Screening and multiple detection of cancer exosomes using an SERS-based method

Wang, Zhile; Zong, Shenfei; Wang, Yujie; Li, Na; Li, Lang; Ju, Lu; Wang, Zhuyuan; Chen, Baoan; Cui, Yiping

doi:10.1039/c7nr09162a

Cited by 219 publications

(156 citation statements)

References 46 publications

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“…The improvement provided by Wang et al consists in including magnetic properties along with the plasmonic ones, facilitating the process of separation of the analyte from the whole sample. They developed a method based on an exosomal capturing probe based on a gold shell magnetic nanostructure with antibodies against surface protein CD63 and a detecting probe consisting in AuNPs functionalized with aptamers/Raman probes (Aptamer H2/DTNB, aptamer CEA/MMC, and aptamer PSMA/2NAT), for breast cancer, colorectal cancer, and prostate cancer, respectively [41]. After adding a known concentration of capturing and detection probes to blood samples, the immunocomplex takes place, and magnetic beads are collected with a magnet.…”

Section: Encoded-sersmentioning

confidence: 99%

Cancer Diagnosis through SERS and Other Related Techniques

Blanco-Formoso

Alvarez-Puebla

2020

IJMS

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Cancer heterogeneity increasingly requires ultrasensitive techniques that allow early diagnosis for personalized treatment. In addition, they should preferably be non-invasive tools that do not damage surrounding tissues or contribute to body toxicity. In this context, liquid biopsy of biological samples such as urine, blood, or saliva represents an ideal approximation of what is happening in real time in the affected tissues. Plasmonic nanoparticles are emerging as an alternative or complement to current diagnostic techniques, being able to detect and quantify novel biomarkers such as specific peptides and proteins, microRNA, circulating tumor DNA and cells, and exosomes. Here, we review the latest ideas focusing on the use of plasmonic nanoparticles in coded and label-free surface-enhanced Raman scattering (SERS) spectroscopy. Moreover, surface plasmon resonance (SPR) spectroscopy, colorimetric assays, dynamic light scattering (DLS) spectroscopy, mass spectrometry or total internal reflection fluorescence (TIRF) microscopy among others are briefly examined in order to highlight the potential and versatility of plasmonics.

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Section: Encoded-sersmentioning

confidence: 99%

Cancer Diagnosis through SERS and Other Related Techniques

Blanco-Formoso

Alvarez-Puebla

2020

IJMS

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“…The magnetic properties of magnetic nanobeads covered by a Au shell have been exploited for both exosome separation and particle aggregation (to generate hot spots) during SERS detection. 344 If the exosomes were dried prior to analysis, additional SERS peaks developed as a consequence of the rupture of the vesicle membranes, exposing the internal content of the exosome. 345 Alternatively, different types of assays have targeted surface antigens to quantify and characterize exosomes, since surface proteins are fundamental for the vesicle biological functions and can provide tumor fingerprints.…”

Section: Exosomesmentioning

confidence: 99%

Sensing of circulating cancer biomarkers with metal nanoparticles

Pallares

Thanh

2019

Nanoscale

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“…The label free detection capability of the SERS approach provided highly selective and multiplexed quantification of exosomes with desirable efficiency. In this context, the feasibility of the SERS‐based immunoassay for multiplexed detection of cancer specific exosomes was reported recently . Specifically, three different SERS nanoprobes were prepared by combining Au NPs with aptamer H2, aptamer CEA, and aptamer PSMA ( Figure ).…”

Section: Nanomaterial‐based Cancer Sensing Systemsmentioning

confidence: 99%

“…The multiplex capability in the aptaimmunocomplex is generated by using specific aptamers, which specifically bind to three different kinds of RMs (5,5′‐dithiobis(2‐nitrobenzoic acid), 7‐mercapto‐4‐methylcoumarin (MMC), and 2‐naphthalenethiol). Reproduced with permission . Copyright 2018, The Royal Society of Chemistry.…”

Section: Nanomaterial‐based Cancer Sensing Systemsmentioning

confidence: 99%

Advanced Functional Structure‐Based Sensing and Imaging Strategies for Cancer Detection: Possibilities, Opportunities, Challenges, and Prospects

Kumar

Kukkar

Hashemi

et al. 2019

Adv Funct Materials

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Cancer is the second most common cause of death in the world. The principal limitations thus far encountered in the clinical practice of probing cancer are diverse and include low sensitivity, time consumption, bulkiness, and cost. In this respect, nanomaterial (NM)-based sensing techniques are recognized as a superior alternative to efficiently resolve such limitations. A better understanding of NM-based sensing platforms is thus important so that these novel avenues can easily be explored for clinical applications. These platforms have the merits of high sensitivity, high specificity, rapid response, and easy-to-read signals. This review offers a comprehensive survey of NM-based advanced cancer-sensing techniques and will help the scientific community establish optimum sensing strategies based on an accurate assessment of the interactions between cancer biomarkers and NM-based platforms.but are not limited to, carcinoma, sarcoma, leukemia, lymphoma, non-Hodgkin lymphoma, myeloma, central nervous system cancer, lung and bronchus cancer, colon cancer, rectum cancer, prostate cancer, bladder cancer, kidney and renal pelvis cancer, endometrial cancer, pancreatic cancer, liver cancer, and thyroid cancers. [1] Moreover, the most commonly occurring cancers tend to differ by common criteria like sex and age. For example, men are at risk for prostate, lung, and colorectal cancer, women are at risk for breast, lung and colorectal cancer, and children are at risk for leukemia, brain tumors, and lymphoma. The severity of the cancer depends upon the development level or staging of the disease. [2] Likewise, the type of treatment required to treat the cancer is determined by the staging of the disease.The more severe condition of cancer is metastasis, i.e., the uncontrolled growth of cells that invade surrounding tissues. The metastasis condition of cancer can affect any organ of the body. [3] As per the WHO 2010 report on cancer, the lives of 30% patients could have been saved if the cancer was diagnosed earlier. The detection of cancer is not easy because the immune system does not necessarily consider cancerous cells as foreign bodies. However, a few changes (such as altered biomarker levels and the presence of cancerous cells in biological fluids) can be detected. [4] In general, cancer biomarkers are overexpressed proteins present in blood/serum and at the cancer cell surface. The accurate and efficient detection of these biomarkers can be useful for cancer detection. The major problem with biomarkers is their low level in the body during the earlier stages of cancer. Hence, an efficient sensor/device capable of detecting these molecules even at very low levels, if developed, could help the clinician efficiently diagnose cancer cells in the human body.The sensing techniques presently used by clinicians suffer from several limitations; specifically, they are time consuming, bulky, have low sensitivity, and are expensive. Nanomaterial (NM)-based techniques have become an important alternative to the laborious conventional...

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Screening and multiple detection of cancer exosomes using an SERS-based method

Cited by 219 publications

References 46 publications

Cancer Diagnosis through SERS and Other Related Techniques

Cancer Diagnosis through SERS and Other Related Techniques

Sensing of circulating cancer biomarkers with metal nanoparticles

Advanced Functional Structure‐Based Sensing and Imaging Strategies for Cancer Detection: Possibilities, Opportunities, Challenges, and Prospects

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