Your search keyword '"Sun, Haoqi"' showing total 8 results

1. How Machine Learning is Powering Neuroimaging to Improve Brain Health

Author

Singh, Nalini M., Harrod, Jordan B., Subramanian, Sandya, Robinson, Mitchell, Chang, Ken, Cetin-Karayumak, Suheyla, Dalca, Adrian Vasile, Eickhoff, Simon, Fox, Michael, Franke, Loraine, Golland, Polina, Haehn, Daniel, Iglesias, Juan Eugenio, O’Donnell, Lauren J., Ou, Yangming, Rathi, Yogesh, Siddiqi, Shan H., Sun, Haoqi, Westover, M. Brandon, Whitfield-Gabrieli, Susan, and Gollub, Randy L.

Published

2022

2. Epilepsy is associated with the accelerated aging of brain activity in sleep.

Author

Hadar, Peter N., Westmeijer, Mike, Sun, Haoqi, Meulenbrugge, Erik-Jan, Jing, Jin, Paixao, Luis, Tesh, Ryan A., Da Silva Cardoso, Madalena, Arnal, Pierrick, Au, Rhoda, Shin, Chol, Kim, Soriul, Thomas, Robert J., Cash, Sydney S., and Westover, M. Brandon

Abstract

Objective: Although seizures are the cardinal feature, epilepsy is associated with other forms of brain dysfunction including impaired cognition, abnormal sleep, and increased risk of developing dementia. We hypothesized that, given the widespread neurologic dysfunction caused by epilepsy, accelerated brain aging would be seen. We measured the sleep-based brain age index (BAI) in a diverse group of patients with epilepsy. The BAI is a machine learning-based biomarker that measures how much the brain activity of a person during overnight sleep deviates from chronological age-based norms. Methods: This case–control study drew information of age-matched controls without epilepsy from home sleep monitoring volunteers and from non-epilepsy patients with Sleep Lab testing. Patients with epilepsy underwent in-patient monitoring and were classified by epilepsy type and seizure burden. The primary outcomes measured were BAI, processed from electroencephalograms, and epilepsy severity metrics (years with epilepsy, seizure frequency standardized by year, and seizure burden [number of seizures in life]). Subanalyses were conducted on a subset with NIH Toolbox cognitive testing for total, fluid, and crystallized composite cognition. Results: 138 patients with epilepsy (32 exclusively focal and 106 generalizable [focal seizures with secondary generalization]) underwent in-patient monitoring, and age-matched, non-epilepsy controls were analyzed. The mean BAI was higher in epilepsy patients vs controls and differed by epilepsy type: −0.05 years (controls) versus 5.02 years (all epilepsy, p < 0.001), 5.53 years (generalizable, p < 0.001), and 3.34 years (focal, p = 0.03). Sleep architecture was disrupted in epilepsy, especially in generalizable epilepsy. A higher BAI was positively associated with increased lifetime seizure burden in focal and generalizable epilepsies and associated with lower crystallized cognition. Lifetime seizure burden was inversely correlated with fluid, crystallized, and composite cognition. Significance: Epilepsy is associated with accelerated brain aging. Higher brain age indices are associated with poorer cognition and more severe epilepsy, specifically generalizability and higher seizure burden. These findings strengthen the use of the sleep-derived, electroencephalography-based BAI as a biomarker for cognitive dysfunction in epilepsy. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effects of Aerobic Exercise on Brain Age and Health in Middle-Aged and Older Adults: A Single-Arm Pilot Clinical Trial.

