater decline in expression discrimination
performance was identified following PM pollution exposure (a: red
line) compared to clean air exposure (a: blue line). The interaction
was statistically significant, as determined by a repeated measures
ANOVA with Bonferroni corrections for multiple comparisons [F(1, 25)
 = 5.552, p  = 0.027]. Inhalation pathway did not mediate changes in
expression discrimination performance (b), as no significant
three-way interaction was found using a repeated measures ANOVA with
Bonferroni corrections [F(1, 25)  = 0.868, p  = 0.360]. n  = 26
independent human participants (biological replicates), within a
fully repeated measures design. a Data are presented as mean values +
/- SEM; (b) Median represented by the horizontal line, box indicates
interquartile range (25th-75th percentiles), whiskers show full data
range between minimum and maximum; white circles indicate individual
data points; black diamonds indicate condition means; *p  < 0.05; **p
 < 0.01. Source data are provided as a Source Data file.

Full size image

No three-way or four-way interactions with the inclusion of emotion
expression, to assess approach bias, were identified (All F's  < 1).
Approach bias refers to participants' natural inclination to favour
positive-affective stimuli (happy faces) over negative-affective
stimuli (fearful faces), driven by emotion regulation processes.
Please refer to the methodology section for further explanation. We
attribute the inability to detect changes in approach bias to two
primary reasons. Firstly, the significant higher-order effect of
discrimination ability obscures that of bias; changes in bias cannot
be observed, as discrimination ability was not consistent between
sessions. Secondly, there is an interaction between session time and
emotion expression, without pollution exposure mediation [F(1, 25)  =
5.817, p  = 0.024, ep^2 = 0.189, 1-b = 0.640]. Bias towards fearful
stimuli was largely similar between pre- (Mean d\({}^{{\prime} }=\)
2.576, s.d.,  = 0.54) and post-exposure (Mean d\({}^{{\prime} }=\)
2.517, s.d.,  = 0.55), whereas bias towards positive-affective
stimuli decreased between pre- (Mean d\({}^{{\prime} }=\) 2.957,
s.d.,  = 0.43) and post-exposure (Mean d\({}^{{\prime} }=\) 2.710,
s.d.,  = 0.55). This implies a possible role of fatigue in approach
bias changes, also decreasing the possibility of observing a
pollution-mediated effect.

A main effect of emotion expression was also identified [F(1, 25)  =
35.018, p  < 0.001, ep^2 = 0.583, 1-b = 1], such that participants
showed generalised bias towards positive-affective (happy) faces
(Mean d\({}^{{\prime} }=\) 2.83, s.d.,  = 0.46) compared to
negative-affective (fearful) faces (Mean d\({}^{{\prime} }=\) 2.55,
s.d.,  = 0.52) regardless of session, exposure, or inhalation
condition. See Table 1 for details of ANOVA main effects and
interactions of interest.

Table 1 Summary of Expression Recognition Task ANOVA results for the 
\({{{{\rm{d}}}}}^{{\prime} }\) performance measure
Full size table

Response time (RT) for correct 'Hit' trials was also analysed to
identify if the significant pollution-mediated variations in emotion
expression discrimination stemmed from strategic processes, such as
trade-offs between speed and accuracy. Results of the ANOVA
identified a significant main effect of emotion expression [F(1, 25)
 = 16.606, p  < 0.001, ep^2 = 0.399, 1-b = 0.975], whereby
participants responded faster to positive-affective (Mean RT  = 535
ms, s.d.,  = 56) comparative to negative-affective (Mean RT  = 544
ms, s.d.,  = 55) stimuli. There was also a significant main effect of
session time identified [F(1, 25)  = 4.636, p  = 0.041, ep^2 = 0.156,
1-b = 0.544], such that participants responded faster post-exposure
(Mean RT  = 536 ms, s.d.,  = 59) compared to pre-exposure (Mean RT  =
543 ms, s.d.,  = 52). Faster response times between sessions may
explain the global decline in performance (indexed by \({{{{\rm
{d}}}}}^{{\prime} }\)) between sessions.

Critically, no other main effects or interactions were identified,
leading us to confirm that pollution-mediated changes to expression
discrimination performance were not a result of compensatory
speed-accuracy mechanisms.

Psychomotor speed and sustained attention

PM pollution exposure did not significantly impact simple response
time or sustained attention measures, as assessed by the Psychomotor
Vigilance Task. This expected outcome allows for a confident
conclusion that the previously described declines in selective
attention and emotion expression recognition are not due to a global
decline in cognitive speed, but rather are attributable to the
complex cognitive functions outlined.

The stability of both psychomotor speed, reflecting global processing
speed, and sustained attention, indicative of continued concentration
over relatively long periods, is outlined below.

Psychomotor Speed: There was no significant effect of inhalation
pathway [F(1, 25)  = 1.691, p  = 0.205], pollution exposure [F(1, 25)
 = 1.070, p  = 0.311], session time (F  < 1), or subsequent
interactions (F's  < 1) on psychomotor speed. See Table 2.

Table 2 Mean response time (RT) in milliseconds and standard
deviation (italicised in brackets) for psychomotor speed & sustained
attention trials between pre- and post-exposure assessments across
all conditions
Full size table

Sustained Attention: There was no significant effect of inhalation
pathway (F  < 1), pollution exposure (F  < 1), session time [F(1, 25)
 = 1.199, p  = 0.284], or subsequent interactions on sustained
attention: inhalation*pollution [F(1, 25)  = 4.121, p  = 0.053];
pollution*session [F(1, 25)  = 3.437, p  = 0.076];
inhalation*pollution*session [F(1, 25)  = 2.046, p  = 0.165];
inhalation*session (F  < 1). See Table 2.

