Salmonella typhi determination usin

Salmonella typhi determination using voltammetric amplification
of nanoparticles: A highly sensitive strategy for metalloimmunoassay
based on a copper-enhanced gold label

A highly sensitive electrochemical amplification immunoassay for Salmonella typhi (S. typhi) determination
has been developed for the first time by using a copper-enhanced gold nanoparticle label coupled with
anodic stripping voltammetry. Monoclonal antibodies for S. typhi were first immobilized on polystyrene
microwells and then captured by S. typhi bacteria. After an immunoreaction occurred, a polyclonal,
antibody–colloidal gold conjugate was added to bind to the S. typhi bacteria. Next, a copper-enhancer
solution containing ascorbic acid and copper (II) sulfate was added into the polystyrene microwells. The
ascorbic acidwas employed to reduce the copper (II) ions to copper (0), whichwas subsequently deposited
onto the gold nanoparticle tags. After the copperwas dissolved in nitric acid, the released copper ionswere
detected by anodic stripping voltammetry. The amount of deposited copper was related to the amount
of gold nanoparticle tag present, which was controlled by the amount S. typhi attached to the polyclonal
antibody–colloidal gold conjugate. Therefore, the anodic stripping peak current was linearly dependent
on the S. typhi concentration over concentration range of 1.30×102 cfu/mL to 2.6×103 cfu/mL in a logarithmic
plot, with a detection limit as low as 98.9 cfu/mL. The influences of the relevant experimental
variables, such as the concentration of copper and the reaction time of S. typhi with antibody, were investigated.
We also successfully applied this method to determine the presence of S. typhi in human serum.
Our results are a step towards developing more sensitive and reliable nanoparticle immunoassays.
1. Introduction
Typhoid fever is a serious problem for the public health of both
underdeveloped and developing countries. It is a bacterial illness
causedby Salmonella typhi (S. typhi), also knownas Salmonella enterica
serotype Typhi, a Gram-negative rod found only in humans.
Each year, around 16 million incidences of typhoid are reported
worldwide, resulting in an estimated 600,000 deaths [1,2]. The
transmission of typhoid fever may occur through several pathways,
such as by contact with infected individuals and by eating
food or by drinking water that is contaminated with typhoid bacteria.
Following ingestion, the bacteria spread from the intestine
via the bloodstream to the intestinal lymph nodes and other areas
of the body where they multiply. The symptoms of this illness
are characterized by the sudden onset of sustained fever, severe
headache, loss of appetite, and either constipation or mild diarrhea.
Samples of urine or blood are used to check the presence of S.
typhi, which is the only way to ensure that the observed illness is
typhoid fever [3]. Therefore, the determination of S. typhi in urine
or blood plays an important role in clinical research and diagnosis
of typhoid fever. Furthermore, a person who recovers from typhoid
fevermay still become an asymptomatic carrier who can infect others.
Thus, the level of S. typhi in the patient’s urine or blood after
recovery should be continuously monitored in order to control the
spread of this epidemic disease. Classical methods are usually used
to detect S. typhi, including culturing [4,5], serological methods,
such as slide agglutination and the Widal test [6], and polymerase
chain reaction (PCR) [7,8]. Even though these methods can provide
highly sensitive results for both qualitative and quantitative analysis,
they are quite labor- and time-intensive to perform due to the
pre-enrichment, isolation, and amplification steps of the bacterial
cells.
With the above-mentioned drawbacks, efforts to develop a
method for S. typhi determination with increased sensitivity and
selectivity and a reduction in analysis time have been proposed.
Currently, alternative methods for biological molecular analysis
are enzyme immunoassay [9,10], surface plasmon resonance [11],
and electrochemical immunoassay [12–14]. In particular, the use
of electrochemical immunoassay has attracted considerable interest
for S. typhi determination because of its inherent simplicity,
high sensitivity, inexpensive instrumentation, and miniaturization.
Although this method has a low detection limit and could be used
in the diagnosis of typhoid fever, a sensitive and rapid method for
analyzing and obtaining important information about the effectiveness
of therapy, follow-up treatments, the epidemic disease, and
protection is still needed. With the development of nanotechnology,
various nanoparticles [15,16] and nano-quantum dots [17,18]
have been used as labels to enhance the sensitivity of the electrochemical
immunoassay technique. Amplified electrochemical
detection of biological molecules was achieved by the dissolution
of the metallic nanoparticles and by recording the subsequent electrochemical
stripping of the dissolved ions. Gold nanoparticles act
as a class of labels with many unique features, such as optical, electronic,
and catalytic properties, that have been previously explored
for potential applications in biomolecular detection. Based on these
advantages, colloidal gold was used as an electrochemical marker
or catalytic label for nanoparticle enlargement in order to elevate
the sensitivity of the bioassay.