Author

Ouyang, An, Zhang, Can, Adra, Noor, Tesh, Ryan A., Sun, Haoqi, Lei, Dan, Jing, Jin, Fan, Peng, Paixao, Luis, Ganglberger, Wolfgang, Briggs, Logan, Salinas, Joel, Bevers, Matthew B., Wrann, Christiane Dorothea, Chemali, Zeina, Fricchione, Gregory, Thomas, Robert J., Rosand, Jonathan, Tanzi, Rudolph E., and Westover, Michael Brandon

Subjects

AEROBIC capacity, EXERCISE physiology, SLEEP interruptions, SLEEP quality, MIDDLE-aged persons, OXYGEN consumption

Abstract

Backgrounds: Sleep disturbances are prevalent among elderly individuals. While polysomnography (PSG) serves as the gold standard for sleep monitoring, its extensive setup and data analysis procedures impose significant costs and time constraints, thereby restricting the long-term application within the general public. Our laboratory introduced an innovative biomarker, utilizing artificial intelligence algorithms applied to PSG data to estimate brain age (BA), a metric validated in cohorts with cognitive impairments. Nevertheless, the potential of exercise, which has been a recognized means of enhancing sleep quality in middle-aged and older adults to reduce BA, remains undetermined. Methods: We conducted an exploratory study to evaluate whether 12 weeks of moderate-intensity exercise can improve cognitive function, sleep quality, and the brain age index (BAI), a biomarker computed from overnight sleep electroencephalogram (EEG), in physically inactive middle-aged and older adults. Home wearable devices were used to monitor heart rate and overnight sleep EEG over this period. The NIH Toolbox Cognition Battery, in-lab overnight polysomnography, cardiopulmonary exercise testing, and a multiplex cytokines assay were employed to compare pre- and post-exercise brain health, exercise capacity, and plasma proteins. Results: In total, 26 participants completed the initial assessment and exercise program, and 24 completed all procedures. Data are presented as mean [lower 95% CI of mean, upper 95% CI of mean]. Participants significantly increased maximal oxygen consumption (Pre: 21.11 [18.98, 23.23], Post 22.39 [20.09, 24.68], mL/kg/min; effect size: −0.33) and decreased resting heart rate (Pre: 66.66 [63.62, 67.38], Post: 65.13 [64.25, 66.93], bpm; effect size: −0.02) and sleeping heart rate (Pre: 64.55 [61.87, 667.23], Post: 62.93 [60.78, 65.09], bpm; effect size: −0.15). Total cognitive performance (Pre: 111.1 [107.6, 114.6], Post: 115.2 [111.9, 118.5]; effect size: 0.49) was significantly improved. No significant differences were seen in BAI or measures of sleep macro- and micro-architecture. Plasma IL-4 (Pre: 0.24 [0.18, 0.3], Post: 0.33 [0.24, 0.42], pg/mL; effect size: 0.49) was elevated, while IL-8 (Pre: 5.5 [4.45, 6.55], Post: 4.3 [3.66, 5], pg/mL; effect size: −0.57) was reduced. Conclusions: Cognitive function was improved by a 12-week moderate-intensity exercise program in physically inactive middle-aged and older adults, as were aerobic fitness (VO2max) and plasma cytokine profiles. However, we found no measurable effects on sleep architecture or BAI. It remains to be seen whether a study with a larger sample size and more intensive or more prolonged exercise exposure can demonstrate a beneficial effect on sleep quality and brain age. [ABSTRACT FROM AUTHOR]

Published

2024

4. Machine Learning Reveals Different Brain Activities in Visual Pathway during TOVA Test

Author

Sun, Haoqi, Sourina, Olga, Yang, Yan, Huang, Guang-Bin, Denk, Cornelia, Klanner, Felix, Lim, Meng-Hiot, Series editor, Ong, Yew-Soon, Series editor, Cao, Jiuwen, editor, Mao, Kezhi, editor, Cambria, Erik, editor, Man, Zhihong, editor, and Toh, Kar-Ann, editor

Published

2015

5. Automated Annotation of Epileptiform Burden and Its Association with Outcomes.

Author

Zafar, Sahar F., Rosenthal, Eric S., Jing, Jin, Ge, Wendong, Tabaeizadeh, Mohammad, Nour, Hassan Aboul, Shoukat, Maryum, Sun, Haoqi, Javed, Farrukh, Kassa, Solomon, Edhi, Muhammad, Bordbar, Elahe, Gallagher, Justin, Moura, Valdery, Ghanta, Manohar, Shao, Yu‐Ping, An, Sungtae, Sun, Jimeng, Cole, Andrew J., and Westover, M. Brandon

