Your search keyword '"Shyamnath Gollakota"' showing total 12 results

1. A Low-power wearable acoustic device for accurate invasive arterial pressure monitoring

Author

Maruchi Kim, Anran Wang, Srdjan Jelacic, Andrew Bowdle, Shyamnath Gollakota, and Kelly Michaelsen

Subjects

Medicine

Abstract

Abstract Background Millions of catheters for invasive arterial pressure monitoring are placed annually in intensive care units, emergency rooms, and operating rooms to guide medical treatment decision-making. Accurate assessment of arterial blood pressure requires an IV pole-attached pressure transducer placed at the same height as a reference point on the patient’s body, typically, the heart. Every time a patient moves, or the bed is adjusted, a nurse or physician must adjust the height of the pressure transducer. There are no alarms to indicate a discrepancy between the patient and transducer height, leading to inaccurate blood pressure measurements. Methods We present a low-power wireless wearable tracking device that uses inaudible acoustic signals emitted from a speaker array to automatically compute height changes and correct the mean arterial blood pressure. Performance of this device was tested in 26 patients with arterial lines in place. Results Our system calculates the mean arterial pressure with a bias of 0.19, inter-class correlation coefficients of 0.959 and a median difference of 1.6 mmHg when compared to clinical invasive arterial measurements. Conclusions Given the increased workload demands on nurses and physicians, our proof-of concept technology may improve accuracy of pressure measurements and reduce the task burden for medical staff by automating a task that previously required manual manipulation and close patient surveillance.

Published

2023

2. Performing tympanometry using smartphones

Author

Justin Chan, Ali Najafi, Mallory Baker, Julie Kinsman, Lisa R. Mancl, Susan Norton, Randall Bly, and Shyamnath Gollakota

Subjects

Medicine

Abstract

Chan et al. develop an open-source smartphone-based tympanometer to evaluate middle ear function. The authors test their device in a group of paediatric patients at an audiology clinic and report a high level of agreement in audiologists’ classification of tympanograms produced using this device compared with a commercial device.

Published

2022

3. Closed-loop wearable naloxone injector system

Author

Justin Chan, Vikram Iyer, Anran Wang, Alexander Lyness, Preetma Kooner, Jacob Sunshine, and Shyamnath Gollakota

Subjects

Medicine, Science

Abstract

Abstract Overdoses from non-medical use of opioids can lead to hypoxemic/hypercarbic respiratory failure, cardiac arrest, and death when left untreated. Opioid toxicity is readily reversed with naloxone, a competitive antagonist that can restore respiration. However, there remains a critical need for technologies to administer naloxone in the event of unwitnessed overdose events. We report a closed-loop wearable injector system that measures respiration and apneic motion associated with an opioid overdose event using a pair of on-body accelerometers, and administers naloxone subcutaneously upon detection of an apnea. Our proof-of-concept system has been evaluated in two environments: (i) an approved supervised injection facility (SIF) where people self-inject opioids under medical supervision and (ii) a hospital environment where we simulate opioid-induced apneas in healthy participants. In the SIF (n = 25), our system identified breathing rate and post-injection respiratory depression accurately when compared to a respiratory belt. In the hospital, our algorithm identified simulated apneic events and successfully injected participants with 1.2 mg of naloxone. Naloxone delivery was verified by intravenous blood draw post-injection for all participants. A closed-loop naloxone injector system has the potential to complement existing evidence-based harm reduction strategies and, in the absence of bystanders, help make opioid toxicity events functionally witnessed and in turn more likely to be successfully resuscitated.

Published

2021

4. Closed-loop wearable naloxone injector system

Author

Jacob E. Sunshine, Preetma Kooner, Shyamnath Gollakota, Wang Anran, Alexander Lyness, Vikram Iyer, and Justin Chan

Subjects

Harm reduction, Public health, Multidisciplinary, Respiratory rate, business.industry, Science, Apnea, Opioid overdose, medicine.disease, Article, Electrical and electronic engineering, Opioid, Respiratory failure, Naloxone, Anesthesia, medicine, Medicine, medicine.symptom, Respiratory system, business, Biomedical engineering, medicine.drug

