A kind of ph sensor and ph value detection method based on anatase type tio2 nanoparticles
A nanoparticle and anatase-type technology, which is applied in the field of pH sensor and pH value detection based on anatase-type TiO2 nanoparticles, can solve the problems of complex detection operation and achieve high detection accuracy, simple process and stable performance Effect
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Embodiment 1
[0041] The present invention only uses ITO conductive glass as the embodiment of the conductive carrier, and uses the urease catalyzed reaction system as the embodiment of biosensing, but is not limited to the specific content of the embodiment.
[0042] The first step: commercial anatase TiO 2 The nanoparticles were uniformly dispersed in the water phase by ultrasonication for 30 minutes.
[0043] Step 2: Cut the commercialized ITO conductive glass into appropriate sizes, soak in acetone and ethanol for 2 hours each, rinse thoroughly with double-distilled water, and soak in double-distilled water for later use.
[0044] The third step: ultrasonically dispersed anatase TiO 2 The nanoparticles are drip-coated on the bottom of the ITO glass to form a 0.5cm×1cm film, which is dried at room temperature to form a flat and uniform film, which is constructed as a sensitive element of the pH sensor and stored at room temperature in the dark.
[0045] The fourth step: the constructed...
Embodiment 2
[0048] Following the experimental steps of Example 1, continue to build a biosensor capable of measuring both the pH value and the concentration of the active substance urea in the biological system.
[0049] Step 6: Modify the 0.1%wt chitosan aqueous solution on the pH sensor TiO 2 Above the nanoparticle modification area, form a 0.5cm×1cm film, dry it in a refrigerator at 4°C to form a flat and uniform film; spread 0.1M pH7.4 phosphate buffer solution with urease and 2%wt glutaraldehyde on the shell On the polysaccharide film, urease was further modified on the ITO conductive glass by amino-amino cross-linking reaction. Apply the three-electrode system mentioned in the third step to obtain a pH biosensor ( figure 2 ).
[0050] Step 7: Select a suitable supporting electrolyte. When different concentrations of substrate urea are added to the solution, the enzyme-catalyzed reaction can cause changes in the pH value of the detection environment, and the electrochemiluminescen...
Embodiment 3
[0052] The present invention only uses ITO conductive glass as the embodiment of the conductive carrier, and uses the acetylcholinesterase catalytic reaction system as the embodiment of biosensing, but is not limited to the specific content of the embodiment. Following the experimental steps of Example 1, continue to construct a biosensor capable of measuring both the pH value and the concentration of the active substance acetylcholine in the biological system.
[0053] Step 6: Modify the 0.1%wt chitosan aqueous solution on the pH sensor TiO 2 Above the nanoparticle modification area, form a 0.5cm×1cm film, dry it in a refrigerator at 4°C to form a uniform film; spread 0.1M pH7.4 phosphate buffer solution with acetylcholinesterase and 2%wt glutaraldehyde On the chitosan film, urease was further modified on the ITO conductive glass through amino-amino cross-linking reaction. Apply the three-electrode system mentioned in the third step to obtain a pH biosensor.
[0054] Step 7...
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