(397bf) Facile Method to Synthesize Graphene-ZnS Nanocomposites and Their Application in Bioelectrochemistry of Hemoglobin

Electrochemical technology is a useful way to probe the
protein conformation and protein electron transfer. Thus, the direct electron
transfer (DET) between biomolecule and electrode has aroused growing interest
due to its significance in both theoretical and practical applications^[1,2].
In recent years, many researches have focused on the application of
nanomaterials to modify electrode. For example, graphene (GR), a two-dimensional sheet of carbon atoms bonded
through sp² hybridization with the properties of high electrical
conductivity, exceptional thermal and mechanical stability, is showing promising
applications in electrode modification^[3]. Due to the excellent optical
and electronic properties, semiconductor quantum dots (QDs) has also been used in
the fields of electrochemical as well as photoelectrochemical biosensors^[4].
Among the QDs materials, CdS nanostructures were most generally used. However, considering
that CdS might be harmful and carcinogenic to the human beings^[5], ZnS
nanomaterial, a semiconductor with large band-gap energy and good conductivity,
has been a good substitute of CdS owing to its low cost and nontoxicity^[6].

In this work, we explored a new method to fabricate
graphene-ZnS (GR-ZnS) nanocomposites for electrochemical applications based on
noncovalent functionalization of graphene (Figure 1). Compared with the harshly
oxidative approaches, herein, the surface of pristine graphene was firstly modified
with 1-aminopyrene via a strong ¦Ð-¦Ð stacking mechanism between the pyrenyl
groups and the carbon rings of the graphene. The introduction of active amine
group on the graphene could not only improve the dispersibility of graphene but
also provide nucleation centers on the surface of graphene for the uniform
growth of ZnS nanoparticles. The as-prepared GR-ZnS nanocomposites were
characterized and identified by means of TEM and EDS analysis, indicating the uniform
formation of ZnS nanoparticles on the surface of graphene. FT-IR spectroscopic
results confirmed that hemoglobin (Hb) remained its native structure in the
nanocomposite material. The GR-ZnS nanocomposites could efficiently promote the
direct electron transfer between Hb and electrode with the electron transfer
rate constant of 3.42 s^-1. The modified electrode was then used for
the determination of H₂O₂
based on the electrocatalytic activity of Hb towards H₂O₂,
which exhibited a linear range from 10 to 250 µM with a detection limit of 1.12
µM. The proposed method to
fabricate graphene-based hybrid nanomaterials would have a great potential for
a wide range of applications.

Figure 1.
Fabrication of a H₂O₂ biosensor.

This work was supported by the NSF of China
(51173128, 31071509), the Ministry of Science and Technology of China (Nos.
2012YQ090194, 2013AA102204, 2012BAD29B05), the Program for New Century
Excellent Talents in Chinese University (NCET-08-0386), and Beiyang Young
Scholar Program (2012).

References

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