Abstract

Overdoses from non-medical use of opioids can lead to hypoxemic/hypercarbic respiratory failure, cardiac arrest, and death when left untreated. Opioid toxicity is readily reversed with naloxone, a competitive antagonist that can restore respiration. However, there remains a critical need for technologies to administer naloxone in the event of unwitnessed overdose events. We report a closed-loop wearable injector system that measures respiration and apneic motion associated with an opioid overdose event using a pair of on-body accelerometers, and administers naloxone subcutaneously upon detection of an apnea. Our proof-of-concept system has been evaluated in two environments: (i) an approved supervised injection facility (SIF) where people self-inject opioids under medical supervision and (ii) a hospital environment where we simulate opioid-induced apneas in healthy participants. In the SIF (n = 25), our system identified breathing rate and post-injection respiratory depression accurately when compared to a respiratory belt. In the hospital, our algorithm identified simulated apneic events and successfully injected participants with 1.2 mg of naloxone. Naloxone delivery was verified by intravenous blood draw post-injection for all participants. A closed-loop naloxone injector system has the potential to complement existing evidence-based harm reduction strategies and, in the absence of bystanders, help make opioid toxicity events functionally witnessed and in turn more likely to be successfully resuscitated.

Published

2021

5. Using smart speakers to contactlessly monitor heart rhythms

Author

Shyamnath Gollakota, Anran Wang, Dan Nguyen, and Arun Sridhar

Subjects

Male, Time Factors, Remote patient monitoring, Hospitalized patients, Medicine (miscellaneous), 02 engineering and technology, 030204 cardiovascular system & hematology, Arrhythmias, Electrocardiography, 0302 clinical medicine, Heart Rate, 0202 electrical engineering, electronic engineering, information engineering, Heart rate variability, Prospective Studies, Biology (General), Measure heart rate, Atrial fibrillation, Signal Processing, Computer-Assisted, Equipment Design, Middle Aged, Telemedicine, Hospitalization, Cardiology, cardiovascular system, Female, General Agricultural and Biological Sciences, Wireless Technology, Algorithms, medicine.medical_specialty, QH301-705.5, Remote diagnosis, Transducers, Proof of Concept Study, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Rhythm, Predictive Value of Tests, Internal medicine, medicine, Humans, Aged, Heart Failure, business.industry, Reproducibility of Results, 020206 networking & telecommunications, Arrhythmias, Cardiac, Acoustics, medicine.disease, Heart failure, Case-Control Studies, business

Abstract

Heart rhythm assessment is indispensable in diagnosis and management of many cardiac conditions and to study heart rate variability in healthy individuals. We present a proof-of-concept system for acquiring individual heart beats using smart speakers in a fully contact-free manner. Our algorithms transform the smart speaker into a short-range active sonar system and measure heart rate and inter-beat intervals (R-R intervals) for both regular and irregular rhythms. The smart speaker emits inaudible 18–22 kHz sound and receives echoes reflected from the human body that encode sub-mm displacements due to heart beats. We conducted a clinical study with both healthy participants and hospitalized cardiac patients with diverse structural and arrhythmic cardiac abnormalities including atrial fibrillation, flutter and congestive heart failure. Compared to electrocardiogram (ECG) data, our system computed R-R intervals for healthy participants with a median error of 28 ms over 12,280 heart beats and a correlation coefficient of 0.929. For hospitalized cardiac patients, the median error was 30 ms over 5639 heart beats with a correlation coefficient of 0.901. The increasing adoption of smart speakers in hospitals and homes may provide a means to realize the potential of our non-contact cardiac rhythm monitoring system for monitoring of contagious or quarantined patients, skin sensitive patients and in telemedicine settings., Anran Wang et al. present a contact-free method of monitoring individual heart beats by converting smart-speakers into active sonar systems. Their approach is capable of measuring heart rhythms with high accuracy in both healthy participants and hospitalized patients, and may be a useful healthcare tool for remote diagnosis or patient monitoring.

Published

2021

6. Contactless cardiac arrest detection using smart devices

Author

Shyamnath Gollakota, Jacob E. Sunshine, Justin Chan, and Thomas D. Rea

Subjects

FOS: Computer and information sciences, medicine.medical_specialty, medicine.medical_treatment, Medicine (miscellaneous), Health Informatics, Severe hypoxia, lcsh:Computer applications to medicine. Medical informatics, Article, Computer Science - Computers and Society, Health Information Management, Internal medicine, Computers and Society (cs.CY), medicine, Cardiopulmonary resuscitation, Cause of death, business.industry, Over the Air, Diagnostic markers, Diagnostic marker, medicine.disease, Computer science, Computer Science Applications, Obstructive sleep apnea, Cardiology, lcsh:R858-859.7, False positive rate, business, Hypopnea

