Confocal microscopy 3D imaging of diesel particulate matter

Lisa Miyashita; Gary Foley; Ian Gill; Gavin Gillmore; Jonathan Grigg; David Wertheim

doi:10.1007/s11356-021-14025-y

Confocal microscopy 3D imaging of diesel particulate matter

Lisa Miyashita
, Gary Foley
, Ian Gill
, Gavin Gillmore
, Jonathan Grigg
, David Wertheim

Queen Mary University of London
Kingston University
Bath Spa University

Research output: Contribution to journal › Article › peer-review

5 Downloads (Pure)

Abstract

To date, diesel particulate matter (DPM) has been described as aggregates of spherule particles with a smooth appearing surface. We have used a new colour confocal microscope imaging method to study the 3D shape of diesel particulate matter (DPM); we observed that the particles can have sharp jagged appearing edges and consistent with these findings, 2D light microscopy demonstrated that DPM adheres to human lung epithelial cells. Importantly, the slide preparation and confocal microscopy method applied avoids possible alteration to the particles' surfaces and enables colour 3D visualisation of the particles. From twenty-one PM particles, the mean (standard deviation) major axis length was 5.6 (2.25) μm with corresponding values for the minor axis length of 3.8 (1.25) μm. These new findings may help explain why air pollution particulate matter (PM) has the ability to infiltrate human airway cells, potentially leading to respiratory tract, cardiovascular and neurological disease.

Original language	English
Pages (from-to)	30384-30389
Journal	Environmental Science and Pollution Research
Volume	28
Early online date	23 Apr 2021
DOIs	https://doi.org/10.1007/s11356-021-14025-y
Publication status	Published - 30 Jun 2021

Bibliographical note

Note: This work was supported by Barts Charity, UK [ref: MGU0312] and The Medical College of Saint Bartholomew's Hospital Trust [ref: 17/LO/1752].

Keywords

3D microscope imaging
Computer science and informatics
confocal microscopy
diesel particulate matter
particulate matter

Access to Document

10.1007/s11356-021-14025-y

Gill-I-48857-VoRFinal published version, 2.12 MBLicence: CC BY

https://doi.org/10.1007/s11356-021-14025-y

Particles II: impact on biological systems and the environment
Wertheim, D., Gillmore, G., Brown, L. & Petford, N., 2022, Weinheim, Germany: Wiley. 22 p. (Advanced Optical Metrology; no. 11)
Research output: Book/Report › Book › peer-review

Cite this

@article{a1ebac726deb487093c6b75cb145f65d,

title = "Confocal microscopy 3D imaging of diesel particulate matter",

abstract = "To date, diesel particulate matter (DPM) has been described as aggregates of spherule particles with a smooth appearing surface. We have used a new colour confocal microscope imaging method to study the 3D shape of diesel particulate matter (DPM); we observed that the particles can have sharp jagged appearing edges and consistent with these findings, 2D light microscopy demonstrated that DPM adheres to human lung epithelial cells. Importantly, the slide preparation and confocal microscopy method applied avoids possible alteration to the particles' surfaces and enables colour 3D visualisation of the particles. From twenty-one PM particles, the mean (standard deviation) major axis length was 5.6 (2.25) μm with corresponding values for the minor axis length of 3.8 (1.25) μm. These new findings may help explain why air pollution particulate matter (PM) has the ability to infiltrate human airway cells, potentially leading to respiratory tract, cardiovascular and neurological disease.",

keywords = "3D microscope imaging, Computer science and informatics, confocal microscopy, diesel particulate matter, particulate matter",

author = "Lisa Miyashita and Gary Foley and Ian Gill and Gavin Gillmore and Jonathan Grigg and David Wertheim",

note = "Note: This work was supported by Barts Charity, UK [ref: MGU0312] and The Medical College of Saint Bartholomew's Hospital Trust [ref: 17/LO/1752].",

year = "2021",

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doi = "10.1007/s11356-021-14025-y",

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T1 - Confocal microscopy 3D imaging of diesel particulate matter

AU - Miyashita, Lisa

AU - Foley, Gary

AU - Gill, Ian

AU - Gillmore, Gavin

AU - Grigg, Jonathan

AU - Wertheim, David

N1 - Note: This work was supported by Barts Charity, UK [ref: MGU0312] and The Medical College of Saint Bartholomew's Hospital Trust [ref: 17/LO/1752].

PY - 2021/6/30

Y1 - 2021/6/30

N2 - To date, diesel particulate matter (DPM) has been described as aggregates of spherule particles with a smooth appearing surface. We have used a new colour confocal microscope imaging method to study the 3D shape of diesel particulate matter (DPM); we observed that the particles can have sharp jagged appearing edges and consistent with these findings, 2D light microscopy demonstrated that DPM adheres to human lung epithelial cells. Importantly, the slide preparation and confocal microscopy method applied avoids possible alteration to the particles' surfaces and enables colour 3D visualisation of the particles. From twenty-one PM particles, the mean (standard deviation) major axis length was 5.6 (2.25) μm with corresponding values for the minor axis length of 3.8 (1.25) μm. These new findings may help explain why air pollution particulate matter (PM) has the ability to infiltrate human airway cells, potentially leading to respiratory tract, cardiovascular and neurological disease.

AB - To date, diesel particulate matter (DPM) has been described as aggregates of spherule particles with a smooth appearing surface. We have used a new colour confocal microscope imaging method to study the 3D shape of diesel particulate matter (DPM); we observed that the particles can have sharp jagged appearing edges and consistent with these findings, 2D light microscopy demonstrated that DPM adheres to human lung epithelial cells. Importantly, the slide preparation and confocal microscopy method applied avoids possible alteration to the particles' surfaces and enables colour 3D visualisation of the particles. From twenty-one PM particles, the mean (standard deviation) major axis length was 5.6 (2.25) μm with corresponding values for the minor axis length of 3.8 (1.25) μm. These new findings may help explain why air pollution particulate matter (PM) has the ability to infiltrate human airway cells, potentially leading to respiratory tract, cardiovascular and neurological disease.

KW - 3D microscope imaging

KW - Computer science and informatics

KW - confocal microscopy

KW - diesel particulate matter

KW - particulate matter

U2 - 10.1007/s11356-021-14025-y

DO - 10.1007/s11356-021-14025-y

M3 - Article

SN - 0944-1344

VL - 28

SP - 30384

EP - 30389

JO - Environmental Science and Pollution Research

JF - Environmental Science and Pollution Research

ER -

Confocal microscopy 3D imaging of diesel particulate matter

Abstract

Bibliographical note

Keywords

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Research output

Particles II: impact on biological systems and the environment

Cite this