Indoor Air Quality (IAQ) has been an area of growing concern with the increasing knowledge of health hazards associated with contaminants, particularly in high occupancy buildings where residents may be exposed to high levels of nuisance dust and other contaminants. Leadership and Energy in Environmental Design (LEED®) certification, which is awarded to buildings that prioritize sustainability and efficient resource use, has been increasingly sought in new construction. As LEED-certified buildings become more commonplace, it is worthwhile to consider whether these new building practices improve IAQ for its occupants. This study compares particulate matter (PM) concentrations in 12 LEED-certified buildings to 12 analogous non-LEED certified buildings on the University of Utah campus. Real-time air sampling was conducted in each building for PM measurements and a Wilcoxon signed rank test was conducted to compare PM levels. A statistically significant difference was found between LEED certification and PM concentrations, with LEED-certified buildings containing, on average, approximately half the PM of their non-LEED counterparts. These findings suggest that LEED certification is worth the financial investment, as it may lead to improved IAQ for residents. However, further research on other contaminants is warranted, including the characterization and comparison of formaldehyde and carbon dioxide levels.

Indoor Air Quality (IAQ), Particulate Matter Concentrations (PM), LEED-Certified Buildings, Sick Building Syndrome (SBS)
1.
Singh,
A.
,
et al.,
Effects of Green Buildings on Employee Health and Productivity
.
American Journal of Public Health
,
2010
.
Google Scholar
 
2.
Heinzerling,
A.,
Hsu
J.,
and
Yip
F.
,
Respiratory Health Effects of Ultrafine Particles in Children: a Literature Review
.
Water, Air, & Soil Pollution
,
2015
.
Google Scholar
 
3.
Li,
H.
,
et al.,
Particulate Matter Exposure and Stress Hormone Levels
.
Circulation
,
2017
.
Google Scholar
 
4.
Europe, W.R.O.f.
,
WHO Guidelines for Indoor Air Quality: Selected Pollutants
.
2010
:
World Health Organization
.
PubMed
 
5.
EPA.
Health and Environmental Effects of Particulate Matter (PM)
.
2018
;
Available from: https://www.epa.gov/pm-pollution/health-and-environmental-effects-particulate-matter-pm.
6.
EPA.
Indoor Air Quality in Offices and Other Large Buildings
.
2017
;
Available from: https://www.epa.gov/indoor-air-quality-iaq/indoor-air-quality-offices-and-other-large-buildings.
7.
Hepner,
C.M.
and
Boser
R.A.
,
Architects’ Perceptions of LEED Indoor Environmental Quality Checklist Items on Employee Productivity
.
International Journal of Construction Education and Research
,
2006
.
Google Scholar
 
8.
Joshi,
S.
,
The sick building syndrome
.
Indian Journal of Occupational and Environmental Medicine,
2008
.
12
(
2
): p.
61
.
Google Scholar
Crossref
Search ADS
 
9.
Apte,
M.G.,
Fisk
W.J.,
and
J.M.
Daisey, Associations Between Indoor CO2 Concentrations and Sick Building Syndrome Symptoms in U.S. Office Buildings: An Analysis of the 1994–1996 BASE Study Data
.
Indoor Air
,
2000
.
Google Scholar
 
10.
Gyntelberg,
F.
,
et al.,
Dust and the Sick Building Syndrome
.
Indoor Air
,
1994
.
Google Scholar
 
11.
EPA.
Indoor Air Facts No. 4: Sick Building Syndrome
.
1991
.
12.
Fischer,
A.
,
et al.,
Ventilation strategies and indoor particulate matter in a classroom
.
Indoor Air
,
2015
.
Google Scholar
 
13.
Trompetter,
W.J.
,
et al.,
The effect of ventilation on air particulate matter in school classrooms
.
Journal of Building Engineering
,
2018
.
Google Scholar
 
14.
Fisk,
W.J.,
Mirer
A.G.,
and
Mendell
M.J.
,
Quantitative relationship of sick building syndrome symptoms with ventilation rates
.
Indoor Air
,
2009
.
Google Scholar
 
15.
Rosbach,
J.
,
et al.,
Classroom ventilation and indoor air quality—results from the FRESH intervention study
.
Indoor Air
,
2016
.
Google Scholar
 
16.
Norhidayah,
A.
,
et al.,
Indoor Air Quality and Sick Building Syndrome in Three Selected Buildings
.
Procedia Engineering
,
2013
.
Google Scholar
 
17.
Database of State Indoor Air Quality Laws.
2019
;
Available from: https://www.eli.org/buildings/database-state-indoor-air-quality-laws.
18.
OSHA.
OSHA Annotated Table Z-1
.
2011
;
Available from: https://www.osha.gov/dsg/annotated-pels/tablez-1.html.
19.
EPA.
NAAQS Table
.
2016
;
Available from: https://www.epa.gov/criteria-air-pollutants/naaqs-table.
20.
Burge,
P.S.
,
Sick building syndrome
.
Occupational and Environmental Medicine
,
2004
.
Google Scholar
 
21.
Ben-David,
T.
and
Waring
M.S.
,
Interplay of ventilation and filtration: Differential analysis of cost function combining energy use and indoor exposure to PM2.5 and ozone
.
Building and Environment
,
2018
.
128
: pp.
320
335
.
Google Scholar
Crossref
Search ADS
 