Working memory

PM pollution exposure did not significantly impact working memory
performance as measured with the Spatial n-back Task. An individual
ANOVA was conducted for each level of difficulty (n-value).

1-back: A significant interaction between inhalation pathway and
session time was identified [F(1, 25)  = 4.766, p  = 0.039, ep^2 =
0.160, 1-b = 0.555], such that regardless of pollution exposure, in
the normal inhalation condition, participant performance improved
between pre- (Mean d\({}^{{\prime} }=\) 3.899, s.d.,  = 0.66) and
post-exposure (Mean d\({}^{{\prime} }=\) 3.997, s.d.,  = 0.60),
whereas in the restricted inhalation condition performance
deteriorated between pre- (Mean d\({}^{{\prime} }=\) 4.023, s.d.,  =
0.65) and post-exposure (Mean d\({}^{{\prime} }=\) 3.810, s.d.,  =
0.60). T-tests revealed no significant performance differences pre-
versus post-exposure in either the normal inhalation [t(25) = 0.955,
p = 0.174] or restricted inhalation conditions [t(25) = 1.529, p =
0.069]. Therefore, while a significant interaction effect was
identified, neither inhalation pathway significantly influenced
performance between pre- and post-exposure.

No other significant main effects or interactions were identified:
session time [F(1, 25)  = 2.996, p  = 0.096]; all other main effects
and interactions (F's  < 1). See Table 3 for condition means.

Table 3 Mean working memory score (\({{{{\rm{d}}}}}^{{\prime} }\))
and standard deviation (italicised in brackets) for the four n-back
difficulty values between pre- and post-exposure assessments across
all conditions
Full size table

2-back: No significant main effects or interactions were identified:
session time [F(1, 25)  = 2.996, p  = 0.096]; all other main effects
and interactions (F's  < 1). See Table 3 for condition means.

3-back: No significant main effects or interactions were identified:
inhalation pathway [F(1, 25)  = 1.772, p  = 0.195];
inhalation*pollution [F(1, 25)  = 1.247, p  = 0.275]; all other main
effects and interactions (F's  < 1). See Table 3 for condition means.

4-back: No significant main effects or interactions were identified:
pollution*session [F(1, 25)  = 3.956, p  = 0.058]; inhalation*session
[F(1, 25)  = 1.606, p  = 0.217]; all other main effects and
interactions (F's  < 1). See Table 3 for condition means. Results of
the 4-back were nearing random chance, indicating a lack of
meaningful pattern or reliability in the results. Given this
observation, it would be advisable to avoid utilising this test in
future assessments, as its validity is questionable based on the
proximity to chance-level outcomes.

Air quality

PM concentrations during the exposure period (1 h) were significantly
higher in the PM pollution condition (PM[2.5] mean = 28.54 mg m^-3,
s.d., = 6.85; PM[10] mean = 37.85 mg m^-3, s.d., = 7.32), compared to
the clean air condition, where no candle was burned (PM[2.5] mean =
3.99 mg m^-3, s.d., = 1.20; PM[10] mean  = 9.00 mg m^-3, s.d., =
2.81). PM[2.5] [F(1, 25) = 326.012, p  < 0.001] and PM[10] [F(1, 25)
= 418.035, p < 0.001]. No significant main effects of inhalation
pathway condition or interaction were identified (F's  < 1). See
Fig. 3a, b. This indicated that burning and extinguishing candles
prior to participant exposure led to significantly higher PM
pollution during the hour exposure compared to no manipulation of air
quality (clean air condition).

Fig. 3: PM[2.5], PM[10], and CO[2] concentrations during the exposure
sessions.
figure 3

Average air pollutant concentrations across each exposure session for
(a) PM[2.5]; (b) PM[10]; and (c) CO[2]. Significantly higher
concentrations of all pollutants were identified during particulate
matter (PM) pollution exposure conditions compared to clean air, as
determined by repeated measures ANOVAs with Bonferroni corrections:
PM[2.5] [F(1, 25)  = 326.012, p  < 0.001]; PM[10] [F(1, 25)  =
418.035, p  < 0.001]; and CO[2] [F(1, 25)  = 292.685, p  < 0.001]. CO
[2] concentrations were significantly higher in the normal inhalation
condition compared to the restricted inhalation condition, as
evidenced by a significant two-way interaction using repeated
measures ANOVA with Bonferroni corrections [F(1, 25)  = 6.819, p  =
0.015]. n  = 26 independent human participants (biological
replicates), within a fully repeated measures design. Median
represented by the horizontal line, box indicates interquartile range
(25th-75th percentiles), whiskers show full data range between
minimum and maximum; white circles indicate individual data points;
black diamonds indicate condition means; **p  < 0.01; ***p  < 0.001.
Source data are provided as a Source Data file.

Full size image

For Carbon Monoxide (CO), 99.87% of the recorded samples showed no
detectable carbon monoxide [0 parts per million (ppm)]. The highest
observed values were 3.5 ppm in the clean air condition and 3 ppm in
the PM pollution condition.

