Thermal therapy using laser sources can be used in combination with other cancer therapies to eliminate tumors. However, high precision temperature control is required to avoid damage in healthy surrounding tissues. Therefore, in order to detect laser induced temperature changes, we have used the fluorescence signal of the enhanced Green Fluorescent Protein (eGFP) over-expressed in an E. coli bacterial culture. For that purpose, the bacteria expressing eGFP are injected in a Fabry-Perot (FP) optofluidic planar microcavity. In order to locally heat the bacterial culture, external infrared or ultraviolet lasers were used. Shifts in the wavelengths of the resonant FP modes are used to determine the temperature increase as a function of the heating laser pump power. Laser induced local temperature increments up to 6–7 °C were measured. These results show a relatively easy way to measure laser induced local temperature changes using a FP microcavity and using eGFP as a molecular probe instead of external nanoparticles, which could damage/alter the cell. Therefore, we believe that this approach can be of interest for the study of thermal effects in laser induced thermal therapies.

1.
X.
Fan
and
I. M.
White
,
Nat. Photonics
5
,
591
(
2011
).
2.
M.
Chalfie
,
Y.
Tu
,
G.
Euskirchen
,
W. W.
Ward
, and
D. C.
Prasher
,
Science
263
,
802
(
1994
).
3.
M. C.
Gather
and
S. H.
Yun
,
Nat. Photonics
5
,
406
(
2011
).
4.
M. C.
Gather
and
S. H.
Yun
,
Opt. Lett.
36
,
3299
(
2011
).
5.
S. Y.
Lee
,
Trends Biotechnol.
14
,
98
(
1996
).
6.
G. M.
Cooper
,
The Cell: A Molecular Approach
(
Sinauer Associates
,
Sunderland, MA
,
2000
), Chap. 1.
7.
B.
Hildebrandt
,
P.
Wust
,
O.
Ahlers
,
A.
Dieing
,
G.
Sreenivasa
,
T.
Kerner
,
R.
Felix
, and
H.
Riess
,
Crit. Rev. Oncol. Hematol.
43
,
33
(
2002
).
8.
R. J.
Stafford
,
D.
Fuentes
,
A. A.
Elliott
,
J. S.
Weinberg
, and
K.
Ahrar
,
Crit. Rev. Biomed. Eng.
38
,
79
(
2010
).
9.
R.
Medvid
,
A.
Ruiz
,
R. J.
Komotar
,
J. R.
Jagid
,
M. E.
Ivan
,
R. M.
Quencer
, and
M. B.
Desai
,
Am. J. Neuroradiol.
36
,
1998
(
2015
).
10.
K.
Okabe
,
N.
Inada
,
C.
Gota
,
Y.
Harada
,
T.
Funatsu
, and
S.
Uchiyama
,
Nat. Commun.
3
,
705
(
2012
).
11.
T.
Hayashi
,
N.
Fukuda
,
S.
Uchiyama
, and
N.
Inada
,
PLoS One
10
,
e0117677
(
2015
).
12.
J. S.
Donner
,
S. A.
Thompson
,
M. P.
Kreuzer
,
G.
Baffou
, and
R.
Quidant
,
Nano Lett.
12
,
2107
(
2012
).
13.
L.
Gao
,
C.
Zhang
,
C.
Li
, and
L. V.
Wang
,
Appl. Phys. Lett.
102
,
193705
(
2013
).
14.
D.
Jaque
and
F.
Vetrone
,
Nanoscale
4
,
4301
(
2012
).
15.
A.
Elsaesser
and
C. V.
Howard
,
Adv. Drug Deliv. Rev.
64
,
129
(
2012
).
16.
F.
Lahoz
,
I. R.
Martín
,
D.
Walo
,
J.
Gil-Rostra
,
F.
Yubero
, and
A. R.
Gonzalez-Elipe
,
J. Phys. D: Appl. Phys.
50
,
215103
(
2017
).
17.
F.
Vetrone
,
R.
Naccache
,
A.
Zamarron
,
A. J.
de la Fuente
,
F.
Sanz-Rodriguez
,
L. M.
Maestro
,
E. M.
Rodriguez
,
D.
Jaque
,
J. G.
Sole
, and
J. A.
Capobianco
,
ACS Nano
4
,
3254
(
2010
).
18.
N. N.
Dong
,
M.
Pedroni
,
F.
Piccinelli
,
G.
Conti
,
A.
Sbarbati
,
J. E.
Ramirez-Hernandez
,
L. M.
Maestro
,
M. C.
Iglesias-de la Cruz
,
F.
Sanz-Rodriguez
,
A.
Juarranz
,
F.
Chen
,
F.
Vetrone
,
J. A.
Capobianco
,
J. G.
Sole
,
M.
Bettinelli
,
D.
Jaque
, and
A.
Speghini
,
ACS Nano
5
,
8665
(
2011
).
19.
A.
Benayas
,
B.
Rosal
,
A.
Pérez-Delgado
,
K.
Santacruz-Gómez
,
D.
Jaque
,
G.
Alonso-Hirata
, and
F.
Vetrone
,
Adv. Opt. Mater.
3
,
687
(
2015
).
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