Your search keyword '"Milyutin, Yana"' showing total 11 results

1. Fabricating and printing chemiresistors based on monolayer-capped metal nanoparticles

Author

Milyutin, Yana, Abud-Hawa, Manal, Kloper-Weidenfeld, Viki, Mansour, Elias, Broza, Yoav Y., Shani, Gidi, and Haick, Hossam

Published

2021

2. Ultra‐Fast Portable and Wearable Sensing Design for Continuous and Wide‐Spectrum Molecular Analysis and Diagnostics

Author

Maity, Arnab, primary, Milyutin, Yana, additional, Maidantchik, Vivian Darsa, additional, Pollak, Yael Hershkovitz, additional, Broza, Yoav, additional, Omar, Rawan, additional, Zheng, Youbin, additional, Saliba, Walaa, additional, Huynh, Tan‐Phat, additional, and Haick, Hossam, additional

Published

2022

3. FRET – based technique for the characterization of contour lines

Author

Milyutin, Yana, Shaham-Waldmann, Nurit, Yaron, Sima, and Paz, Yaron

Published

2012

4. A Wearable Microneedle‐Based Extended Gate Transistor for Real‐Time Detection of Sodium in Interstitial Fluids (Adv. Mater. 10/2022)

Author

Zheng, Youbin, primary, Omar, Rawan, additional, Zhang, Rongjun, additional, Tang, Ning, additional, Khatib, Muhammad, additional, Xu, Qi, additional, Milyutin, Yana, additional, Saliba, Walaa, additional, Broza, Yoav Y., additional, Wu, Weiwei, additional, Yuan, Miaomiao, additional, and Haick, Hossam, additional

Published

2022

5. Dynamics of light-induced charge transfer between carbon nanotube and CdSe/CdS core/shell nanocrystals

Author

Zeevi, Gilad, primary, Dehnel, Joanna, additional, Budniak, Adam K., additional, Milyutin, Yana, additional, Ankonina, Guy, additional, Haick, Hossam, additional, Lifshitz, Efrat, additional, and Yaish, Yuval E., additional

Published

2021

6. Stretchable and Highly Permeable Nanofibrous Sensors for Detecting Complex Human Body Motion (Adv. Mater. 41/2021)

Author

Horev, Yehu David, primary, Maity, Arnab, additional, Zheng, Youbin, additional, Milyutin, Yana, additional, Khatib, Muhammad, additional, Yuan, Miaomiao, additional, Suckeveriene, Ran Yosef, additional, Tang, Ning, additional, Wu, Weiwei, additional, and Haick, Hossam, additional

Published

2021

7. Exhaled breath diagnostics of lung and gastric cancers in China using nanosensors

Author

Gharra, Alaa, primary, Broza, Yoav Y., additional, Yu, Guiping, additional, Mao, Weidong, additional, Shen, Dong, additional, Deng, Lichun, additional, Wu, Chun, additional, Wang, Qiong, additional, Sun, Xia, additional, Huang, Jianming, additional, Xuan, Zhuoqi, additional, Huang, Bing, additional, Wu, Song, additional, Milyutin, Yana, additional, Kloper‐Weidenfeld, Viki, additional, and Haick, Hossam, additional

Published

2020

8. Time‐Resolved and Self‐Adjusting Hybrid Functional Fabric Sensor for Decoupling Multiple Stimuli from Bending

Author

Sun, Jiaxing Jeccy, primary, Zhang, Min, additional, Khatib, Muhammad, additional, Milyutin, Yana, additional, Saliba, Walaa, additional, Kloper, Viki, additional, Garaa, Alaa, additional, Wu, Weiwei, additional, Jin, Han, additional, Segev‐Bar, Meital, additional, Deng, Yunfeng, additional, Horev, Yehu David, additional, Vishinkin, Rotem, additional, and Haick, Hossam, additional

Published

2019

9. Time-space-resolved origami hierarchical electronics for ultrasensitive detection of physical and chemical stimuli

Author

Zhang, Min, primary, Sun, Jiaxing Jeccy, additional, Khatib, Muhammad, additional, Lin, Zi-Yang, additional, Chen, Zi-Han, additional, Saliba, Walaa, additional, Gharra, A’laa, additional, Horev, Yehu David, additional, Kloper, Viki, additional, Milyutin, Yana, additional, Huynh, Tan-Phat, additional, Brandon, Simon, additional, Shi, Guoyue, additional, and Haick, Hossam, additional

Published

2019

10. Sensing gastric cancer via point-of-care sensor breath analyzer.

Author

Leja, Marcis, Kortelainen, Juha M., Polaka, Inese, Turppa, Emmi, Mitrovics, Jan, Padilla, Marta, Mochalski, Pawel, Shuster, Gregory, Pohle, Roland, Kashanin, Dmitry, Klemm, Richard, Ikonen, Veikko, Mezmale, Linda, Broza, Yoav Y., Shani, Gidi, Haick, Hossam, Kloper, Viki, Milyutin, Yana, Abboud, Manal, and Saliba, Walaa

Subjects

STOMACH cancer, FISHER discriminant analysis, VOLATILE organic compounds, EARLY detection of cancer, BIOSENSORS, STOMACH tumors, RESEARCH, MEDICAL databases, INFORMATION storage & retrieval systems, RESEARCH methodology, DISCRIMINANT analysis, PHARMACOKINETICS, CASE-control method, MEDICAL cooperation, EVALUATION research, COMPARATIVE studies, CLINICAL medicine, NANOTECHNOLOGY, RESEARCH funding, BREATH tests, PRECANCEROUS conditions, EQUIPMENT & supplies