Results of the ANOVA investigating CO[2] concentrations indicated
that there was a significant main effect of pollution condition [F(1,
25)  = 292.685, p  < 0.001], such that CO[2] concentrations during
exposure were significantly higher in the PM pollution condition
(mean  = 712 ppm, s.d.,  = 48) compared to clean air condition (mean
 = 598 ppm, s.d.,  = 42). A significant main effect of inhalation
pathway was also identified [F(1, 25)  = 6.819, p  = 0.015, ep^2 =
0.214, 1-b = 0.709], such that CO[2] concentrations were
significantly higher under normal inhalation (mean  = 670 ppm, s.d.,
 = 49) compared to restricted inhalation conditions (mean  = 640 ppm,
s.d.,  = 51). No significant interaction was present (F  < 1). See
Fig. 3c. The observed higher CO[2] concentrations during normal
inhalation, as opposed to restricted inhalation, may be attributed to
inevitable differences in respiratory processes of participants
during the two conditions. It is suggested that when blocking the
nasal pathway, less CO[2] is retained in the body and subsequently
exhaled, compared to unrestricted breathing through the nose and
mouth^52. This difference in respiratory behaviour could explain the
observed significant differences between CO[2] concentrations between
the two inhalation conditions.

Exposure awareness

At the end of each session, participants reported the pollution
condition (clean air or candle) they believed they had experienced. A
kh^2 analysis showed no significant association between the actual
pollution exposure condition experienced and participant-reported
exposure [kh^2(1, N  = 104)  = 1.943, p  = 0.163]. This suggests that
the study blinding was successful and the awareness of air condition
would not significantly contribute to explaining the identified
cognitive changes, thereby enhancing the validity of the study. See
Table 4 for frequencies and confidence judgement values.

Table 4 Exposure awareness of participants
Full size table

Discussion

In this study, participants were exposed to either high
concentrations of particulate matter (PM) air pollution, using candle
burning as the PM source, or clean air during conditions of either
normal or nasally restricted inhalation. Before, and 4 h after
exposure, participants completed four computer tasks to assess
working memory, selective attention, emotion expression
discrimination, psychomotor speed, and sustained attention. Exposure
to PM air pollution led to a decline in selective attention
performance and emotion expression discrimination ability, subsets of
executive functioning. Working memory performance and psychomotor
vigilance were unaffected by PM exposure. Inhalation method did not
mediate any identified results.

These findings support prior research on the impact of PM pollution
exposure on executive processing. The deficits in selective attention
closely corroborate previous evidence showing a reduction in
selective attention performance following short-term PM exposure^12,
13,14. Additionally, research on longer-term exposure reveals similar
impacts on executive function performance^53,54. The identified
deficits in expression discrimination mediated by PM corroborate
evidence from a vaccination study, which demonstrated a decline in
emotion recognition 6.5 h after typhoid vaccination, accompanied by
upregulation of inflammatory biomarkers^42. This suggests that PM
pollution-induced inflammation may lead to socio-cognitive
impairments. A critical component of emotion expression recognition
is the engagement of 'theory of mind'^55, a social-cognitive skill
wherein individuals interpret their own and others' mental states to
predict and explain behaviour^56. Previous studies have identified
connections between air pollution and interpersonal attraction^57, a
notion partially substantiated by research linking recent ambient
concentrations of PM to the incidence of violent crime in US cities^
58. These findings may validate the concept that PM exposure leads to
socio-emotional dysfunction, aligning with previous research that
links inflammation and air pollution to deficits in emotional
recognition and a rise in antisocial behaviour.

Interestingly, functional similarities exist between selective
attention and expression discrimination processes^59, and a link is
present between the neural mechanisms of reactive and proactive
cognitive control and social anxiety^60, potentially further
supporting the connection between these neural constructs. Moreover,
there is growing evidence highlighting the impact of systemic
inflammation on the attenuation or functional alterations of
prefrontal cortical neurons^61, which strengthens the link between
acute inflammatory processes and executive cognitive dysfunction.
These studies may suggest that PM pollution exposure leads to
executive and socio-cognitive dysfunction due to the impact of air
pollution-mediated inflammation on brain regions that share
functional similarities between selective attention and emotion
recognition processes.

In light of the significant effects of particulate matter exposure on
selective attention and emotion expression discrimination, it may
appear unexpected that there was no identified impact of PM pollution
on working memory performance. Notably, existing research^12,13
indicates the resilience of working memory against short-term
pollution exposure episodes, despite the susceptibility to
pollution-induced effects of other facets of cognition. Nevertheless,
there is documented evidence of chronic exposure to high particulate
concentrations negatively affecting both working memory^62,63,64,65,
66 and episodic memory^67. Moreover, there is evidence suggesting
that working memory can be affected following inflammation induced by
vaccination^43,46. This growing body of evidence suggests a potential
divergence in the impact of PM pollution on executive, higher order
cognitive processing, and working memory. Further insights into these
differences could be investigated through non-invasive brain imaging
studies. One interesting outcome of this study was an interaction
between session time (pre- versus post-exposure) and inhalation
pathway (normal versus restricted inhalation) on immediate recall of
spatial locations (1-back of the Spatial n-back task). Although
further analysis revealed no significant changes from inhalation
method between pre- and post-exposure, the potential impact of
disrupting breathing patterns with a nose clip (albeit not during
cognitive tasks) merits additional investigation. This effect was
unique to this specific circumstance as it was not observed in any
other tasks or in more challenging n-back blocks.

It is not believed that the effects observed in this study can be
attributed to differences in CO[2] concentration. Recent research
examining the impact of CO[2] exposure in office environments found
no significant effect on cognitive functioning with concentrations up
to 2100 ppm^68; the maximum average hourly CO[2] concentration in
this study was reported as 845 ppm. Additionally, while some studies
indicate cognitive changes at concentrations as low as 1000 ppm^69,
it is noteworthy that these effects are typically observed only while
exposure is ongoing and when it lasts longer than 1 h^70, with an
expectation of rapid recovery immediately following exposure. Given
the 4-h delay between exposure end and post-exposure testing in our
study, we find it unlikely that CO[2] exposure serves as a causal
factor for the identified changes in cognitive function.

