Nanoparticle Cytometrics: a quantitative analysis of the toxic effect of nanoparticles
Lead Research Organisation:
Swansea University
Department Name: College of Engineering
Abstract
The last decade has seen an explosion in the development and use of nanoscale technologies and materials and this trend will undoubtedly continue for some time to come. It is clear therefore that human exposure to nanoscale particles will grow dramatically and this has triggered serious concerns over the safety of nanoparticles in relation to human health and the wider ecosystems within which we live. Much of this stems from the paradigm shift incorporated in the move to nano scales which invalidates current chemical risk assessments that are based on bulk properties and hence grossly inappropriate for nano-systems. A marked example of this is provided by noble metals such as Gold; these are traditionally viewed as inert and hence bio-compatible however in nano-particulate form the huge increase in their surface area makes them highly reactive. The issue of surface area has led to the realisation that the quantisation of potential toxins into nano-particulate form is important and that assessment of health risk must take account of specific particle number rather than gross measures of chemical solution based on weight per volume. There is also a growing realisation that the function of particles due to size, shape and chemistry is important. This gap in understanding of chemical hazard at the nanoscale has led to a number of reports from government agencies and royal commissions emphasising the need to develop new measurement techniques to quantify the level of nanoparticle dose and to assess potential toxicity. We propose to use flow cytometry, a laser-based technology, to optically track fluorescent nanoparticles within populations of living cells. This optical measurement approach will be linked to electron microscopy to image particles within cells at the nanoscale. Together these techniques will provide a fully calibrated metrology providing information on number of particles per cell for each and every cell within a measured set (typically a million cells). Our objective is to provide a fundamental understanding of the way in which nanoparticle dose is acquired by cells through natural uptake mechanisms (endocytosis) and then diluted within growing tissue as particles are divided between daughter cells upon cell division (mitosis). A range of cell types will be used to reflect the main exposure routes to nanoparticles, i.e. skin, lung and circulatory (blood) systems. A detailed study of any toxic effects of nanoparticles on the cells will be undertaken and this together with the absolute quantification of dose will allow us to correlate any potential nanotoxicity to the number and form of nanoparticle within a given cell type.
Publications
Summers HD
(2013)
Quantification of nanoparticle dose and vesicular inheritance in proliferating cells.
in ACS nano
Ware MJ
(2014)
Analysis of the influence of cell heterogeneity on nanoparticle dose response.
in ACS nano
Soenen SJ
(2013)
Fluorescent non-porous silica nanoparticles for long-term cell monitoring: cytotoxicity and particle functionality.
in Acta biomaterialia
Rees P
(2011)
A transfer function approach to measuring cell inheritance.
in BMC systems biology
Rees P
(2016)
An Analysis of the Practicalities of Multi-Color Nanoparticle Cellular Bar-Coding.
in Combinatorial chemistry & high throughput screening
Nagy D
(2021)
Developing ovine mammary terminal duct lobular units have a dynamic mucosal and stromal immune microenvironment.
in Communications biology
Summers HD
(2015)
Poisson-event-based analysis of cell proliferation.
in Cytometry. Part A : the journal of the International Society for Analytical Cytology
Wills JW
(2020)
Image-Based Cell Profiling Enables Quantitative Tissue Microscopy in Gastroenterology.
in Cytometry. Part A : the journal of the International Society for Analytical Cytology
Davies N
(2015)
Development of an Optically Transparent Silicon Based Technology Platform for Biological Analysis
in IEEE Sensors Journal
Tonkin J
(2014)
Optical tracking of drug release from porous silicon delivery vectors
in IET Optoelectronics
Margulis K
(2014)
Active curcumin nanoparticles formed from a volatile microemulsion template
in Journal of Materials Chemistry B
Hondow N
(2016)
Quantifying the cellular uptake of semiconductor quantum dot nanoparticles by analytical electron microscopy.
in Journal of microscopy
Hondow N
(2012)
Quantitative characterization of nanoparticle agglomeration within biological media
in Journal of Nanoparticle Research
Hondow N
(2014)
Quantifying Nanoparticle-Cell Interactions
in Microscopy and Microanalysis
Manshian BB
(2016)
Genotoxic capacity of Cd/Se semiconductor quantum dots with differing surface chemistries.
in Mutagenesis
Doak SH
(2012)
In vitro genotoxicity testing strategy for nanomaterials and the adaptation of current OECD guidelines.
in Mutation research
Brown MR
(2015)
Statistical prediction of nanoparticle delivery: from culture media to cell.
in Nanotechnology
Rees P
(2019)
The origin of heterogeneous nanoparticle uptake by cells.
in Nature communications
Rees P
(2014)
Nanoparticle vesicle encoding for imaging and tracking cell populations.
in Nature methods
Summers H
(2011)
Statistical analysis of nanoparticle dosing in a dynamic cellular system
in Nature Nanotechnology
Summers H
(2011)
Bionanoscience: Nanoparticles in the life of a cell.
in Nature nanotechnology
Wills JW
(2016)
Genetic toxicity assessment of engineered nanoparticles using a 3D in vitro skin model (EpiDerm™).
in Particle and fibre toxicology
Description | We have established that nanoparticle uptake into biological cells is a random process. Through detailed experimental studies we have shown that statistical mathematics can be used to describe the particle uptake and through this probability approach prediction of nanoparticle-cell interactions can be achieved. In the context of nanotoxicology research we have shown that time dependent studies provide a more accurate assessment of the actual dose delivered to the cell than the standard end-point measurements. |
Exploitation Route | Using our findings researchers can now accurately predict the nanoparticle dose across a population of cells and the dilution of this dose as the cells divide. This will allow meaningful assessment of the potency of nanomedicines and the toxicity of nanoparticles. |
Sectors | Environment Healthcare Pharmaceuticals and Medical Biotechnology |
Description | EPSRC Platform |
Amount | £1,250,000 (GBP) |
Funding ID | EP/N013506/1 |
Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
Sector | Public |
Country | United Kingdom |
Start | 02/2016 |
End | 01/2021 |
Description | Joint research programme and student exchange |
Organisation | The Methodist Hospital, Houston |
Country | United States |
Sector | Hospitals |
PI Contribution | Development of time-mortality based dose-response assays appropriate for the assessment of nanomedicine potency |
Collaborator Contribution | hosting of students in the US, provision of facilities (EM, animal studies, RF treatment systems), performing experimental studies on nanomedicine-cell interactions in-vitro and in-vivo |
Impact | Papers published - entered in relevant section PhD student trained and now continuing career as a PDRA in Baylor College of Medicine in Houston |
Start Year | 2009 |