Abstract

Background: Detection of disease by means of volatile organic compounds from breath samples using sensors is an attractive approach to fast, noninvasive and inexpensive diagnostics. However, these techniques are still limited to applications within the laboratory settings. Here, we report on the development and use of a fast, portable, and IoT-connected point-of-care device (so-called, SniffPhone) to detect and classify gastric cancer to potentially provide new qualitative solutions for cancer screening.Methods: A validation study of patients with gastric cancer, patients with high-risk precancerous gastric lesions, and controls was conducted with 2 SniffPhone devices. Linear discriminant analysis (LDA) was used as a classifying model of the sensing signals obatined from the examined groups. For the testing step, an additional device was added. The study group included 274 patients: 94 with gastric cancer, 67 who were in the high-risk group, and 113 controls.Results: The results of the test set showed a clear discrimination between patients with gastric cancer and controls using the 2-device LDA model (area under the curve, 93.8%; sensitivity, 100%; specificity, 87.5%; overall accuracy, 91.1%), and acceptable results were also achieved for patients with high-risk lesions (the corresponding values for dysplasia were 84.9%, 45.2%, 87.5%, and 65.9%, respectively). The test-phase analysis showed lower accuracies, though still clinically useful.Conclusion: Our results demonstrate that a portable breath sensor device could be useful in point-of-care settings. It shows a promise for detection of gastric cancer as well as for other types of disease.Lay Summary: A portable sensor-based breath analyzer for detection of gastric cancer can be used in point-of-care settings. The results are transferrable between devices via advanced IoT technology. Both the hardware and software of the reported breath analyzer could be easily modified to enable detection and monitirng of other disease states. [ABSTRACT FROM AUTHOR]

Published

2021

11. Sensing gastric cancer via point‐of‐care sensor breath analyzer

Author

Leja, Marcis, Kortelainen, Juha M., Polaka, Inese, Turppa, Emmi, Mitrovics, Jan, Padilla, Marta, Mochalski, Pawel, Shuster, Gregory, Pohle, Roland, Kashanin, Dmitry, Klemm, Richard, Ikonen, Veikko, Mezmale, Linda, Broza, Yoav Y., Shani, Gidi, Haick, Hossam, Kloper, Viki, Milyutin, Yana, Abboud, Manal, Saliba, Walaa, Bdarneh, Shifaa, Khateb, Salam, Gharra, Alaa, Zuri, Liat, Vasiljevs, Edgars, Lauka, Lelde, Gasenko, Evita, Skapars, Roberts, Sivins, Armands, Bogdanova, Inga, Isajevs, Sergejs, Kikuste, Ilze, Vanags, Aigars, Tolmanis, Ivars, Kojalo, Ilona, Veliks, Viktors, Jaeschke, Carsten, Fleischer, Max, Sramek, Maria, nav Gils, Mark, Kulju, Minna, and Miettinen, Janika

Subjects

Adult, Male, Cancer Research, Validation study, medicine.medical_specialty, volatile organic compound, Point-of-Care Systems, Biosensing Techniques, Sensitivity and Specificity, 03 medical and health sciences, 0302 clinical medicine, SDG 3 - Good Health and Well-being, breath analyzer, Stomach Neoplasms, Cancer screening, medicine, Humans, Nanotechnology, 030212 general & internal medicine, Point of care, Aged, Aged, 80 and over, business.industry, gastric cancer, screening, Cancer, personalized, Discriminant Analysis, Gastric lesions, Middle Aged, medicine.disease, Linear discriminant analysis, precancerous lesion, 3. Good health, Breath analyzer, Oncology, Breath Tests, 030220 oncology & carcinogenesis, Area Under Curve, Case-Control Studies, Female, Radiology, Internet of Things, business, Precancerous Conditions

Abstract

Background Detection of disease by means of volatile organic compounds from breath samples using sensors is an attractive approach to fast, noninvasive and inexpensive diagnostics. However, these techniques are still limited to applications within the laboratory settings. Here, we report on the development and use of a fast, portable, and IoT-connected point-of-care device (so-called, SniffPhone) to detect and classify gastric cancer to potentially provide new qualitative solutions for cancer screening. Methods A validation study of patients with gastric cancer, patients with high-risk precancerous gastric lesions, and controls was conducted with 2 SniffPhone devices. Linear discriminant analysis (LDA) was used as a classifying model of the sensing signals obatined from the examined groups. For the testing step, an additional device was added. The study group included 274 patients: 94 with gastric cancer, 67 who were in the high-risk group, and 113 controls. Results The results of the test set showed a clear discrimination between patients with gastric cancer and controls using the 2-device LDA model (area under the curve, 93.8%; sensitivity, 100%; specificity, 87.5%; overall accuracy, 91.1%), and acceptable results were also achieved for patients with high-risk lesions (the corresponding values for dysplasia were 84.9%, 45.2%, 87.5%, and 65.9%, respectively). The test-phase analysis showed lower accuracies, though still clinically useful. Conclusion Our results demonstrate that a portable breath sensor device could be useful in point-of-care settings. It shows a promise for detection of gastric cancer as well as for other types of disease. Lay summary A portable sensor-based breath analyzer for detection of gastric cancer can be used in point-of-care settings. The results are transferrable between devices via advanced IoT technology. Both the hardware and software of the reported breath analyzer could be easily modified to enable detection and monitirng of other disease states.