Hand-Held Volatilome Analyzer Based on Elastically Deformable Nanofibers

Yucel, Muge; Akın, Osman; Çayören, Mehmet; Akduman, İbrahim; Palaniappan, Alagappan; Liedberg, Bo; Hızal, Gürkan; İnci, Fatih; Yıldız, Ümit Hakan

doi:10.1021/acs.analchem.7b05187

Cited by 16 publications

(10 citation statements)

References 47 publications

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“…The fact that they can be produced in these mentioned configurations, making easier to use them for flexible, high-precision, and stable sensors. [74] Apart from these features, carbon black and carbon containing nanofibers can also be used as conductive filling material, and they can be integrated into elastic materials and fabrics. [75] Overall, carbon-based nanomaterials exhibit notable performance in flexible electronics; for instance, high optical transparency of thin films (such as 97.7% optical transparency of graphene [76] ), mechanical flexibility (tensile strength of 100-200 GPa [77] ), and adjustable metallic/semiconductor properties (e.g., the thermal conductivity of CNTs is 6600 W mK −1 , [78] the thermal conductivity and the charge-carrier mobility of graphene 5000 W mK −1 and 250 000 cm 2 Vs −1 , respectively [79] ).…”

Section: Flexible Materialsmentioning

confidence: 99%

Carbon‐Based Nanomaterials and Sensing Tools for Wearable Health Monitoring Devices

Erdem

Derin

Shirejini

et al. 2021

Adv Materials Technologies

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In this manner, sensor technologies have garnered great attention in various fields, including biomedicine, [2][3][4][5] environmental monitoring, [6][7][8][9] smart devices, [10] wearable devices, [11] automobile manufacturing [12] since the semiconductor materials and circuits have been developed. In particular, biosensors are powerful and innovative analytical tools that incorporate biological receptors to recognize biological analytes through either physical or chemical transducers. Primarily, bio-receptors are responsible for identifying and capturing target analytes, and the transducer basically translates biological and chemical information into the detectable signals, which are eventually converted into the concentration of the analyte. [13,14] Considering gold standard methods, such as enzyme-linked immunosorbent assay (ELISA) [15] and polymerase chain reaction (PCR)-based strategies, [16] biosensors mostly hold crucial features, such as i) short assay time, [17] ii) affordable tools and reagents, [18] iii) portability, [19] and iv) facile use and minimum user interpretation. [20] Nowadays, the applications of biosensors have been leveraged by the advancements of portable and miniaturized platforms. In particular, over the past years, wearable health monitoring devices have notable impact on continuous and real-time monitoring of health parameters, thereby accelerating the deployment of biosensing strategies to daily lives. Besides, non-invasive and ease-of-collecting information supports the benefits of the wearable systems for enhancing the awareness of individuals and communities. [21][22][23] The special features of the mechanically flexible and stable wearable sensors include remarkable means, such as portability, comfortability, light-weight, non-invasive, and reliable performance. To put it simply, wearable sensors are readily attached to skin or organ surfaces through an adhesive tape [24] or microneedles, [25] and because of such easy integrations, several researchers have focused on developing wearable sensors for real-time health monitoring. A wearable sensor is basically composed of some vital elements, including a flexible base material attached to the skin or an organ, a signal transfer electrode, and a biorecognition element. Recently, researchers have concentrated on creating integrated sensors that are able to measure various parameters simultaneously, such as pressure, temperature,The healthcare system has a drastic paradigm shift from centralized care to home-based and self-monitoring strategies; aiming to reach more individuals, minimize workload in hospitals, and reduce healthcare-associated expenses. Particularly, wearable technologies are garnering considerable interest by tracking physiological parameters through motion and activities, and monitoring biochemical markers from sweat, saliva, and tears. Through their integrations with sensors, microfluidics, and wireless communication systems, they allow physicians, family members, or individuals to monitor multiple parameters withou...