Abstract

Out-of-hospital cardiac arrest is a leading cause of death worldwide. Rapid diagnosis and initiation of cardiopulmonary resuscitation (CPR) is the cornerstone of therapy for victims of cardiac arrest. Yet a significant fraction of cardiac arrest victims have no chance of survival because they experience an unwitnessed event, often in the privacy of their own homes. An under-appreciated diagnostic element of cardiac arrest is the presence of agonal breathing, an audible biomarker and brainstem reflex that arises in the setting of severe hypoxia. Here, we demonstrate that a support vector machine (SVM) can classify agonal breathing instances in real-time within a bedroom environment. Using real-world labeled 9-1-1 audio of cardiac arrests, we train the SVM to accurately classify agonal breathing instances. We obtain an area under the curve (AUC) of 0.9993 ± 0.0003 and an operating point with an overall sensitivity and specificity of 97.24% (95% CI: 96.86–97.61%) and 99.51% (95% CI: 99.35–99.67%). We achieve a false positive rate between 0 and 0.14% over 82 h (117,985 audio segments) of polysomnographic sleep lab data that includes snoring, hypopnea, central, and obstructive sleep apnea events. We also evaluate our classifier in home sleep environments: the false positive rate was 0–0.22% over 164 h (236,666 audio segments) of sleep data collected across 35 different bedroom environments. We prototype our proof-of-concept contactless system using commodity smart devices (Amazon Echo and Apple iPhone) and demonstrate its effectiveness in identifying cardiac arrest-associated agonal breathing instances played over the air.

Published

2019

7. Detecting middle ear fluid using smartphones

Author

Shyamnath Gollakota, Randall A. Bly, Sharat Raju, Rajalakshmi Nandakumar, and Justin Chan

Subjects

Male, Acoustic reflectometry, medicine.medical_specialty, Adolescent, Acute otitis media, Ear, Middle, Audiology, 03 medical and health sciences, 0302 clinical medicine, otorhinolaryngologic diseases, medicine, Humans, 030212 general & internal medicine, Child, 030223 otorhinolaryngology, Pneumatic otoscopy, medicine.diagnostic_test, Otitis Media with Effusion, business.industry, Infant, Diagnostic marker, General Medicine, Tympanometry, Benchmarking, Otitis, medicine.anatomical_structure, ROC Curve, Child, Preschool, Female, Smartphone, medicine.symptom, Middle ear fluid, business, Eardrum

Abstract

The presence of middle ear fluid is a key diagnostic marker for two of the most common pediatric ear diseases: acute otitis media and otitis media with effusion. We present an accessible solution that uses speakers and microphones within existing smartphones to detect middle ear fluid by assessing eardrum mobility. We conducted a clinical study on 98 patient ears at a pediatric surgical center. Using leave-one-out cross-validation to estimate performance on unseen data, we obtained an area under the curve (AUC) of 0.898 for the smartphone-based machine learning algorithm. In comparison, commercial acoustic reflectometry, which requires custom hardware, achieved an AUC of 0.776. Furthermore, we achieved 85% sensitivity and 82% specificity, comparable to published performance measures for tympanometry and pneumatic otoscopy. Similar results were obtained when testing across multiple smartphone platforms. Parents of pediatric patients (n = 25 ears) demonstrated similar performance to trained clinicians when using the smartphone-based system. These results demonstrate the potential for a smartphone to be a low-barrier and effective screening tool for detecting the presence of middle ear fluid.

Published

2019

8. Opioid overdose detection using smartphones

Author

Shyamnath Gollakota, Jacob E. Sunshine, and Rajalakshmi Nandakumar

Subjects

Adult, Male, medicine.medical_specialty, Central apnea, Poison control, 01 natural sciences, Fentanyl, 03 medical and health sciences, 0302 clinical medicine, medicine, Humans, 030212 general & internal medicine, 0101 mathematics, Harm reduction, business.industry, Illicit Drugs, Respiration, 010102 general mathematics, Apnea, Opioid overdose, General Medicine, medicine.disease, Sleep Apnea, Central, Analgesics, Opioid, Opioid, Respiratory failure, Emergency medicine, Female, Smartphone, medicine.symptom, Drug Overdose, business, Algorithms, medicine.drug

Abstract

Early detection and rapid intervention can prevent death from opioid overdose. At high doses, opioids (particularly fentanyl) can cause rapid cessation of breathing (apnea), hypoxemic/hypercarbic respiratory failure, and death, the physiologic sequence by which people commonly succumb from unintentional opioid overdose. We present algorithms that run on smartphones and unobtrusively detect opioid overdose events and their precursors. Our proof-of- concept contactless system converts the phone into a short-range active sonar using frequency shifts to identify respiratory depression, apnea, and gross motor movements associated with acute opioid toxicity. We develop algorithms and perform testing in two environments: (i) an approved supervised injection facility (SIF), where people self-inject illicit opioids, and (ii) the operating room (OR), where we simulate rapid, opioid-induced overdose events using routine induction of general anesthesia. In the SIF (n = 209), our system identified postinjection, opioid-induced central apnea with 96% sensitivity and 98% specificity and identified respiratory depression with 87% sensitivity and 89% specificity. These two key events commonly precede fatal opioid overdose. In the OR, our algorithm identified 19 of 20 simulated overdose events. Given the reliable reversibility of acute opioid toxicity, smartphone-enabled overdose detection coupled with the ability to alert naloxone-equipped friends and family or emergency medical services (EMS) could hold potential as a low-barrier, harm reduction intervention.

