Medical Smart Textiles Based on Fiber Optic Technology:  An Overview

Massaroni, Carlo; Saccomandi, Paola; Schena, Emiliano

doi:10.3390/jfb6020204

Cited by 147 publications

(96 citation statements)

References 70 publications

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“…By focusing on force sensors, we introduce different sensing principles and compare the advantages and disadvantages of each sensor for an in-depth review and intuitive introduction for developers and practitioners considering the addition of force feedback for MRI interventions and rehabilitations. These basic principles can be extended for fiber optic sensing of a plural of parameters beyond forces, including pressure, temperature, shape, vibration [11], physiological parameters [12], textile based wearable devices [13], [14], etc. Thanks to the temperature sensing capability of fiber optic sensors, they have been used for temperature monitoring during thermal treatments [15], including radiofrequency ablation, laser ablation, microwave ablation, high intensity focused ultrasound ablation, and cryoablation.…”

Section: Introductionmentioning

confidence: 99%

Fiber-Optic Force Sensors for MRI-Guided Interventions and Rehabilitation: A Review

Iordachita

Tokuda

et al. 2017

IEEE Sensors J.

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Magnetic Resonance Imaging (MRI) provides both anatomical imaging with excellent soft tissue contrast and functional MRI imaging (fMRI) of physiological parameters. The last two decades have witnessed the manifestation of increased interest in MRI-guided minimally invasive intervention procedures and fMRI for rehabilitation and neuroscience research. Accompanying the aspiration to utilize MRI to provide imaging feedback during interventions and brain activity for neuroscience study, there is an accumulated effort to utilize force sensors compatible with the MRI environment to meet the growing demand of these procedures, with the goal of enhanced interventional safety and accuracy, improved efficacy and rehabilitation outcome. This paper summarizes the fundamental principles, the state of the art development and challenges of fiber optic force sensors for MRI-guided interventions and rehabilitation. It provides an overview of MRI-compatible fiber optic force sensors based on different sensing principles, including light intensity modulation, wavelength modulation, and phase modulation. Extensive design prototypes are reviewed to illustrate the detailed implementation of these principles. Advantages and disadvantages of the sensor designs are compared and analyzed. A perspective on the future development of fiber optic sensors is also presented which may have additional broad clinical applications. Future surgical interventions or rehabilitation will rely on intelligent force sensors to provide situational awareness to augment or complement human perception in these procedures.

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Section: Introductionmentioning

confidence: 99%

Fiber-Optic Force Sensors for MRI-Guided Interventions and Rehabilitation: A Review

Iordachita

Tokuda

et al. 2017

IEEE Sensors J.

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“…In [8], the authors developed an unobtrusive way to obtain ICG through textile integration. There is also an increased interest in optical fiber sensors and their integration into smart textiles for non-invasive monitoring of cardiac parameters [12], [13]. However, a more convenient way that would allow users to wear their standard clothing and still be able to obtain continuous PEP measurements is still needed.…”

Section: Introductionmentioning

confidence: 99%

Automatic Detection of Seismocardiogram Sensor Misplacement for Robust Pre-Ejection Period Estimation in Unsupervised Settings

Ashouri

Inan

2017

IEEE Sensors J.

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Seismocardiography (SCG), the measurement of the local chest vibrations due to the movements of blood and the heart, is a non-invasive technique for assessing myocardial contractility via the pre-ejection period (PEP). Recently, SCG-based extraction of PEP has been shown to be an effective means of classifying decompensated from compensated heart failure patients, and thus can be potentially used for monitoring such patients at home. Accurate extraction of PEP from SCG signals hinges on lab-based population data (i.e., regression curves) linking particular time-domain features of the SCG signal to corresponding features from reference standard bulky instruments such as impedance cardiography (ICG). Such regression curves, in the case of SCG, have always been estimated based on the “ideal” positioning of the SCG sensor on the chest. However, in settings such as the home where users may position the SCG measurement hardware on the chest without supervision, it is likely that the sensor will not always be placed exactly on this “ideal” location on the sternum, but rather on other positions on the chest as well. In this study, we show for the first time that the regression curve for estimating PEP from SCG signals differs significantly as the position of the sensor changes. We further devise a method to automatically detect when the sensor is placed in any position other than the desired one in order to avoid inaccurate systolic time interval estimation. Our classification algorithm for this purpose resulted in 0.83 precision and 0.82 recall when classifying whether the sensor is placed in the desired position or not. The classifier was tested with heartbeats taken both at rest, and also during exercise recovery to ensure that waveform changes due to positioning could be accurately discriminated from those due to physiological effects.

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“…The response time of the demodulation system will be affected, which is important for most applications that need dynamic, real-time measurements. Such applications include health monitoring of different structures such as floating structures (aircraft fuselage or ship's hull) or for the measurement of mechanical parameters with FBGs embedded in artificial skins, or for medical applications [9,10,11].…”

Section: Introductionmentioning

confidence: 99%

A novel algorithm based on DFB tunable laser array for demodulation of FBG sensors

Guo

Yao

et al. 2017

IEICE Electron. Express

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In this paper, a high effective demodulate algorithm based on tunable four-channel DFB (Distributed Feedback) laser array is proposed. In comparison with common algorithms which can work correctly when tunable laser have to be rapidly tuned through FBG's (Fiber Bragg Grating) whole spectrum, the algorithm is unique in that accurate demodulation can be done by scanning only 0.4 nm bandwidth of FBG's reflected spectrum and the scanned spectrum can be any part of the whole FBG spectrum including those regions with relatively low power. Therefore, the laser tuning time and response time of demodulation system is much more reduced which is important for most applications that need dynamic, real-time measurements. Wavelength-division multiplexing for FBG sensing network will be supported by the demodulating system and algorithm. Based on strain experiments of the FBG sensing system, excellent demodulation accuracy were demonstrated by the proposed algorithm.

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Medical Smart Textiles Based on Fiber Optic Technology: An Overview

Cited by 147 publications

References 70 publications

Fiber-Optic Force Sensors for MRI-Guided Interventions and Rehabilitation: A Review

Fiber-Optic Force Sensors for MRI-Guided Interventions and Rehabilitation: A Review

Automatic Detection of Seismocardiogram Sensor Misplacement for Robust Pre-Ejection Period Estimation in Unsupervised Settings

A novel algorithm based on DFB tunable laser array for demodulation of FBG sensors

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