Quantitative Determination of Enzyme Activity in Single Cells by Scanning Microelectrode Coupled with a Nitrocellulose Film-Covered Microreactor by Means of a Scanning Electrochemical Microscope

• Published in: Analytical chemistry (Washington) Vol. 79; no. 3; pp. 1256 - 1261
• Main Authors: Zhang, Xiaoli, Sun, Fuchan, Peng, Xuewei, Jin, Wenrui
• Format: Journal Article
• Language: English
• Published: Washington, DC American Chemical Society 01.02.2007
• Subjects: Analytical chemistry; Cells - enzymology; Chemistry; Collodion; Electrochemical methods; Electrochemistry; Electrodes; Enzymes; Enzymes - analysis; Enzymes - metabolism; Exact sciences and technology; Humans; Hydrogen Peroxide - metabolism; Microelectrodes; Microscopy; Microscopy - instrumentation; Microscopy - methods; Neutrophils - enzymology; Peroxidase - analysis; Oxygen; Catalytic reaction; Hydrogen peroxide; Enzyme; Electrochemical method; Interference; Benzoquinone; Vaporization; Hydroquinone; Sample preparation; Peroxidases; Sample cell; Cellulose nitrate; Standard curve; Microelectrode; Microreactor; Peroxidase; Oxidoreductases; Electrochemical reaction; Quantitative analysis
• ISSN: 0003-2700; 1520-6882
• DOI: 10.1021/ac061450y

An electrochemical method for quantitative determination of enzyme activity in single cells was developed by scanning a microelectrode (ME) over a nitrocellulose film-covered microreactor with micropores by means of a scanning electrochemical microscope (SECM). Peroxidase (PO) in neutrophils was chosen as the model system. The microreactor consisted of a microwell with a solution and a nitrocellulose film with micropores. A single cell perforated by digitonin was injected into the microwell. After the perforated cell was lysed and allowed to dry, physiological buffer saline (PBS) containing hydroquinone (H2Q) and H2O2 as substrates of the enzyme-catalyzed reaction was added in the microwell. The microwell containing the extract of the lysed cell and the enzyme substrates was covered with Parafilm to prevent evaporation. The solution in the microwell was incubated for 20 min. In this case, the released PO from the cell converted H2Q into benzoquinone (BQ). Then, the Parafilm was replaced by a nitrocellulose film with micropores to fabricate the microreactor. The microreactor was placed in an electrochemical cell containing PBS, H2Q, and H2O2. After a 10-μm-radius Au ME was inserted into the electrochemical cell and approached down to the microreactor, the ME was scanned along the central line across the microreactor by means of a SECM. The scan curve with a peak was obtained by detecting BQ that diffused out from the microreactor through the micropores on the nitrocellulose film. PO activity could be quantified on the basis of the peak current on the scan curve using a calibration curve. This method had two obvious advantages:  no electrode fouling and no oxygen interference.