Blocking the orthonasal pathway (the nose) to the olfactory bulb did
not significantly mediate changes in cognitive function related to
air pollution. This suggests that the identified effects may be
mediated through the respiratory system, either directly or
indirectly. However, it is challenging to draw definitive conclusions
without further investigation. Although it is not feasible to
entirely block the entry of odourants to the olfactory epithelium via
the retronasal route (the pathway from the mouth to the nose), the
mechanisms of odour perception differ considerably between nasal and
oral breathing^71. Research indicates that oral-only breathing does
not activate the neural pathways associated with olfactory processing
to the same extent as nasal breathing, which can hinder the ability
to learn olfactory cues^72. Thus, while some odour perception may
still occur through alternative routes, obstructing the nasal pathway
significantly reduces the intensity of olfactory stimulation and,
consequently, the entry of pollutants.

A condition isolating the olfactory pathway (nasal-only breathing)
would provide further clarity on this unanswered query, although it
would be experimentally very difficult to block particle entry into
the lungs. Whilst not significant, there was a trend identified in
the Face Identification Task suggesting a more pronounced effect of
particulate matter air pollution on selective attention performance
in the normal inhalation condition, where both the respiratory and
olfactory pathway were unrestricted. This could suggest an important
role of the olfactory pathway in selective attention ability, but not
other cognitive functions such as emotion expression recognition.
Although, it may also be reasonable to assume that any worsening of
effects could simply be due to a higher pollution dosage, possibly
evidenced by the significantly elevated average CO[2] concentrations
during exposures when inhalation was not restricted. Similarly, it is
conceivable that, assuming a similar composition, particles of
different sizes may be key to understanding a possible differing role
of the olfactory or respiratory pathways. The nasal mucosa, being
highly vascularised, facilitates swift absorption of chemicals and
drugs^73; therefore both soluble and insoluble particles could
potentially reach the brain through this route. Indeed, evidence
suggests that ultrafine particles demonstrate increased effectiveness
in traversing the alveolar/capillary barrier^74. There is a clear
necessity for further research to confirm the potential role of the
olfactory pathway in selective attention ability and to better
understand the effects of PM air pollution on cognitive function.

In conclusion, this study showed a reduction in higher-order
cognitive processing 4 h after exposure to high concentrations of PM
[2.5] in healthy individuals, while spatial working memory function
is robust against short-term exposure episodes. Blocking of the
olfactory pathway did not significantly mediate particulate
pollution-related cognitive function changes, however further
research is strongly encouraged to investigate pathway-related
differences, allowing for a more nuanced understanding of the
distinctive factors and mechanisms that contribute to the identified
trends within this study. Identifying cognitive effects within a
healthy population suggests that the impact of air pollution exposure
on brain function may be more significant in more vulnerable groups.
Future research could focus on populations at higher risk of
cognitive problems, such as older adults.

Methods

This project received ethical approval from the University of
Birmingham Science, Technology, Engineering and Mathematics (STEM)
ethics committee, number ERN_21-1188. Written informed consent was
obtained from each participant, and we confirm that the research
complied with all relevant ethical regulations.

Briefly, the methodology of the study was a single-blind
within-participants design. Participants took part in four cognitive
tasks (total time 60 min) prior to, and 4 h following, a 1-h exposure
session. Air quality was manipulated using candle burning as
previously described in Shehab and Pope (2019)^18. This has been
shown to be a low-cost, controlled method to increase PM[2.5]
concentrations to levels that might be experienced in an urban area^
75. PM[2.5], PM[10], Carbon Dioxide (CO[2]), and Carbon Monoxide (CO)
were monitored throughout exposure to all air quality conditions.
Inhalation pathway was manipulated by using a swimming nose clip,
blocking the olfactory pathway, thereby decreasing the concentration
of particulate pollution entering the body via this route.
Participants took part in both PM pollution and clean air conditions
whilst wearing the nose clip (allowing for 'restricted' oral-only
inhalation) or without nose clip ('normal' inhalation through both
nose and mouth).

Participants

Thirty-nine staff and students at the University of Birmingham,
Birmingham, UK were recruited through on-campus advertisements and
offered cash on completion of each study visit. Individuals who
reported current neurological, psychiatric, inflammatory, or
respiratory disorders (e.g., multiple sclerosis, depression,
rheumatoid arthritis, asthma), or current smoking (including
e-cigarettes) were excluded. See Supplementary Methods for full study
exclusion criteria. A full dataset was collected from 30
participants. All data was removed from four participants due to
scores on the Depression, Anxiety, and Stress Scale (DASS) indicative
of undisclosed or diagnosed mental health conditions; a pattern of
random responses during cognitive tasks, suggesting potential
interference or disruption (referred to as Sabotage); and
self-reported non-compliance or adherence to study instructions.

The resultant data set for analysis contained 26 participants. Mean
age  = 27.7 years, s.d.,  = 10.6, range 19-67; 57.7% female (reported
gender and biological sex).