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Section: Flexible Materialsmentioning

confidence: 99%

Carbon‐Based Nanomaterials and Sensing Tools for Wearable Health Monitoring Devices

Erdem

Derin

Shirejini

et al. 2021

Adv Materials Technologies

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“…Healthcare systems have been in the midst of a paradigm transition from the centralized care to the point-of-care (POC) and the point-of-need (PON) settings . In the course of this revolution, sensor systems have played one of the crucial roles by not only providing powerful alternatives to current analytical tools, but also paving the way to make them in portable and easy-to-use fashions. , In particular, many sensors are well-aligned with functional and precise nanostructures to address real-world problems in biomedicine . As a classical definition, sensor systems are a kind of translator that first analyzes biological signals or interactions with target and recognition elements and, then, transfers (bio)chemical signals into an analytical entity, including electrical, mechanical, or optical signals .…”

Section: Recent Progress In Covid-19 Diagnostic Technologiesmentioning

confidence: 99%

“…In addition, microfluidics as an integrated technology has significantly improved the outcomes of many biomedical approaches, including optical biosensors for COVID-19 diagnosis through the improvements in molecular interactions between analytes and recognition elements, and also, the reductions in the thickness of the boundary layer ,− For this purpose, a biosensor was developed by combining an all-fiber optical system, a multimode fiber bioprobe, and a microfluidic chip . The detection was carried out through the Fresnel reflection mechanism coupled with an immunoassay strategy.…”

Section: Recent Progress In Covid-19 Diagnostic Technologiesmentioning

confidence: 99%

Unifying the Efforts of Medicine, Chemistry, and Engineering in Biosensing Technologies to Tackle the Challenges of the COVID-19 Pandemic

et al. 2021

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“…[32] In this review, a better understanding of cancer metastasis and point-of-care (POC) applications will be elaborated. [33][34][35][36][37] 1.1. Cancer Metastasis Metastasis is the dissemination of the cells from the initial neoplasm to distant organs; the known primary site of metastasis can or cannot affect the prognosis.…”

Section: Introductionmentioning

confidence: 99%

“…[ 32 ] In this review, a better understanding of cancer metastasis and point‐of‐care (POC) applications will be elaborated. [ 33–37 ]…”

Section: Introductionmentioning

confidence: 99%

Smart Material‐Integrated Systems for Isolation and Profiling of Rare Cancer Cells and Emboli

Sagdic

İnci

2021

Adv Eng Mater

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This review presents a broad aspect of smart material‐integrated systems for isolating and profiling rare circulating tumor cells (CTCs) and circulating tumor microemboli (CTM) to provide physiological, biological, and mechanistic insights into cancer research. In particular, CTCs/CTM have emanated as essential pieces of evidence that can reveal clonal evolution, tumor heterogeneity, and disease progression within the metastatic cascade. Morphologies, cellular compositions, and rarity of CTCs/CTM make them difficult to track and isolate for profiling distinct molecular characteristics in the case of metastatic potential. Accordingly, with the advanced‐characterization techniques, examining the aspects of the specific surface markers of CTCs/CTM, epithelial‐to‐mesenchymal (EMT), mesenchymal‐to‐epithelial (MET) transitions, and timing of tumor cell dissemination would assist us to understand cancer biology and metastatic characteristics. Existing clinical and research methods for the enrichment and isolation of these sporadic cells depend on mainly conventional methods with low‐yield and expensive features. Owing to their specialized functions and analytical performances, smart material‐based technologies hold an enormous impact not only on cell detection, but also on cell isolation for downstream analyses. Herein, the main reasons for cell isolation are discussed and the recent developments in CTCs/CTM approaches for identifying further methods and future perspectives are elaborated on.

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Hand-Held Volatilome Analyzer Based on Elastically Deformable Nanofibers

Cited by 16 publications

References 47 publications

Carbon‐Based Nanomaterials and Sensing Tools for Wearable Health Monitoring Devices

Carbon‐Based Nanomaterials and Sensing Tools for Wearable Health Monitoring Devices

Unifying the Efforts of Medicine, Chemistry, and Engineering in Biosensing Technologies to Tackle the Challenges of the COVID-19 Pandemic

Smart Material‐Integrated Systems for Isolation and Profiling of Rare Cancer Cells and Emboli

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