Recently, copper, silver, and gold-enhanced colloidal gold have
been reported for immunoglobin G (IgG) determination, which
is the model of electrochemical immunoassay with low detection
limits ranged from 1.0 ng/mL to 0.25 pg/mL [19–21]. The
metal-enhanced colloidal gold electrochemical stripping metalloimmunoassay
combines the high sensitivity of stripping metal
analysis with the remarkable signal amplification resulting from
the catalytic precipitation of metals onto the gold nanoparticles
[21–23]. Among these metals, the copper-enhanced protocol
is better than the other metal-enhancing protocols because the
copper-enhancer solution, which contains ascorbic acid and copper
sulphate, is easy to prepare and preserve. Furthermore, the copper
determination by anodic stripping voltammetry is simple, and
highly sensitive. Willner and co-workers also applied the catalytic
deposition of copper on gold nanoparticles forNADHdetection [24].
However, metal-enhanced colloidal gold has not been previously
applied to the detection of bacterial cells in real samples, especially
for the detection of S. typhi. Therefore,we have employed the
electrochemical strippingmetalloimmunoassay based on a copperenhanced
gold nanoparticle label for the determination of S. typhi in
real samples for the very first time, which will be useful in the diagnosis,
follow-up treatment, and controlling in advance the epidemic
disease of typhoid fever.
In thiswork, our ultimate aimwas to develop an electrochemical
metalloimmunoassay based on copper-enhanced gold nanoparticle
label for S. typhi determination in real samples with a low limit
of detection, high accuracy, and fast analysis time. The details of
the optimization and the excellent performance of our proposed
method are presented in the following sections.
2. Experimental
2.1. Instrumentation
The stripping voltammograms were recorded using an Autolab
Potentiostat 30 (Metrohm, Switzerland) with a three-electrode system.
A glassy-carbon (GC) electrode (Bioanalytical System Inc., area
0.07 cm2) was used as the working electrode. Prior to use, the GC
electrode was pretreated by sequential polishing with 1m and
0.3m of alumina/water slurries on felt pads, followed by rinsing
with deionized water in order to remove the alumina impurities.
A platinum wire and Ag/AgCl with a salt bridge were used as the
counter and reference electrodes, respectively. The electrochemical
equipmentwas housed in a Faraday cage to reduce electronic noise.
2.2. Materials and methods
The polystyrene, 96-well, microtiter plates (high-binding ELISA
plates) were purchased from Ronbio (Shanghai, China). Polyclonal
and monoclonal rabbit antibodies for polysaccharides of
S. typhi O901 and S. typhi were obtained from Siriraj Hospital.
Hydrogen tetrachloroaurate (III) and albumin bovine serum
(BSA) were obtained from the Sigma Chemical Co. (St. Louis, MO).
Nitric acid (65%), sodium chloride, sodium dihydrogen phosphate,
disodium hydrogen phosphate, sodium carbonate, sodium bicarbonate,
sodium citrate, copper (II) sulfate, and ascorbic acid were
obtained from Merck (Germany).
The coating buffer for the microwells was 0.05M
NaHCO3–Na2CO3 (pH 9.6). The incubation and washing buffer
consisted of 0.01MNaH2PO4–Na2HPO4 (pH 7.4) and 0.15Msodium
chloride. The copper-enhancer solution was made from a 1:1 (v/v)
ratio of 0.10M ascorbic acid and 0.2M copper (II) sulfate. All of
the solutions were prepared using Milli-Q 18M water (Millipore
purification system).
2.3. Preparation of the antibody–colloidal gold conjugate
2.3.1. Preparation of gold nanoparticles
The gold nanoparticles were prepared according to the method
reported in Refs. [19,25] with slight modifications. Briefly, 1mL
of 1% HAuCl4 solution was mixed with 100mL of doubly distilled
water and boiled under vigorous stirring. Then, 2.5mLof 1% sodium
citrate was added into solution under continuous heating and stirring
for 15min until the color of solution changed to wine red. The
colloidal solution was left to cool at room temperature under stirring
and was later stored in dark bottles at 4 ◦C. The solution of
colloidal gold particles was characterized by a UV–vis spectrophotometer
and a transmission electron microscope (TEM).
2.3.2. Antibody–colloidal gold conjugate
The amount of coating antibody (polyclonal rabbit antibody for
polysaccharides of S. typhi O901) on the surface of the gold nanoparticles
was optimized from 75mg/L to 1200 mg/L. Solutions were
prepared from 15,000 mg/L stock solutions of the rabbit antibody
to S. typhi. An appropriat