Power analyses were conducted based on unpublished data from previous
experiments, using conservative estimates to ensure adequate
sensitivity. For the Expression Recognition Task, using effect size
and variance from prior data on approach bias before and after
exposure to low-quality air (via candle burning) or ambient air (D
Approach bias = 0.27, s.d., = 0.45), a sample size of 30 participants
was conservatively estimated to provide 90% power to detect a
significant change in socio-emotional processing at p  < 0.05.
Similarly, for the Face Identification Task, based on previous data
on cognitive load and attention after diesel exhaust exposure (DRT  =
22 ms, s.d.,  = 25 ms), 30 participants were estimated to provide 90%
power to detect a 15 ms change in response time (p < 0.05). Although
the final sample size was 26 participants, the conservative nature of
the power analyses ensures that the study retains sufficient
sensitivity despite the slightly smaller sample.

Design

This single-blind study used a repeated measures experimental design
across 4 days. The within-subject factors were inhalation pathway,
(normal inhalation, restricted inhalation); pollution exposure,
(clean air, PM pollution); and session time (pre-exposure,
post-exposure). The order of inhalation and exposure conditions were
counterbalanced across the four sessions. Condition orders were
randomly assigned to participant ID numbers (1-32) before data
collection began; note that inhalation pathway condition was always
the same for two subsequent exposures. Participants were subsequently
assigned unique ID numbers sequentially based on successful
recruitment. To address unequal distribution of conditions following
participant attrition, a new participant ID was generated for the
same condition. This aimed to control for potential psychological
biases such as learning and fatigue effects in the experimental
design. See Supplementary Table 1 for the condition order details of
the 26 participants included in the data analysis.

Materials

A Windows 10 computer running Matrix Laboratory (MATLAB) version
R2022a (9.4; MATLAB, 2022)^76 was used to run the cognitive tasks.
All tasks were in the format of a MATLAB script utilising the
Psychophysics Toolbox version 3.0.14^77. Task scripts and
instructions are available on GitHub. We opted not to use assessments
of general cognition, such as the Mini-Mental State Examination
(MMSE), Montreal Cognitive Assessment (MoCA), and Wechsler Adult
Intelligence Scale (WAIS) as these were primarily derived to index
severe damage or failure of cognition, as occurs in stroke or brain
damage. As such they are insensitive to more subtle but nonetheless
important cognitive degradation. TSI Optical Particle Sizer (OPS)
3330 was used to measure concentrations of PM[2.5] and PM[10]
throughout participant exposure. LI-COR LI-820 CO[2] Gas Analyzer was
used to measure concentrations of Carbon Dioxide. LASCAR EL-USB-CO
Data Logger was used to measure concentrations of Carbon Monoxide. To
provide PM (particulate matter) pollution, 100% stearin candles made
from animal fat were burned. These unscented candles, measuring 190
mm in height and 22 mm in radius, were purchased from a major
hypermarket. A swimming nose clip was used to reduce pollution
concentration entering the olfactory pathway in the restricted
inhalation condition.

Air quality monitoring

TSI OPS 3330: This instrument uses single particle counting
technology to measure particles from 0.3 to 10 micrometres (mm)
across 16 size channels. These channels were set to the default
values of sample weighting factors defined by European Standard EN481
for PM[2.5] and PM[10]. The instrument was set to record particle
concentration and size distribution in 10 second intervals. The
authors note there was no means of measuring the relative number of
ultrafine particles. We use PM[2.5] mass concentration as our metric
of PM pollution, following standard public health protocols.

LI-COR LI-820 CO[2] Gas Analyzer: This sensor is a non-dispersive
infrared gas analyser measuring CO[2] concentrations. The instrument
was set to record in 1 second intervals, with resultant values
measured as particles per million (ppm).

LASCAR EL-USB-CO Data Logger: This standalone instrument was set to
record in 10 second intervals, with CO values measured as particles
per million (ppm).

Subjective measures

The Depression, Anxiety, and Stress Scale (DASS)^78 was used to
identify recent participant depression, anxiety, and stress.
Participants rated to what extent 42 statements applied to them over
the past week on a scale of 0 to 4 (Did not apply at all--Applied to
me very much, or most of the time). Higher scores indicate higher
levels of psychological distress, with a maximum of 42 available for
each metric (depression, anxiety, and stress).

Participants responded to a question about their awareness of the
pollution exposure condition: "This morning, you spent 60 min in a
room. Before entering, the room either had a burning candle or not.
Please indicate which air condition you believe that you experienced
today" responding to one of two options: Candle or No candle.
Participants were also asked of their confidence in their answer:
"How confident are you in your answer?" responding to one of the
following five options: Not confident at all (0); Slightly confident
(1); Somewhat confident (2); Fairly confident (3); or Completely
confident (4).

Cognitive tasks

These tasks, originally developed for this study, have subsequently
been detailed in a published protocol for a different experiment,
HIPTox^79.

Spatial n-back task

The n-back task is a continuous performance assessment employed to
evaluate working memory capacity^80. In this widely used cognitive
task, participants are presented with sequences of stimuli, in this
case, spatial locations, and must determine whether the currently
displayed stimulus matches the one presented presented 'n' trials
earlier. As 'n' increases, the volume of information retained in
working memory also grows. It is broadly recognised that working
memory has a limited capacity, with Miller (1956)^81 proposing that
the number of items that can be held is ~7 +- 2. Consequently, as 'n'
increases, both the task's difficulty and the proportion of errors
tend to rise. Poor performance on the task suggests deficits in
encoding, maintaining, and/or retrieving information.

The stimuli comprised a centrally positioned 3 x 3 grid with white
grid lines (red-green-blue coordinate, RGB [255, 255, 255]) displayed
on a grey background (RGB [128, 128, 128]). The grid measured 16.5 cm
in both height and width, subtending a visual angle of ~15.78^[?] in
both dimensions when viewed from a distance of 60 cm. The grid was
situated centrally on the screen to ensure focused stimulus
presentation.

