Here, we describe a protocol for the preparation of quantum dot nanobeads (QDNB) and the detection of disease biomarkers using QDNB-based lateral flow immunoassay strips. The test results can be qualitatively assessed under UV light illumination and quantitatively measured using a fluorescent strip reader within 15 min.
Quantum dots, also known as semiconductor nanocrystals, are novel fluorescent labels for biological imaging and sensing. However, quantum dot-antibody conjugates with small dimensions (~10 nm), prepared through laborious purification procedures, exhibit limited sensitivity in detecting certain trace disease markers using lateral flow immunoassay strips. Herein, we present a method for the preparation of quantum dot nanobeads (QDNB) using a one-step emulsion evaporation method. Using the as-prepared QDNB, a fluorescent lateral flow immunoassay was fabricated to detect disease biomarkers using C-reactive protein (CRP) as an example. Unlike single quantum dot nanoparticles, quantum dot nanobead-antibody conjugates are more sensitive as immunoassay labels due to signal amplification by encapsulating hundreds of quantum dots in one polymer composite nanobead. Moreover, the larger size of QDNBs facilitates easier centrifugation separation when conjugating QDNBs with antibodies. The fluorescent lateral flow immunoassay based on QDNBs was fabricated, and the CRP concentration in the sample was measured in 15 min. The test results can be qualitatively assessed under UV light illumination and quantitatively measured using a fluorescent reader within 15 min.
Lateral flow immunoassay (LFIA) strips serve as crucial rapid detection tools at point-of-care1,2, particularly in disease screening during epidemics. However, traditional colloidal gold-based LFIA test strips exhibit low detection sensitivity and only provide qualitative results3. To enhance the detection sensitivity of LFIA, various new nanoparticles have emerged, including colored latex4,5, upconversion fluorescent nanoparticles6, time-resolved fluorescent microspheres7,8, and quantum dots9,10,11. Quantum dots (QDs)12,13, also known as semiconductor nanocrystals, offer tunable emission wavelengths, a wide excitation range, and high luminescence efficiency, making them ideal labels for biological imaging.
However, the fluorescence signal emitted by individual quantum dots remains weak, resulting in relatively low detection sensitivity in immunoassays. Encapsulation of numerous quantum dots within microspheres can amplify signals and improve the sensitivity of quantum dot-based immunoassays. Various methods, such as layer-by-layer self-assembly14,15,16,17,18, the swelling method19,20, and silica microsphere21,22,23,24 encapsulation, have been employed to encapsulate quantum dots inside microspheres. For example, quantum dot-functionalized silica nanosphere labels can be achieved by increasing QD loading per sandwiched immunoreaction25. A spray dryer equipped with an ultrasonic atomizer has also been used to prepare nanoscale QD-BSA nanospheres26. However, the aforementioned methods suffer from complex multi-steps, fluorescence quenching, and low productivity.
In our previous work27, an emulsion-solvent evaporation method for encapsulating quantum dots inside polymer nanobeads was reported. This preparation technique is simple, maintains the fluorescent efficiency of QDs, ensures high encapsulation efficiency, and allows for easy scalable production. Several research groups have successfully developed LFIA strips using QDNBs prepared through this method for applications, including food toxin detection28,29,30, infectious disease biomarker detection31,32, and environmental monitoring33.
This protocol presents specific preparation steps for quantum dot nanobeads (QDNB), QDNB and antibody conjugation, preparation of QDNB-based LFIA, and measurement of C-reactive protein (CRP) in human plasma samples.
Here, we describe a protocol for the preparation of quantum dot nanobeads (QDNB)27 and the use of QDNB for the preparation of fluorescent lateral flow immunoassays (LFIA). The qualitative and quantitative measurement of CRP in samples is demonstrated. This QDNB-based LFIA can also be applied to other disease biomarkers25,32, food toxins29,30, viruses16,…
The authors have nothing to disclose.
This work was supported by the Project of Shanghai Science and Technology Committee (STCSM) (22S31902000) and the Clinical Research Incubation Program of Shanghai Skin Disease Hospital (NO. lcfy2021-10).
(dimethylamino)propyl)-N’-ethylcarbodiimide hydrochloride | Sigma-Aldrich | 03450 | |
Absorbance paper | Kinbio Biotech | CH37K | |
Bovine serum albumin | Sigma-Aldrich | B2064 | |
Casein | Sigma-Aldrich | C8654 | |
CdSe/ZnS quantum dot | Suzhou Mesolight Inc. | CdSe/ZnS-625 | |
Choloroform | Sino Pharm | 10006818 | |
CRP antibody | Hytest Biotech | 4C28 | |
Fluorescent lateral flow assay reader | Suzhou Helmence Precision Instrument | FIC-H1 | |
Glass fiber pad | Kinbio Biotech | SB06 | |
Goat anti-rabbit IgG | Sangon Biotech | D111018 | |
Nitrocellulose membrane | Satorious | CN140 | |
Poly(styrene-maleic anhydride) copolymer | Sigma-Aldrich | S458066 | |
Rabbit IgG | Sangon Biotech | D110502 | |
Sodium dodecyl sulfate | Sino Pharm | 30166428 | |
Sodium hydroxide | Sino Pharm | 10019718 |
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