Urea detection in milk by urease-assisted pH-sensitive carbon
dots

Wenzhi Yin; Wenzhi Yin; Wenzhi Yin; Ye Zhang; Ye Zhang; Jiao Gu; Jiao Gu; Tingyu Wang; Tingyu Wang; Chaoqun Ma; Chaoqun Ma; Chun Zhu; Chun Zhu; Lei Li; Lei Li; Zichen Yang; Zichen Yang; Zichen Yang; Tuo Zhu; Tuo Zhu; Guoqing Chen; Guoqing Chen

doi:10.1364/AO.437787

Applied Optics
Vol. 60,
Issue 33,
pp. 10421-10428
(2021)
•https://doi.org/10.1364/AO.437787

Urea detection in milk by urease-assisted pH-sensitive carbon dots

Wenzhi Yin, Ye Zhang, Jiao Gu, Tingyu Wang, Chaoqun Ma, Chun Zhu, Lei Li, Zichen Yang, Tuo Zhu, and Guoqing Chen

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Wenzhi Yin, Ye Zhang, Jiao Gu, Tingyu Wang, Chaoqun Ma, Chun Zhu, Lei Li, Zichen Yang, Tuo Zhu, and Guoqing Chen, "Urea detection in milk by urease-assisted pH-sensitive carbon dots," Appl. Opt. 60, 10421-10428 (2021)

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Abstract

Excessive urea in milk will lead to serious health problems. To detect whether the urea concentration in milk exceeds the standard and ensure the quality of milk, it is necessary to develop detection technology for urea in milk. But it is difficult to detect urea in milk conveniently and accurately by traditional methods. To measure the concentration of urea in milk, stable green light carbon dots (CDs) were synthesized by a one-step method as a fluorescent probe. Then, 3, 5-diaminobenzoic acid was used as the precursor for CD synthesis. Experimental results showed that CDs can generate strong fluorescence when excited by light (350–450 nm). The fluorescence peak wavelength is 490 nm, and the optimum excitation wavelength is 390 nm. The fluorescence intensity of CDs has a significant change with variations of pH (pH of 6–9), and the higher the pH, the lower the fluorescence intensity. Additionally, urea can be hydrolyzed by urease to produce ammonia and carbon dioxide. Ammonia is ionized in water to produce ${{\rm OH}^ -}$, which increases the pH of the solution. After adding standard urea to milk, urease and CDs are added. The fluorescence intensity of CDs in the mixed solution decreases as the concentration of standard added urea increases. Thus the concentration of urea in milk can be calculated. The experimental results show that the CD method for detecting urea in milk has advantages of high sensitivity and wide measurement range. The linear interval is 25–500 mg/L, ${{ R}^2}$ is 0.998, and the limit of detection is 6.27 mg/L. The concentration of urea in the milk used in the experiment is 265.46 mg/L. CDs are easy to fabricate, and the advantages of the method are simple operation, no pretreatment, safety, and low cost. A new method for the detection of urea in milk was established, to the best of our knowledge, and this method can aid in food quality control.

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Methods	Real Samples	Sample Preparation	Linear Range/ $m g \cdot L^{- 1}$	LOD/ $m g \cdot L^{- 1}$	Detection Time/Min	Reference
ZnO-MWCNTs composite	Human serum	No sample preparation	100–1000	13.8	2	[22]
CuInS2 quantum dots	Human serum	Precipitated protein	12–360	6	31	[23]
Copper nanoclusters	Human serum	Ultra-filtration	15–300	0.6	45	[24]
Potentiometric biosensor	Milk	Skimmed by centrifugation	–	1.5	15–18	[4]
Infrared micro-spectroscopy	Milk	Milk and chloroform	–	780	Not explicitly given	[25]
Impedance sensor	Milk	No sample preparation	–	600	More than 35	[26]
Gold nanoparticles	Milk	Precipitated protein	1200–9000	1200	19	[11]
CDs	Milk	No sample preparation	25–500	6.27	40	This work

	LC-MS	Concentration of Urea/ $m g \cdot L^{- 1}$
CD Method/ $m g \cdot L^{- 1}$	Method/ $m g \cdot L^{- 1}$	Spiked	Measured	Recovery/%	$R S D / n = 5$ , %
265.46	259.4	150	430.27	109.87	3.73
		250	522.55	102.84	1.76
		350	596.97	94.72	1.02

Methods	Real Samples	Sample Preparation	Linear Range/ $m g \cdot L^{- 1}$	LOD/ $m g \cdot L^{- 1}$	Detection Time/Min	Reference
ZnO-MWCNTs composite	Human serum	No sample preparation	100–1000	13.8	2	[22]
CuInS2 quantum dots	Human serum	Precipitated protein	12–360	6	31	[23]
Copper nanoclusters	Human serum	Ultra-filtration	15–300	0.6	45	[24]
Potentiometric biosensor	Milk	Skimmed by centrifugation	–	1.5	15–18	[4]
Infrared micro-spectroscopy	Milk	Milk and chloroform	–	780	Not explicitly given	[25]
Impedance sensor	Milk	No sample preparation	–	600	More than 35	[26]
Gold nanoparticles	Milk	Precipitated protein	1200–9000	1200	19	[11]
CDs	Milk	No sample preparation	25–500	6.27	40	This work

	LC-MS	Concentration of Urea/ $m g \cdot L^{- 1}$
CD Method/ $m g \cdot L^{- 1}$	Method/ $m g \cdot L^{- 1}$	Spiked	Measured	Recovery/%	$R S D / n = 5$ , %
265.46	259.4	150	430.27	109.87	3.73
		250	522.55	102.84	1.76
		350	596.97	94.72	1.02

Abstract

Supplementary Material (1)

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Applied Optics