Airflow recovery from thoracic and abdominal movements using
Synchrosqueezing Transform and Locally Stationary Gaussian Process Regression
- URL: http://arxiv.org/abs/2008.04473v1
- Date: Tue, 11 Aug 2020 01:37:38 GMT
- Title: Airflow recovery from thoracic and abdominal movements using
Synchrosqueezing Transform and Locally Stationary Gaussian Process Regression
- Authors: Whitney K. Huang, Yu-Min Chung, Yu-Bo Wang, Jeff E. Mandel, and
Hau-Tieng Wu
- Abstract summary: We propose to use the nonlinear-type time-frequency analysis tool, synchrosqueezing transform, to represent the thoracic and abdominal movement signals as the features.
We show that, using a dataset that contains respiratory signals under normal sleep conditions, an accurate prediction can be achieved by fitting the proposed model in the feature space.
- Score: 6.496038875667294
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Airflow signal encodes rich information about respiratory system. While the
gold standard for measuring airflow is to use a spirometer with an occlusive
seal, this is not practical for ambulatory monitoring of patients. Advances in
sensor technology have made measurement of motion of the thorax and abdomen
feasible with small inexpensive devices, but estimation of airflow from these
time series is challenging. We propose to use the nonlinear-type time-frequency
analysis tool, synchrosqueezing transform, to properly represent the thoracic
and abdominal movement signals as the features, which are used to recover the
airflow by the locally stationary Gaussian process. We show that, using a
dataset that contains respiratory signals under normal sleep conditions, an
accurate prediction can be achieved by fitting the proposed model in the
feature space both in the intra- and inter-subject setups. We also apply our
method to a more challenging case, where subjects under general anesthesia
underwent transitions from pressure support to unassisted ventilation to
further demonstrate the utility of the proposed method.
Related papers
- The Useful Side of Motion: Using Head Motion Parameters to Correct for Respiratory Confounds in BOLD fMRI [0.4681661603096333]
Respiration induces head motion, including real and pseudo motion, which likely provides useful information about respiratory events.
Recommended notch filters mitigate respiratory-induced motion artifacts, suggesting that a bandpass filter at the respiratory frequency band isolates respiratory-induced head motion.
This study seeks to enhance the accuracy of RV estimation from resting-state BOLD-fMRI data by integrating estimated head motion parameters.
arXiv Detail & Related papers (2024-10-16T17:58:20Z) - CathFlow: Self-Supervised Segmentation of Catheters in Interventional Ultrasound Using Optical Flow and Transformers [66.15847237150909]
We introduce a self-supervised deep learning architecture to segment catheters in longitudinal ultrasound images.
The network architecture builds upon AiAReSeg, a segmentation transformer built with the Attention in Attention mechanism.
We validated our model on a test dataset, consisting of unseen synthetic data and images collected from silicon aorta phantoms.
arXiv Detail & Related papers (2024-03-21T15:13:36Z) - AiAReSeg: Catheter Detection and Segmentation in Interventional
Ultrasound using Transformers [75.20925220246689]
endovascular surgeries are performed using the golden standard of Fluoroscopy, which uses ionising radiation to visualise catheters and vasculature.
This work proposes a solution using an adaptation of a state-of-the-art machine learning transformer architecture to detect and segment catheters in axial interventional Ultrasound image sequences.
arXiv Detail & Related papers (2023-09-25T19:34:12Z) - Eulerian Phase-based Motion Magnification for High-Fidelity Vital Sign
Estimation with Radar in Clinical Settings [4.337995322608567]
We developed a complex Gabor filter-based decomposition method to amplify phases at different spatial wavelength levels to magnify motion.
We show that our proposed technique performs better than the conventional temporal FFT-based method in clinical settings.
arXiv Detail & Related papers (2022-12-03T20:52:31Z) - Fuzzy Attention Neural Network to Tackle Discontinuity in Airway
Segmentation [67.19443246236048]
Airway segmentation is crucial for the examination, diagnosis, and prognosis of lung diseases.
Some small-sized airway branches (e.g., bronchus and terminaloles) significantly aggravate the difficulty of automatic segmentation.
This paper presents an efficient method for airway segmentation, comprising a novel fuzzy attention neural network and a comprehensive loss function.
arXiv Detail & Related papers (2022-09-05T16:38:13Z) - Minute ventilation measurement using Plethysmographic Imaging and
lighting parameters [8.739176372427842]
Breathing disorders such as sleep apnea is a critical disorder that affects a large number of individuals due to the insufficient capacity of the lungs to contain/exchange oxygen and carbon dioxide to ensure that the body is in the stable state of homeostasis.
Respiratory Measurements such as minute ventilation can be used in correlation with other physiological measurements such as heart rate and heart rate variability for remote monitoring of health and detecting symptoms of such breathing related disorders.
arXiv Detail & Related papers (2022-08-29T00:42:48Z) - Machine Learning for Mechanical Ventilation Control (Extended Abstract) [52.65490904484772]
Mechanical ventilation is one of the most widely used therapies in the ICU.
We frame these as a control problem: ventilators must let air in and out of the patient's lungs according to a prescribed trajectory of airway pressure.
Our data-driven approach learns to control an invasive ventilator by training on a simulator itself trained on data collected from the ventilator.
This method outperforms popular reinforcement learning algorithms and even controls the physical ventilator more accurately and robustly than PID.
arXiv Detail & Related papers (2021-11-19T20:54:41Z) - Adaptive Low-Pass Filtering using Sliding Window Gaussian Processes [71.23286211775084]
We propose an adaptive low-pass filter based on Gaussian process regression.
We show that the estimation error of the proposed method is uniformly bounded.
arXiv Detail & Related papers (2021-11-05T17:06:59Z) - An Apparatus for the Simulation of Breathing Disorders: Physically
Meaningful Generation of Surrogate Data [24.50116388903113]
We introduce an apparatus comprising of PVC tubes and 3D printed parts as a simple yet effective method of simulating both obstructive and restrictive respiratory waveforms in healthy subjects.
Independent control over both inspiratory and expiratory resistances allows for the simulation of obstructive breathing disorders through the whole spectrum of FEV1/FVC spirometry ratios.
waveform characteristics of breathing disorders, such as a change in inspiratory duty cycle or peak flow are also observed in the waveforms resulting from use of the artificial breathing disorder simulation apparatus.
arXiv Detail & Related papers (2021-09-14T14:00:37Z) - Trans-SVNet: Accurate Phase Recognition from Surgical Videos via Hybrid
Embedding Aggregation Transformer [57.18185972461453]
We introduce for the first time in surgical workflow analysis Transformer to reconsider the ignored complementary effects of spatial and temporal features for accurate phase recognition.
Our framework is lightweight and processes the hybrid embeddings in parallel to achieve a high inference speed.
arXiv Detail & Related papers (2021-03-17T15:12:55Z) - Wearable Respiration Monitoring: Interpretable Inference with Context
and Sensor Biomarkers [5.065947993017157]
Breathing rate (BR), minute ventilation (VE), and other respiratory parameters are essential for real-time patient monitoring in many acute health conditions, such as asthma.
In this work, we infer respiratory parameters from wearable ECG and wrist motion signals.
arXiv Detail & Related papers (2020-07-02T22:12:49Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.