Published

2018

9. Leveraging Dual-Observable Input for Fine-Grained Thumb Interaction Using Forearm EMG

Author

Xiaoyi Zhang, Shyamnath Gollakota, Donny Huang, James Fogarty, and T. Scott Saponas

Subjects

Training set, InformationSystems_INFORMATIONINTERFACESANDPRESENTATION(e.g.,HCI), Computer science, Speech recognition, SwIPe, Wearable computer, Input device, Thumb, DUAL (cognitive architecture), body regions, medicine.anatomical_structure, Forearm, medicine, Gesture

Abstract

We introduce the first forearm-based EMG input system that can recognize fine-grained thumb gestures, including left swipes, right swipes, taps, long presses, and more complex thumb motions. EMG signals for thumb motions sensed from the forearm are quite weak and require significant training data to classify. We therefore also introduce a novel approach for minimally-intrusive collection of labeled training data for always-available input devices. Our dual-observable input approach is based on the insight that interaction observed by multiple devices allows recognition by a primary device (e.g., phone recognition of a left swipe gesture) to create labeled training examples for another (e.g., forearm-based EMG data labeled as a left swipe). We implement a wearable prototype with dry EMG electrodes, train with labeled demonstrations from participants using their own phones, and show that our prototype can recognize common fine-grained thumb gestures and user-defined complex gestures.

Published

2015

10. Contactless Sleep Apnea Detection on Smartphones

Author

Nathaniel F. Watson, Shyamnath Gollakota, and Rajalakshmi Nandakumar

Subjects

business.industry, Computer science, Central apnea, Apnea, Sleep apnea, medicine.disease, Sonar, respiratory tract diseases, Breathing, medicine, General Earth and Planetary Sciences, Computer vision, Sleep (system call), Artificial intelligence, medicine.symptom, Marine mammals and sonar, business, Hypopnea, Simulation, General Environmental Science

Abstract

We present a contactless solution for detecting sleep apnea events on smartphones. To achieve this, we introduce a novel system that monitors the minute chest and abdomen movements caused by breathing on smartphones. Our system works with the phone away from the subject and can simultaneously identify and track the fine-grained breathing movements from multiple subjects. We do this by transforming the phone into an active sonar system that emits frequency-modulated sound signals and listens to their reflections; our design monitors the minute changes to these reflections to extract the chest movements. Results from a home bedroom environment shows that our design operates efficiently at distances of up to a meter and works even with the subject under a blanket. Building on the above system, we develop algorithms that identify various sleep apnea events including obstructive apnea, central apnea, and hypopnea from the sonar reflections. We deploy our system at the UW Medicine Sleep Center at Harborview and perform a clinical study with 37 patients for a total of 296 hours. Our study demonstrates that the number of respiratory events identified by our system is highly correlated with the ground truth and has a correlation coefficient of 0.9957, 0.9860, and 0.9533 for central apnea, obstructive apnea and hypopnea respectively. Furthermore, the average error in computing of rate of apnea and hypopnea events is as low as 1.9 events/hr.

Published

2015

11. Non-Invasive Approach to Securing Medical Implants

Author

Shyamnath Gollakota

Subjects

medicine.medical_specialty, Non invasive, medicine, Surgery

Published

2014

12. Non-intrusive tongue machine interface

Author

Ben Taskar, Qiao Zhang, Shyamnath Gollakota, and Raj P.N. Rao

Subjects

medicine.anatomical_structure, medicine.diagnostic_test, Tongue, Computer science, Speech recognition, Interface (computing), medicine, Electromyography, Machine interface, Set (psychology), Gesture

Abstract

There has been recent interest in designing systems that use the tongue as an input interface. Prior work however either require surgical procedures or in-mouth sensor placements. In this paper, we introduce TongueSee, a non-intrusive tongue machine interface that can recognize a rich set of tongue gestures using electromyography (EMG) signals from the surface of the skin. We demonstrate the feasibility and robustness of TongueSee with experimental studies to classify six tongue gestures across eight participants. TongueSee achieves a classification accuracy of 94.17% and a false positive probability of 0.000358 per second using three-protrusion preamble design.

Published

2014