Page 81 - 78_03
P. 81
DISEÑO
DE
UN
GENOSENSOR…
14.
Carpini
G.,
Lucarelli
F.,
Marrazza
G.,
&
Mascini
M.
(2004).
Oligonucleotide--modi?ed
screen--
printed
gold
electrodes
for
enzyme--ampli?ed
sensing
of
nucleic
acids.
Biosensors
&
Bioelectronics,
20(2),
167–175.
15.
Miranda--Castro
R.,
de--los--Santos--Álvarez
P.,
Lobo--Castañón
M.J.,
Miranda--Ordieres
A.J.,
&
Tuñón--Blanco
P.
(2007).
Hairpin--DNA
probe
for
enzyme--amplified
electrochemical
detection
of
Legionella
pneumophila.
Analytical
Chemistry,
79(11),
4050--4055.
16.
Basic
Local
Alignment
Search
Tool;
www.ncbi.nlm.nih.gov/BLAST
17.
Zuker,
M.
(2003).
Mfold
web
server
for
nucleic
acid
folding
and
hybridization
prediction.
Nucleic
Acids
Research,
31(13),
3406--3415.
18.
McEwen,G,
Chen,
F.,
&
Zhou,
A.
(2009).
Immobilization,
hybridization
and
oxidation
of
synthetic
DNA
on
gold
surface:
electron
transfer
investigated
by
electrochemistry
and
scanning
tunneling
microscopy.
Analytical
chimica
acta,
643(1--2),
26--37.
19.
García--González
R.,
Abedul--Fernández
M.T.,
Pernía
A.,
&
Costa--García
A.
(2008).
Electrochemical
characterization
of
different
screen--printed
gold
electrodes.
Electrochimica
acta,
53(8),
3242--3249.
20.
Levicky
R.,
Herne
T.M.,
Tarlov,
M.J.,
&
Satija
S.K.
(1998).
Using
self--assembly
to
control
the
structure
of
DNA
monolayers
in
gold:
A
Neutron
Reflectivity
Study.
Journal
of
the
American
Chemical
Society,
120(38),
9787--9792.
NOTA
DEL
EDITOR
Este
trabajo
obtuvo
el
Premio
FAES--FARMA
en
el
concurso
científico
2011
de
la
Real
Academia
Nacional
de
Farmacia.
343