Subjects

APACHE (Disease classification system), ARTIFICIAL intelligence, BRAIN-computer interfaces, RESEARCH, ELECTROENCEPHALOGRAPHY, RESEARCH methodology, RETROSPECTIVE studies, MEDICAL cooperation, EVALUATION research, TREATMENT effectiveness, COMPARATIVE studies, RESEARCH funding, SEIZURES (Medicine), ECONOMIC aspects of diseases, LONGITUDINAL method

Abstract

Objective: This study was undertaken to determine the dose-response relation between epileptiform activity burden and outcomes in acutely ill patients.Methods: A single center retrospective analysis was made of 1,967 neurologic, medical, and surgical patients who underwent >16 hours of continuous electroencephalography (EEG) between 2011 and 2017. We developed an artificial intelligence algorithm to annotate 11.02 terabytes of EEG and quantify epileptiform activity burden within 72 hours of recording. We evaluated burden (1) in the first 24 hours of recording, (2) in the 12-hours epoch with highest burden (peak burden), and (3) cumulatively through the first 72 hours of monitoring. Machine learning was applied to estimate the effect of epileptiform burden on outcome. Outcome measure was discharge modified Rankin Scale, dichotomized as good (0-4) versus poor (5-6).Results: Peak epileptiform burden was independently associated with poor outcomes (p < 0.0001). Other independent associations included age, Acute Physiology and Chronic Health Evaluation II score, seizure on presentation, and diagnosis of hypoxic-ischemic encephalopathy. Model calibration error was calculated across 3 strata based on the time interval between last EEG measurement (up to 72 hours of monitoring) and discharge: (1) <5 days between last measurement and discharge, 0.0941 (95% confidence interval [CI] = 0.0706-0.1191); 5 to 10 days between last measurement and discharge, 0.0946 (95% CI = 0.0631-0.1290); >10 days between last measurement and discharge, 0.0998 (95% CI = 0.0698-0.1335). After adjusting for covariates, increase in peak epileptiform activity burden from 0 to 100% increased the probability of poor outcome by 35%.Interpretation: Automated measurement of peak epileptiform activity burden affords a convenient, consistent, and quantifiable target for future multicenter randomized trials investigating whether suppressing epileptiform activity improves outcomes. ANN NEUROL 2021;90:300-311. [ABSTRACT FROM AUTHOR]

Published

2021

6. Night-to-night variability of sleep electroencephalography-based brain age measurements.

Author

Hogan, Jacob, Sun, Haoqi, Paixao, Luis, Westmeijer, Mike, Sikka, Pooja, Jin, Jing, Tesh, Ryan, Cardoso, Madalena, Cash, Sydney S., Akeju, Oluwaseun, Thomas, Robert, and Westover, M. Brandon

Subjects

*BRAIN diseases, *STANDARD deviations, *DIAGNOSIS of epilepsy, *SLEEP, *WEARABLE technology

Abstract

• Using multiple nights of EEG to estimate the night-to-night variability of a previously established sleep EEG-based Brain Age Index (BAI). • Averaging BAI over n nights reduces night-to-night variability of BAI by a factor of n . • Average BAI over multiple nights is a relatively stable estimate of brain health. Brain Age Index (BAI), calculated from sleep electroencephalography (EEG), has been proposed as a biomarker of brain health. This study quantifies night-to-night variability of BAI and establishes probability thresholds for inferring underlying brain pathology based on a patient's BAI. 86 patients with multiple nights of consecutive EEG recordings were selected from Epilepsy Monitoring Unit patients whose EEGs reported as within normal limits. While EEGs with epileptiform activity were excluded, the majority of patients included in the study had a diagnosis of chronic epilepsy. BAI was calculated for each 12-hour segment of patient data using a previously established algorithm, and the night-to-night variability in BAI was measured. The within-patient night-to-night standard deviation in BAI was 7.5 years. Estimates of BAI derived by averaging over 2, 3, and 4 nights had standard deviations of 4.7, 3.7, and 3.0 years, respectively. Averaging BAI over n nights reduces night-to-night variability of BAI by a factor of n , rendering BAI a more suitable biomarker of brain health at the individual level. A brain age risk lookup table of results provides thresholds above which a patient has a high probability of excess BAI. With increasing ease of EEG acquisition, including wearable technology, BAI has the potential to track brain health and detect deviations from normal physiologic function. The measure of night-to-night variability and how this is reduced by averaging across multiple nights provides a basis for using BAI in patients' homes to identify patients who should undergo further investigation or monitoring. [ABSTRACT FROM AUTHOR]

