Surface modification of alignment layer by ultraviolet irradiation to dramatically improve the detection limit of liquid-crystal-based immunoassay for the cancer biomarker CA125

Su, Hui Wen; Lee, Mon-Juan; Lee, Wei

doi:10.1117/1.jbo.20.5.057004

Cited by 32 publications

(21 citation statements)

References 45 publications

(39 reference statements)

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“…Currently, LC-based biosensing is applied in the detection of enzymatic reactions, antibody-antigen immunoreactions, DNA hybridization, and the like [1,3,4]. Our previous studies established that the sensitivity of LC-based immunodetection for the cancer biomarker CA125 can be significantly enhanced by using a eutectic nematic LC with a wide nematic range (<−30-95 °C compared with 5CB having a narrow nematic range of ~24-35 °C) and large birefringence (Δn = 0.333 at 589 nm and 20 °C) [7][8][9]. Nevertheless, present techniques based on optical texture observation are limited by the non-uniformity of LC textures, which are difficult to reproduce and hard to be quantitated.…”

Section: Introductionmentioning

confidence: 99%

Highly sensitive color-indicating and quantitative biosensor based on cholesteric liquid crystal

Hsiao

Sung

Lee

et al. 2015

Biomed. Opt. Express

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Liquid crystal (LC)-based biosensors employ highly sensitive interfaces between the alignment layers and LCs to detect biomolecules and their interactions. Present techniques based on optical texture observation of the homeotropic-to-planar response of nematic LCs are limited by their quantitative reproducibility of results, indicating that both the accuracy and reliability of LC-based detection require further improvements. Here we show that cholesteric LC (CLC) can be used as a novel sensing element in the design of an alternative LC-based biosensing device. The chirality of the vertically anchored (VA) CLC was exploited in the detection of bovine serum albumin (BSA), a protein standard commonly used in protein quantitation. The color appearance and the corresponding transmission spectrum of the cholesteric phase changed with the concentration of BSA, by which a detection limit of 1 fg/ml was observed. The optical response of the VA CLC interface offers a simple and inexpensive platform for highly sensitive and naked-eye color-indicating detection of biomolecules, and, thus, may facilitate the development of point-of-care devices for the detection of disease-related biomarkers.

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Section: Introductionmentioning

confidence: 99%

Highly sensitive color-indicating and quantitative biosensor based on cholesteric liquid crystal

Hsiao

Sung

Lee

et al. 2015

Biomed. Opt. Express

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“…To extend current technique to clinical application, BSA can be substituted for an antibody specific for a disease-related biomarker, which is then reacted with a serum sample containing the biomarker to assess the detection specificity of BPLCs, as described in our previous work on the LC-based detection of the cancer biomarker CA125 [8][9][10]. Although the process of achieving and maintaining BPs may require further simplification to enhance practical application, results from this study provide the first implications that quantitative biosensors based on BPLCs may be realized with the fast development of BP-related photonic technologies.…”

Section: Resultsmentioning

confidence: 99%

“…Moreover, TL205, a nematic LC of low cytotoxicity, served as the substrate for the imaging of human embryonic stem cells [7]. By exploiting the large birefringence of another nematic LC, HDN, we demonstrated that the increased birefringence is critical to lowering the detection limit of CA125, a cancer biomarker, in a LC-based immunoassay [8][9][10]. For biological detection with other phases of LCs, cholesteric LCs (CLCs), produced by incorporating a chiral dopant in nematic LCs, were utilized as droplets in the design of glucose and cholesterol biosensors [11].…”

Section: Introductionmentioning

confidence: 99%

Label-free protein sensing by employing blue phase liquid crystal

Lee¹,

Chang²,

Lee³

2017

Biomed. Opt. Express

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Blue phases (BPs) are mesophases existing between the isotropic and chiral nematic phases of liquid crystals (LCs). In recent years, blue phase LCs (BPLCs) have been extensively studied in the field of LC science and display technology. However, the application of BPLCs in biosensing has not been explored. In this study, a BPLC-based biosensing technology was developed for the detection and quantitation of bovine serum albumin (BSA). The sensing platform was constructed by assembling an empty cell with two glass slides coated with homeotropic alignment layers and with immobilized BSA atop. The LC cells were heated to isotropic phase and then allowed to cool down to and maintained at distinct BP temperatures for spectral measurements and texture observations. At BSA concentrations below 10 −6 g/ml, we observed that the Bragg reflection wavelength blueshifted with increasing concentration of BSA, suggesting that the BP is a potentially sensitive medium in the detection and quantitation of biomolecules. By using the BPLC at 37 °C and the same polymorphic material in the smectic A phase at 20 °C, two linear correlations were established for logarithmic BSA concentrations ranging from 10 −9 to 10 −6 g/ml and from 10

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“…The sample preparation procedure of LC-based immunological assays has multiple steps [ 79 , 80 , 81 ]. Initially, the glass slides are cleaned by immersing in detergent solution, deionized water, and finally in 99% ethanol in sequential order and in each step allowing the ultra-sonication for 15 min at room temperature.…”

Section: Liquid Crystal Based Detection Of Cancermentioning

confidence: 99%

“…In the final step, LC is filled through capillary mechanism. The LC cell optical texture is observed under a microscope in the transmitted light illumination by using crossed polarizers [ 79 , 80 , 81 ]. The fundamental mechanism behind this principle is a change in the optical texture of LCs, directly proportional to the number and type of biomolecules from the analyst source present in an LC aligning layer.…”

Section: Liquid Crystal Based Detection Of Cancermentioning

confidence: 99%

Liquid Crystals: A Novel Approach for Cancer Detection and Treatment

Vallamkondu

Corgiat

Gollapelli

et al. 2018

Cancers

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Liquid crystals are defined as the fourth state of matter forming between solid and liquid states. Earlier the applications of liquid crystals were confined to electronic instruments, but recent research findings suggest multiple applications of liquid crystals in biology and medicine. Here, the purpose of this review article is to discuss the potential biological impacts of liquid crystals in the diagnosis and prognosis of cancer along with the risk assessment. In this review, we also discussed the recent advances of liquid crystals in cancer biomarker detection and treatment in multiple cell line models. Cases reviewed here will demonstrate that cancer diagnostics based on the multidisciplinary technology and intriguingly utilization of liquid crystals may become an alternative to regular cancer detection methodologies. Additionally, we discussed the formidable challenges and problems in applying liquid crystal technologies. Solving these problems will require great effort and the way forward is through the multidisciplinary collaboration of physicists, biologists, chemists, material-scientists, clinicians, and engineers. The triumphant outcome of these liquid crystals and their applications in cancer research would be convenient testing for the detection of cancer and may result in treating the cancer patients non-invasively.

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Surface modification of alignment layer by ultraviolet irradiation to dramatically improve the detection limit of liquid-crystal-based immunoassay for the cancer biomarker CA125

Cited by 32 publications

References 45 publications

Highly sensitive color-indicating and quantitative biosensor based on cholesteric liquid crystal

Highly sensitive color-indicating and quantitative biosensor based on cholesteric liquid crystal

Label-free protein sensing by employing blue phase liquid crystal

Liquid Crystals: A Novel Approach for Cancer Detection and Treatment

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