During each trial, a blank 3 x 3 grid was displayed for 600 ms,
followed by a single white square appearing in one of the nine
possible grid locations for 1000 ms. Subsequently, the blank grid was
shown once more. Participants were required to remember the sequence
of grid positions and indicate for each trial whether the square
occupied the same location as it had 'n' trials earlier, or different
location. This was a two-alternative forced choice task, where
participants used the 'm' and 'z' keyboard keys to respond 'same' and
'different' respectively; these keys were reversed for left-handed
participants. Responses were expected within 10 seconds of the
prompt. See Figure 4a for an illustration of the sequence of displays
in each trial. The task consisted of four blocks of 45 trials, each
containing eight matches (i.e., 'same' locations). The value of 'n'
increased with each block: block 1, n = 1; block 4, n = 4.

Fig. 4: Illustration of the four cognitive tasks.
figure 4

a Spatial n-back Task; (b) Face Identification Task, which used face
images sourced from Set A of the Karolinska Directed Emotional Faces
dataset^86 (placeholder images are displayed in the figure rather
than the actual stimuli); (c) Expression Recognition Task, which used
face images sourced from the RADIATE database^91,92 (placeholder
images are displayed in the figure rather than the actual stimuli); (
d) Psychomotor Vigilance Task--Psychomotor speed trials; and (e)
Psychomotor Vigilance Task--sustained attention trials. The screens
shown are for illustrative purposes only; refer to the text for the
actual stimuli sizes and on-screen locations.

Full size image

Face identification task

This task evaluates executive function by assessing selective
attention, akin to established cognitive assessments such as the
Stroop^82 and Flanker^83 tasks. Participants must disregard
distractions and focus on the primary task objective.

Given the limited capacity of high-level cognitive systems, the brain
employs two complementary mechanisms for attentional control.
Proactive control is used to plan strategically and engage
selectively with anticipated relevant information while avoiding
foreseeable distractions. Simultaneously, reactive control is
activated to adjust behaviour in response to unexpected events. For
example, preparing coffee involves proactive control to locate and
approach the kettle while ignoring the biscuit tin (particularly if
on a diet). Conversely, reactive control is required to avoid a
colleague who unexpectedly steps into your path. These mechanisms
compete for attentional resources; successful task execution depends
on sustained proactive control^84,85, while distraction caused by
unforeseen, irrelevant events reflect reactive control.

The stimuli included a white (RGB [255, 255, 255]) spatial cue arrow
pointing left or right and a centrally presented white fixation
cross, all displayed on a black background (RGB [0, 0, 0]). Faces
were sourced from the A set of the Karolinska Directed Emotional
Faces^86, encompassing all available emotional expressions: fearful,
angry, disgusted, happy, neutral, and surprised. Scrambled images
were generated by dividing face images into 13,984 squares and
randomising their positions. Each image subtended 8.6^[?] x 11.0^[?],
with two images displayed simultaneously, each laterally offset by
approximately  +- 8.1^[?] of visual angle for symmetrical presentation.

Participants were instructed to respond as quickly as possible to
identify the gender presentation of the target face using either the
'A' and 'Z' keyboard keys (for left-handed participants) or the 'L'
and 'P' keys (for right-handed participants), using the index and
middle fingers of their dominant hand. Key assignment to 'male' and
'female' was counterbalanced across participants. The task consisted
of four blocks of 60 trials each, totalling 240 trials.

Each trial began with a fixation cross presented for 500 milliseconds
(ms), followed by a spatial cue for 400 ms that reliably indicated
the location of the upcoming target. This was followed by another
fixation cross (350-850 ms, determined by a random integer between 20
and 50 sampled at a 17 Hz frame rate). The face array then appeared
for 75 ms, followed by a final fixation cross presented for 1500 ms
or until participants responded. The face array comprised a central
fixation cross, a distractor image (either scrambled or a face), and
a target image (face). Gender and emotional expression congruency
were balanced across trials, ensuring all stimulus combinations were
equally likely. Participants were instructed to identify the gender
presentation of the target face as quickly and accurately as possible
following the short (75 ms) presentation of the face array. See Fig. 
4b for the sequence of displays in each trial.

In this task, participants were required to identify the gender
presentation of a target face while either another face (in two-face
trials) or a non-face (in one-face trials) distractor was present.
The presence of a face distractor typically increases response time^
87, reflecting reactive selective attention capture. Studies on
cognitive control consistently show that response slowing caused by
distractors is more pronounced when the preceding trial lacked a
compelling distractor (one-face trials) compared to trials with
distractors (two-face trials)^88. This phenomenon is attributed to
prior distractor suppression (in trial n-1), which enhances proactive
processing of the target in the current trial n. In contrast, the
absence of prior distractor suppression weakens proactive control,
increasing vulnerability to distractor capture^89. Differences in
response times (RTs) between two-face trials following two-face
trials (repeat sequences) and those following one-face trials (change
sequences) inversely reflect proactive control (DRT). Thus, greater
response times in change sequences compared to repeat sequences
indicate reduced proactive control.

Expression recognition task

This Go/No-go task utilised happy and fearful facial expressions as
target stimuli to assess decision-making performance between
positive-affective and negative-affective expressions. The task
examined both approach bias and the ability to discriminate between
emotional expressions.

Approach bias

This aspect of the task explores the tendency to engage with
positive-affective stimuli (e.g., happy faces) more readily than with
negative-affective stimuli (e.g., fearful faces). This preference is
thought to reflect underlying emotion regulation processes^90. A
natural inclination to approach positive stimuli and avoid negative
stimuli is expected to produce a bias in accuracy, with better
performance for happy targets and poorer performance for fearful
targets.

