Gold Nanoparticle-Based Electrode Marks Breakthrough in Urinalysis Disease Detection Methodology

By LabMedica International staff writers
Posted on 25 Feb 2022

Image: Electroanalytical technique uses gold-containing ternary nanocomposites (Photo courtesy of Unsplash)

Using gold-containing ternary nanocomposites, researchers have developed a novel electroanalytical technique with key diagnostic implications.

The novel electroanalytical technique developed by researchers at Xi'an Jiaotong University (Xi'an, China) permits the co-detection of dopamine (DA) and uric acid (UA) in urine samples even in the presence of ascorbic acid (AA). Urinalysis, or the detection and estimation of various pathophysiological substances in urine samples, is routinely recommended for disease diagnosis. Increased levels of UA, for instance, may indicate underlying kidney or heart disease. Similarly, an increase in the urinary levels of dopamine DA may indicate the presence of neurological disorders like neuroblastoma or Parkinson's disease. Because pathology labs need to simultaneously determine the urinary levels of multiple substances, techniques that permit such co-detection are necessary. However, such co-analyses sometimes present with technical hurdles. In the case of urine samples, the relatively higher concentrations of AA in urine interferes with the simultaneous detection of DA and UA, both of which are present at relatively lower levels.

To resolve this challenge, the researchers combined a nanocomposite mixture, which had an average grain size of 10-9 meters or more, made up of gold nanoparticles (AuNPs), a special (conducting) polymer, and electrochemically-treated graphene oxide over a conventional glassy carbon electrode (GCE), to get a superior electrode. A GCE combines the properties of glass with those of graphite. However, it needed to be modified for the selective and simultaneous detection of DA and UA in the presence of high concentrations of AA. The researchers employed a combination of chemical and electrochemical methods. They started with poly(3,4-ethylenedioxythiophene), or PEDOT, which is a highly conductive polymer with much promise in the field of biosensors.

The PEDOT-AuNPs were chemically synthesized from chloroauric acid and 3,4-ethylenedioxythiophene at room temperature. The addition of graphene oxide (GO) resulted in the formation of a homogeneous suspension of PEDOT-AuNPs-GO. This suspension was then dropped onto the surface of a GCE and dried. Finally, following an electrochemical procedure, the nanomaterial OPEDOT-AuNPs-ERGO/GCE was successfully fabricated and readied for bioanalytical measurements. When used, the modified electrode could simultaneously detect extremely tiny amounts of DA (1 mM) and UA (5 mM) under physiological conditions, even in the presence of a large excess (1.0 mM) of AA. The research team foresees a bright future for this novel nanomaterial-based application, especially in clinical and diagnostic setups. Future studies are certainly required, but this novel nanocomposite electrode has strong potential to become the gold standard for diagnostics in pathology laboratories.

"PEDOT can be overoxidized to obtain OPEDOT, whose hydrophilicity and unique properties make it useful in electroanalytical applications," said Associate Professor Dongdong Zhang of Xi'an Jiaotong University who led the research team. "However, since OPEDOT is not as good an electrical conductor or catalyst, it is modified with suitable nanomaterials, in this case, gold nanoparticles."

"Our novel, graphene-based, ternary composite, with its advantageous features, is a promising candidate for electroanalytical and clinical applications," added Dr. Zhang.

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Xi'an Jiaotong University