Sugar detection using drop evaporation

Yixiao Qu; Zhengyuan Ma; Min Zhang; Xing Huang; Lujia Xuan; Rui Ding; Wenya Liao; Zhiqiang Wu; Yihe Lin; Kami Hu; Zheng Liu; Ruoyang Chen; Hui He

doi:10.1002/dro2.150

Droplet ›› 2025, Vol. 4 ›› Issue (1) : e150 DOI: 10.1002/dro2.150

RESEARCH ARTICLE

Sugar detection using drop evaporation

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Abstract

Evaporation deposition of a spilt sugary drop on the supporting surface can attract ants to surround it. People have a long history of using this phenomenon as an implication of sugar in the drop. Unfortunately, it is hard to detect sugar concentration and has to depend exclusively on ants.Here,weshow a facile strategy for the eye-naked detection on sugar concentrations in common liquid mixtures, based on their evaporation depositions. Our experiments show that evaporation drops without any sugar form clear ring-like depositions, and the width of the ring area enlarges with the increase in sugar concentration.We demonstrate that the increase in sugar concentration can increase the liquid viscosity and decrease the capillary flow velocity, thus weakening the “coffee ring” effect. Our further experiments indicate that the temperature has insignificant effects on the correlation between sugar concentrations and ring-like depositions, but the substrate wettability impacts on the correlation by promoting the formation of ring-like depositions. Based on themechanism study,we develop a strategy for detecting sugar concentrations via quantitatively correlating them with the width of the ring area, and demonstrate that it is valid for various liquid mixtures, for example, carbonate beverage, liquid medicine, and plant nutrient. Our findings not only present new insights into the understanding of the sugary drop evaporation, but also provide a facile strategy of detecting sugar concentration that promises great applications in food safety, pharmaceutical detection, and agricultural productmeasurements.

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Yixiao Qu, Zhengyuan Ma, Min Zhang, Xing Huang, Lujia Xuan, Rui Ding, Wenya Liao, Zhiqiang Wu, Yihe Lin, Kami Hu, Zheng Liu, Ruoyang Chen, Hui He. Sugar detection using drop evaporation. Droplet, 2025, 4(1): e150 DOI:10.1002/dro2.150

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References

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[1]	Xie L, Ye X, Liu D, Ying Y. Quantification of glucose, fructose and sucrose in bayberry juice by NIR and PLS. Food Chem. 2009;114:1135-1140.

[2]	Galant AL, Kaufman RC, Wilson JD. Glucose: detection and analysis. Food Chem. 2015;188:149-160.

[3]	Wijayanti SD, Schachinger F, Ludwig R, Haltrich D. Electrochemical and biosensing properties of an FAD-dependent glucose dehydrogenase from Trichoderma virens. Bioelectrochemistry. 2023;153:108480.

[4]	Kang X, Wang J, Wu H, Aksay IA, Liu J, Lin Y. Glucose oxidase-graphene-chitosan modified electrode for direct electrochemistry and glucose sensing. Biosens Bioelectron. 2009;25:901-905.

[5]	Gao H, Xiao F, Ching CB, Duan H. One-step electrochemical synthesis of PtNi nanoparticle-graphene nanocomposites for nonenzymatic amperometric glucose detection. ACS Appl Mater Interfaces. 2011;3:3049-3057.

[6]	Wang Q, Kaminska I, Niedziolka-Jonsson J, et al. Sensitive sugar detection using 4-aminophenylboronic acid modified graphene. Biosens Bioelectron. 2013;50:331-337.

[7]	Jimenez MJM, Jaramillo-Botero A, Avila A. Au-NP-based colorimetric assay for sugar detection and quantification. Sens Actuators Rep. 2023;6:100171.

[8]	Bruen D, Delaney C, Diamond D, Florea L. Fluorescent probes for sugar detection. ACS Appl Mater Interfaces. 2018;10:38431-38437.

[9]	Wu X, Li Z, Chen X, Fossey JS, James TD, Jiang Y. Selective sensing of saccharides using simple boronic acids and their aggregates. Chem Soc Rev. 2013;42:8032-8048.

[10]	Sun X, James TD. Glucose sensing in supramolecular chemistry. Chem Rev. 2015;115:8001-8037.

[11]	Monteux C, Lequeux F. Packing and sorting colloids at the contact line of a drying drop. Langmuir. 2011;27:2917-2922.

[12]	Noguera-Marin D, Moraila-Martinez CL, Cabrerizo-Vilchez MA, Rodriguez-Valverde MA. Particle segregation at contact lines of evaporating colloidal drops: influence of the substrate wettability and particle charge-mass ratio. Langmuir. 2015;31:6632-6638.

[13]	Wong TS, Chen TH, Shen X, Ho CM. Nanochromatography driven by the coffee ring effect. Anal Chem. 2011;83:1871-1873.

[14]	Layani M, Gruchko M, Milo O, Balberg I, Azulay D, Magdassi S. Transparent conductive coatings by printing coffee ring arrays obtained at room temperature. ACS Nano. 2009;3:3537-3542.

[15]	Wen JT, Ho CM, Lillehoj PB. Coffee ring aptasensor for rapid protein detection. Langmuir. 2013;29:8440-8446.

[16]	Cao R, Pan Z, Tang H, et al. Understanding the coffee-ring effect of red blood cells for engineering paper-based blood analysis devices. Chem Eng J. 2020;391:123522.

[17]	Gulka CP, Swartz JD, Trantum JR, et al. Coffee rings as low-resource diagnostics: detection of the malaria biomarker Plasmodium falciparum histidine-rich protein-II using a surface-coupled ring of Ni(II)NTA gold-plated polystyrene particles. ACS Appl Mater Interfaces. 2014;6:6257-6263.

[18]	Xu J, Du J, Jing C, Zhang Y, Cui J. Facile detection of polycyclic aromatic hydrocarbons by a surface-enhanced Raman scattering sensor based on the Au coffee ring effect. ACS Appl Mater Interfaces. 2014;6:6891-6897.

[19]	Hong Y, Li Y, Huang L, et al. Label-free diagnosis for colorectal cancer through coffee ring-assisted surface-enhanced Raman spectroscopy on blood serum. J Biophotonics. 2020;13:e201960176.

[20]	Deegan RD, Bakajin O, Dupont TF, Huber G, Nagel SR, Witten TA. Capillary flow as the cause of ring stains from dried liquid drops. Nature. 1997;389:827-829.

[21]	Wilson SK, D’Ambrosio HM. Evaporation of sessile droplets. Annu Rev Fluid Mech. 2023;55:481-509.

[22]	Kim DO, Pack M, Hu H, Kim H, Sun Y. Deposition of colloidal drops containing ellipsoidal particles: competition between capillary and hydrodynamic forces. Langmuir. 2016;32:11899-11906.

[23]	Yunker PJ, Still T, Lohr MA, Yodh AG. Suppression of the coffee-ring effect by shape-dependent capillary interactions. Nature. 2011;476:308-311.

[24]	Du Z, Zhou H, Yu X, Han Y. Controlling the polarity and viscosity of small molecule ink to suppress the contact line receding and coffee ring effect during inkjet printing. Colloids Surf A. 2020;602:125111.