Published

2021

7. Brain age from the electroencephalogram of sleep.

Author

Sun, Haoqi, Paixao, Luis, Oliva, Jefferson T., Goparaju, Balaji, Carvalho, Diego Z., van Leeuwen, Kicky G., Akeju, Oluwaseun, Thomas, Robert J., Cash, Sydney S., Bianchi, Matt T., and Westover, M. Brandon

Subjects

*SLEEP, *AGING, *ELECTROENCEPHALOGRAPHY, *AGE, *MACHINE learning

Abstract

Abstract The human electroencephalogram (EEG) of sleep undergoes profound changes with age. These changes can be conceptualized as "brain age (BA)," which can be compared to chronological age to reflect the degree of deviation from normal aging. Here, we develop an interpretable machine learning model to predict BA based on 2 large sleep EEG data sets: the Massachusetts General Hospital (MGH) sleep lab data set (N = 2532; ages 18–80); and the Sleep Heart Health Study (SHHS, N = 1974; ages 40–80). The model obtains a mean absolute deviation of 7.6 years between BA and chronological age (CA) in healthy participants in the MGH data set. As validation, a subset of SHHS containing longitudinal EEGs 5.2 years apart shows an average of 5.4 years increase in BA. Participants with significant neurological or psychiatric disease exhibit a mean excess BA, or "brain age index" (BAI = BA-CA) of 4 years relative to healthy controls. Participants with hypertension and diabetes have a mean excess BA of 3.5 years. The findings raise the prospect of using the sleep EEG as a potential biomarker for healthy brain aging. Highlights • Brain age based on two large sleep EEG datasets (N MGH = 2532 and N SHHS = 1974). • Brain age tracks chronological age at the population level. • Chronological age is predicted with mean absolute deviation of 7.6 years in healthy participants. • Significant neurological and psychiatric diseases lead to a 4-year increase in brain age. • Interpretation using age norms derived from matched brain age and chorological age. [ABSTRACT FROM AUTHOR]

Published

2019

8. Excess brain age in the sleep electroencephalogram predicts reduced life expectancy.

Author

Paixao, Luis, Sikka, Pooja, Sun, Haoqi, Jain, Aayushee, Hogan, Jacob, Thomas, Robert, and Westover, M. Brandon

Subjects

*LIFE expectancy, *AGE, *ELECTROENCEPHALOGRAPHY, *SLEEP, *INDIVIDUAL differences

Abstract

The brain age index (BAI) measures the difference between an individual's apparent "brain age" (BA; estimated by comparing EEG features during sleep from an individual with age norms), and their chronological age (CA); that is BAI = BA–CA. Here, we evaluate whether BAI predicts life expectancy. Brain age was quantified using a previously published machine learning algorithm for a cohort of participants ≥40 years old who underwent an overnight sleep electroencephalogram (EEG) as part of the Sleep Heart Health Study (n = 4877). Excess brain age (BAI >0) was associated with reduced life expectancy (adjusted hazard ratio: 1.12, [1.03, 1.21], p = 0.002). Life expectancy decreased by −0.81 [−1.44, −0.24] years per standard-deviation increase in BAI. Our findings show that BAI, a sleep EEG-based biomarker of the deviation of sleep microstructure from patterns normal for age, is an independent predictor of life expectancy. • Brain age index (BAI), a sleep EEG-based biomarker, is associated with reduced life expectancy. • BAI is the difference between sleep EEG-predicted brain age and chronological age. • Each standard-deviation increase in BAI decreases life expectancy by about one year. [ABSTRACT FROM AUTHOR]

Published

2020