Expression discrimination

This aspect constitutes the perceptual component of the task.
Participant accuracy, regardless of the target expression, indicates
the ability to distinguish among different emotion expressions. A
higher overall accuracy demonstrates an improved capacity to promptly
perceive and categorise happy and fearful facial expressions, which
is a pivotal concept in theory of mind^56, a critical
social-cognitive skill.

The expressive faces used in this task were sourced from the RADIATE
database^91,92. Each face image was displayed centrally against a
white background (RGB [255, 255, 255]), with explanatory text and
fixation crosses presented in black (RGB [0, 0, 0]). Stimuli
consisted of a centrally positioned face image measuring 8 cm in both
height and width, subtending a visual angle of ~7.68^[?] in both
dimensions when viewed from a distance of 60 cm.

Participants were instructed to respond to faces displaying the
target expression (happy or fearful) and to withhold responses to
non-target expressions. Participant responses were made as quickly as
possible by pressing the keyboard spacebar with their dominant hand.
The target expression alternated between blocks, beginning with
'happy'. Each trial began with a fixation cross presented for 550-950
ms, followed by an expressive face image displayed for 100 ms, and
then a blank screen lasting 700 ms or until a response was made. See
Fig. 4c for the sequence of displays in each trial. The task
consisted of six blocks of 44 trials each, with 28 target (Go) images
and 16 non-target (No-go) images per block. All face stimuli featured
either open mouths (more expressive) or closed mouths (less
expressive), with these conditions evenly distributed between Go and
No-go trials within each block.

Psychomotor vigilance task

This basic response time task assessed simple reaction time,
providing a measure of global processing (psychomotor speed) and the
ability to maintain concentration over extended periods (sustained
attention)^93.

The target stimulus was a centrally presented red circle with a
diameter of 0.5 cm (RGB [255, 60, 0]), displayed against a black
background (RGB [0, 0, 0]). The circle subtended a visual angle of
~0.48^[?] when viewed from a distance of 60 cm. Explanatory text and
fixation crosses were shown in white (RGB [255, 255, 255]).

Participants were instructed to focus on a centrally positioned
fixation cross and respond as quickly as possible when the target, a
small red circle, appeared. Each trial began with a fixation cross
displayed for 400-800 ms in psychomotor speed trials, or for 25-35 s
in sustained attention trials. This was followed by the appearance of
the red circle target for 400 ms or until the participant responded.
If the keyboard spacebar was pressed during the target presentation,
a white circle was shown for 400 ms as feedback. See Fig. 4d and e
for a visual representation of both trial sequence types. The task
consisted of one block of 85 trials, including 10 sustained attention
trials with long fixation intervals and 75 psychomotor speed trials
with shorter fixation intervals.

Procedure

Upon arrival, participant suitability was checked against exclusion
criteria and after informed consent participants completed the four
cognitive tasks in the cognitive testing room: Spatial n-back Task;
Face Identification Task; Expression Recognition Task; and
Psychomotor Vigilance Task. Twenty minutes prior to participants
completing the tasks, two candles were lit (PM pollution condition
only) in an adjacent 'exposure' room (4.15  x 2.95  x 3.40 m  = 41.6
m^3) and windows closed (all conditions). One minute prior to task
completion, the candles were extinguished and the air quality sensors
were activated to record Particulate Matter (PM), Carbon Dioxide (CO
[2]), and Carbon Monoxide (CO) concentrations. Participants, wearing
a nose clip in the restricted inhalation condition, were taken into
the exposure room and seated close to the air quality sensors. A fan
circulated air in the room. Participants remained in the exposure
room for 60 min, during which they completed the DASS questionnaire.
After 60 min of exposure to either elevated PM concentrations (PM
pollution condition) or room air (clean air condition), participants
left the lab.

Four hours later, participants returned to the cognitive testing
room. The cognitive tasks were repeated in the same order as
previously described. Participants were then asked to indicate
whether they believed they were exposed to the clean air or PM
pollution condition earlier that day, and they received monetary
compensation for their time. This procedure was repeated, after a
minimum two-week washout period, until all four conditions were
completed. See Fig. 5.

Fig. 5: Experimental procedure.
figure 5

As described in text, candles were burned 20 min prior to the
exposure (2) in the PM pollution condition.

Full size image

Data processing

Spatial n-back task

Each trial has four possible outcomes^94: a hit (correctly
identifying a 'same' location), a correct rejection (correctly
identifying a 'different' location), a miss (failing to identify a
'same' location), or a false alarm (incorrectly responding 'same' to
a 'different' location).

Working memory ability was quantified using \({{{{\rm{d}}}}}^{{\
prime} }\), which represents the standardised difference between the
signal-present (same location) and signal-absent (different location)
distributions. It was calculated as the Z-score of the hit rate [#
Hits / (#Hits + #Misses)] minus false alarm rate [#False Alarms / (#
False Alarms + #Correct Rejections)]. This calculation was performed
separately for each n-back value, with lower \({{{{\rm{d}}}}}^{{\
prime} }\) scores indicating poorer working memory performance. As 'n
' increases, performance is expected to decline, consistent with the
increased working memory load. Response time (RT) was not considered
in this task, as participants were not instructed to respond quickly
and were given a relatively long response window of 10 seconds.

Face identification task

The primary metric of interest in this task is cognitive control,
measured using DRT (the difference in response time between repeat
sequences and change sequences). Accuracy is not considered in the
analyses, as it was only necessary to establish a task goal for
participants, but is not relevant for calculating cognitive control.

