Targeted SERS nanosensors measure physicochemical gradients and free energy changes in live 3D tumor spheroids

Lauren E. Jamieson; Victoria L. Camus; Pierre O. Bagnaninchi; Kate M. Fisher; Grant D. Stewart; William H. Nailon; Duncan B. McLaren; David James Harrison; Colin J. Campbell

doi:10.1039/C6NR06031E

Targeted SERS nanosensors measure physicochemical gradients and free energy changes in live 3D tumor spheroids

Lauren E. Jamieson, Victoria L. Camus, Pierre O. Bagnaninchi, Kate M. Fisher, Grant D. Stewart, William H. Nailon, Duncan B. McLaren, David James Harrison, Colin J. Campbell

School of Medicine

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

Abstract

Use of multicellular tumor spheroids (MTS) to investigate therapies has gained impetus because they have potential to mimic factors including zonation, hypoxia and drug-resistance. However, analysis remains difficult and often destroys 3D integrity. Here we report an optical technique using targeted nanosensors that allows in situ 3D mapping of redox potential gradients whilst retaining MTS morphology and function. The magnitude of the redox potential gradient can be quantified as a free energy difference (ΔG) and used as a measurement of MTS viability. We found that by delivering different doses of radiotherapy to MTS we could correlate loss of ΔG with increasing therapeutic dose. In addition, we found that resistance to drug therapy was indicated by an increase in ΔG. This robust and reproducible technique allows interrogation of an in vitro tumor-model's bioenergetic response to therapy, indicating its potential as a tool for therapy development.

Original language	English
Pages (from-to)	16710-16718
Number of pages	9
Journal	Nanoscale
Volume	8
Issue number	37
Early online date	6 Sept 2016
DOIs	https://doi.org/10.1039/C6NR06031E
Publication status	Published - 7 Oct 2016

Keywords

Nanosensor
SERS
Spheroid
Redox
Free-energy

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1039/C6NR06031ELicence: CC BY

Jamieson_2016_SERS_Nanoscale_CC
Copyright 2016 the Author(s), published by the Royal Society of Chemistry. This Open Access Article is licensed under a Creative Commons Attribution 3.0 Unported Licence.
Final published version, 2.74 MBLicence: CC BY

David James Harrison
- djh20st-andrews.acuk
Person: Academic

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title = "Targeted SERS nanosensors measure physicochemical gradients and free energy changes in live 3D tumor spheroids",

abstract = "Use of multicellular tumor spheroids (MTS) to investigate therapies has gained impetus because they have potential to mimic factors including zonation, hypoxia and drug-resistance. However, analysis remains difficult and often destroys 3D integrity. Here we report an optical technique using targeted nanosensors that allows in situ 3D mapping of redox potential gradients whilst retaining MTS morphology and function. The magnitude of the redox potential gradient can be quantified as a free energy difference (ΔG) and used as a measurement of MTS viability. We found that by delivering different doses of radiotherapy to MTS we could correlate loss of ΔG with increasing therapeutic dose. In addition, we found that resistance to drug therapy was indicated by an increase in ΔG. This robust and reproducible technique allows interrogation of an in vitro tumor-model's bioenergetic response to therapy, indicating its potential as a tool for therapy development.",

keywords = "Nanosensor, SERS, Spheroid, Redox, Free-energy",

author = "Jamieson, {Lauren E.} and Camus, {Victoria L.} and Bagnaninchi, {Pierre O.} and Fisher, {Kate M.} and Stewart, {Grant D.} and Nailon, {William H.} and McLaren, {Duncan B.} and Harrison, {David James} and Campbell, {Colin J.}",

note = "CJC is grateful to the Leverhulme trust for support (Project Grant RPG-2012-680). VLC is grateful to the Jamie King Cancer Research Fund for funding.",

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doi = "10.1039/C6NR06031E",

language = "English",

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journal = "Nanoscale",

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TY - JOUR

T1 - Targeted SERS nanosensors measure physicochemical gradients and free energy changes in live 3D tumor spheroids

AU - Jamieson, Lauren E.

AU - Camus, Victoria L.

AU - Bagnaninchi, Pierre O.

AU - Fisher, Kate M.

AU - Stewart, Grant D.

AU - Nailon, William H.

AU - McLaren, Duncan B.

AU - Harrison, David James

AU - Campbell, Colin J.

N1 - CJC is grateful to the Leverhulme trust for support (Project Grant RPG-2012-680). VLC is grateful to the Jamie King Cancer Research Fund for funding.

PY - 2016/10/7

Y1 - 2016/10/7

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AB - Use of multicellular tumor spheroids (MTS) to investigate therapies has gained impetus because they have potential to mimic factors including zonation, hypoxia and drug-resistance. However, analysis remains difficult and often destroys 3D integrity. Here we report an optical technique using targeted nanosensors that allows in situ 3D mapping of redox potential gradients whilst retaining MTS morphology and function. The magnitude of the redox potential gradient can be quantified as a free energy difference (ΔG) and used as a measurement of MTS viability. We found that by delivering different doses of radiotherapy to MTS we could correlate loss of ΔG with increasing therapeutic dose. In addition, we found that resistance to drug therapy was indicated by an increase in ΔG. This robust and reproducible technique allows interrogation of an in vitro tumor-model's bioenergetic response to therapy, indicating its potential as a tool for therapy development.

KW - Nanosensor

KW - SERS

KW - Spheroid

KW - Redox

KW - Free-energy

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JO - Nanoscale

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ER -

Targeted SERS nanosensors measure physicochemical gradients and free energy changes in live 3D tumor spheroids

Abstract

Keywords

UN SDGs

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David James Harrison

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