22.
Allen,
J.G.
,
et al.,
Green Buildings and Health
.
Current Environmental Health Reports
,
2015
.
Google Scholar
 
23.
Newsham,
G.R.
,
et al.,
Do ‘green’buildings have better indoor environments? New evidence
.
Building Research & Information
,
2013
.
Google Scholar
 
24.
MacNaughton,
P.
,
et al.,
The impact of working in a green certified building on cognitive function and health
.
Building and Environment
,
2017
.
Google Scholar
 
25.
Khoshbakht,
M.
,
et al.,
Are green buildings more satisfactory? A review of global evidence
.
Habitat International
,
2018
.
Google Scholar
 
26.
Hult,
E.L.
,
et al.,
Formaldehyde and acetaldehyde exposure mitigation in US residences: in-home measurements of ventilation control and source control
.
Indoor Air
,
2015
.
Google Scholar
 
27.
Gou,
Z.
and
Xie
X.
,
Evolving green building: triple bottom line or regenerative design?
Journal of Cleaner Production
,
2017
.
153
: pp.
600
607
.
Google Scholar
Crossref
Search ADS
 
28.
EPA.
US Green Building Council’s Leadership in Energy and Environmental Design (LEED)
.
2017
;
Available from: https://www.epa.gov/smartgrowth/us-green-building-councils-leadership-energy-and-environmental-design-leedr.
29.
USCBC.
Green Building Leadership is LEED
.
2019
;
Available from: https://new.usgbc.org/leed.
30.
Wei,
W.,
Ramalho
O.,
and
Mandin
C.
,
Indoor air quality requirements in green building certifications
.
Building and Environment
,
2015
.
Google Scholar
 
31.
USGBC
.
Construction IAQ management plan – during construction
.
2019
;
Available from: https://www.usgbc.org/credits/new-construction/v22/eqc31?view=interpretations.
32.
Lee,
E.
,
Indoor environmental quality (IEQ) of LEED-certified home: Importance-performance analysis (IPA)
.
Building and Environment
,
2019
.
Google Scholar
Crossref
Search ADS
 
33.
Steinemann,
A.,
Wargocki
P.,
and
Rismanchi
B.,
Ten questions concerning green buildings and indoor air quality
.
Building and Environment
,
2017
.
Google Scholar
Crossref
Search ADS
 
34.
Batterman,
S.
,
et al.,
Ventilation rates in recently constructed U.S. school classrooms
.
Indoor Air
,
2017
.
Google Scholar
 
35.
Stephens,
B.
and
Siegel
J.A.
,
Ultrafine particle removal by residential heating, ventilating, and air-conditioning filters
.
Indoor Air
,
2013
.
Google Scholar
Crossref
Search ADS
 
36.
Coombs,
K.C.
,
et al.,
Indoor air quality in green-renovated vs. non-green low-income homes of children living in a temperate region of US (Ohio)
.
Science of The Total Environment
,
2016
.
Google Scholar
Crossref
Search ADS
 
37.
Xiong,
Y.
,
et al.,
Indoor air quality in green buildings: A case-study in a residential high-rise building in the northeastern United States
.
J Environ Sci Health A Tox Hazard Subst Environ Eng
,
2015
.
Google Scholar
 
38.
Hamilton,
M.
,
et al.,
Perceptions in the U.S. building industry of the benefits and costs of improving indoor air quality
.
Indoor Air
,
2016
.
Google Scholar
 
39.
Sustainability: Energy and Buildings.
2019
;
Available from:
https://sustainability.utah.edu/progress/focus-areas/energy-buildings/leed-buildings/.
40.
Nicolow,
J.
Measuring the Cost to Become LEED Certified
.
2008
;
Available from: http://www.facilitiesnet.com/bom/articleemail.asp?id=10057.
Google Scholar
 
41.
Sustainability: LEED Buildings
2019
;
Available from: https://sustainability.utah.edu/progress/focus-areas/energy-buildings/leed-buildings/.
42.
Utah Museum of Fine Arts.
2019
;
Available from: https://umfa.utah.edu.
43.
Utah Museum of Natural History.
2019
;
Available from: https://nhmu.utah.edu.
44.
Sleeth,
D.
,
Quantitative Exposure Assessment: Sampling Strategies
.
2019
.
Google Scholar
 
45.
University of Utah.
2019
;
Available from: https://www.usnews.com/best-colleges/university-of-utah-3675.
46.
University of Utah Main Campus.
2019
;
Available from: https://www.utah.edu/printable-maps/assets/main-campus-map.pdf.
47.
TSI.
DustTrak II Aerosol Monitor 8532
.
2019
;
Available from: https://www.tsi.com/dusttrak-ii-aerosol-monitor-8532/.
48.
USGBC.
U. of Utah Turpin Building Renovation
.
2019
;
Available from: https://www.usgbc.org/projects/u-utah-turpin-building-renovation.
49.
Zona,
Z.
,
et al.,
Changes in particulate matter concentrations at different altitudinal levels with environmental dynamics
.
Journal of Animal and Plant Sciences
,
2015
.
Google Scholar
 
50.
Wilcoxon Signed Ranks Test,
in
Encyclopedia of Measurement and Statistics
.
Sage Publications, Inc
.
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Author notes

1. Rocky Mountain Center for Occupational and Environmental Health, University of Utah, 391 Chipeta Way, Suite C, SLC, UT 84108. Telephone: 801-581-4800 Fax: 801-581-7224

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2020