Trials were excluded from statistical analyses if there was no
response on the current or previous trial, or if the response on the
current trial (n) was too fast (RT < 200 ms). Additionally,
individual RTs were trimmed if they deviated by more than +- 2
standard deviations from the mean RT for repeat and change sequences,
respectively.

Expression recognition task

As with the Spatial n-back Task, there are four possible outcomes for
each trial^94: a hit (correct 'Go' response to the target
expression), a correct rejection (correct 'No-go' response to the
non-target expression), a miss (incorrect 'No-go' response to the
target expression), and a false alarm (incorrect 'Go' response to the
non-target expression).

Trials were excluded if response times (RT) were below 200 ms,
indicating an anticipation error. The metric \({{{{\rm{d}}}}}^{{\
prime} }\), which measures expression sensitivity, was calculated as
the Z-score of the hit rate [#Hits / (#Hits + #Misses)] minus false
alarm rate [#False Alarms / (#False Alarms + #Correct Rejections)].
This was computed separately for each emotion expression type. A
lower \({{{{\rm{d}}}}}^{{\prime} }\) score indicates reduced
sensitivity to the stimulus signal, reflecting greater difficulty in
distinguishing between expressions.

Psychomotor vigilance task

The primary metric of interest in this task was Response Time (RT),
irrespective of whether participants respond within the 400 ms window
required for 'correct' response feedback. RT is defined as the time
elapsed between perceiving the target visual stimulus and pressing
the response button.

Sustained attention was measured by RT following long fixation pauses
(ten trials), with a shorter RT indicating better sustained
attention. Psychomotor speed was assessed by RT following short
fixation pauses (75 trials), with a shorter RT reflecting faster
psychomotor speed.

It is expected that average RTs will not differ significantly between
the pre-exposure and post-exposure test sessions. This would suggest
that exposure to low-quality air does not affect sustained attention
or basic psychomotor functioning. If significant RT differences are
observed, they may reflect fatigue rather than more complex
mechanisms linking air pollution exposure to diminished higher-order
cognitive functioning.

Data analysis

Cognitive Tasks: Approach bias (Expression Recognition Task) was
analysed using a four-way (2 x 2 x 2 x 2) repeated measures analysis
of variance (ANOVA), with inhalation pathway (normal, restricted);
pollution exposure (clean air, PM pollution); session time
(pre-exposure, post-exposure); and emotion expression (happy,
fearful) as the factors. All other cognitive metrics of interest were
analysed using a three-way (2 x 2 x 2) repeated measures ANOVA, with
inhalation pathway; pollution exposure; and session time as the
factors. Bonferroni corrections for multiple comparisons were applied
to each analysis. To further investigate interaction effects,
one-tailed paired samples T-tests were conducted as necessary. The
authors note that the statistical significance of all reported
T-tests would be the same if conducted as two-tailed tests.

Air Quality: Pollutant concentrations were averaged across the 1-h
exposure period. PM[2.5], PM[10], and CO[2] were analysed separately
using a two-way (2 x 2) repeated measures analysis of variance
(ANOVA), with inhalation pathway (normal, restricted) and pollution
exposure (clean air, PM pollution) as the factors. Bonferroni
corrections for multiple comparisons were applied to each analysis.

Exposure Awareness: The frequencies of the actual air pollution
exposure condition and the self-reported exposure condition were
compared using a kh^2 test.

Reporting summary

Further information on research design is available in the Nature
Portfolio Reporting Summary linked to this article.

Data availability

Data supporting the findings of this study are available in the
article, its Supplementary information and Source data file. Raw and
processed demographic, cognitive, and air quality data generated in
this study and used for analysis have been deposited in the
University of Birmingham eData Repository^95. Task instructions and
MATLAB scripts used for cognitive testing are available on GitHub. 
Source data are provided with this paper.

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Acknowledgements

The authors would like to take this opportunity to thank all
volunteer participants for their involvement in the project. The
authors disclose receipt of the following financial support for the
research, authorship, and/or publication of this article: This work
was supported by the Natural Environment Research Council [grant
number NE/W002213/1], awarded to T.F., G.M., and F.D.P.; and the
University of Birmingham Institute for Global Innovation Clean Air
Theme [grant number 5054], awarded to T.F., J.E.R., and F.D.P.

Author information

Authors and Affiliations

 1. University of Birmingham, School of Geography, Earth and
    Environmental Sciences, Birmingham, B15 2TT, UK

    Thomas Faherty & Francis D. Pope

 2. University of Birmingham, School of Psychology, Birmingham, B15
    2TT, UK

    Jane E. Raymond

 3. University of Manchester, Centre for Atmospheric Science,
    Department of Earth and Environmental Sciences, Manchester, M13
    9PL, UK

    Gordon McFiggans

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T.F., G.M., and F.D.P. secured funding for the study; T.F. and F.D.P.
formulated the research question; T.F., J.E.R., and F.D.P. conceived
and designed the experiment; T.F. conducted the experiment, analysed
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and F.D.P. reviewed the manuscript; and all authors approved the
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Faherty, T., Raymond, J.E., McFiggans, G. et al. Acute particulate
matter exposure diminishes executive cognitive functioning after four
hours regardless of inhalation pathway. Nat Commun 16, 1339 (2025).
https://doi.org/10.1038/s41467-025-56508-3

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  * Received: 08 July 2024

  * Accepted: 20 January 2025

  * Published: 06 February 2025

  * DOI: https://doi.org/10.1038/s41467-025-56508-3

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