A robust adaptive denoising framework for real-time artifact removal in scalp EEG measurements
Objective. Non-invasive measurement of human neural activity based on the scalp electroencephalogram (EEG) allows for the development of biomedical devices that interface with the nervous system for scientific, diagnostic, therapeutic, or restorative purposes. However, EEG recordings are often consi...
Saved in:
| Published in | Journal of neural engineering Vol. 13; no. 2; pp. 26013 - 26028 |
|---|---|
| Main Authors | , , |
| Format | Journal Article |
| Language | English |
| Published |
England
IOP Publishing
01.04.2016
|
| Subjects | |
| Online Access | Get full text |
Cover
Loading…
| Abstract | Objective. Non-invasive measurement of human neural activity based on the scalp electroencephalogram (EEG) allows for the development of biomedical devices that interface with the nervous system for scientific, diagnostic, therapeutic, or restorative purposes. However, EEG recordings are often considered as prone to physiological and non-physiological artifacts of different types and frequency characteristics. Among them, ocular artifacts and signal drifts represent major sources of EEG contamination, particularly in real-time closed-loop brain-machine interface (BMI) applications, which require effective handling of these artifacts across sessions and in natural settings. Approach. We extend the usage of a robust adaptive noise cancelling (ANC) scheme ( filtering) for removal of eye blinks, eye motions, amplitude drifts and recording biases simultaneously. We also characterize the volume conduction, by estimating the signal propagation levels across all EEG scalp recording areas due to ocular artifact generators. We find that the amplitude and spatial distribution of ocular artifacts vary greatly depending on the electrode location. Therefore, fixed filtering parameters for all recording areas would naturally hinder the true overall performance of an ANC scheme for artifact removal. We treat each electrode as a separate sub-system to be filtered, and without the loss of generality, they are assumed to be uncorrelated and uncoupled. Main results. Our results show over 95-99.9% correlation between the raw and processed signals at non-ocular artifact regions, and depending on the contamination profile, 40-70% correlation when ocular artifacts are dominant. We also compare our results with the offline independent component analysis and artifact subspace reconstruction methods, and show that some local quantities are handled better by our sample-adaptive real-time framework. Decoding performance is also compared with multi-day experimental data from 2 subjects, totaling 19 sessions, with and without filtering of the raw data. Significance. The proposed method allows real-time adaptive artifact removal for EEG-based closed-loop BMI applications and mobile EEG studies in general, thereby increasing the range of tasks that can be studied in action and context while reducing the need for discarding data due to artifacts. Significant increase in decoding performances also justify the effectiveness of the method to be used in real-time closed-loop BMI applications. |
|---|---|
| AbstractList | Objective. Non-invasive measurement of human neural activity based on the scalp electroencephalogram (EEG) allows for the development of biomedical devices that interface with the nervous system for scientific, diagnostic, therapeutic, or restorative purposes. However, EEG recordings are often considered as prone to physiological and non-physiological artifacts of different types and frequency characteristics. Among them, ocular artifacts and signal drifts represent major sources of EEG contamination, particularly in real-time closed-loop brain-machine interface (BMI) applications, which require effective handling of these artifacts across sessions and in natural settings. Approach. We extend the usage of a robust adaptive noise cancelling (ANC) scheme (&${H}\infty }$; filtering) for removal of eye blinks, eye motions, amplitude drifts and recording biases simultaneously. We also characterize the volume conduction, by estimating the signal propagation levels across all EEG scalp recording areas due to ocular artifact generators. We find that the amplitude and spatial distribution of ocular artifacts vary greatly depending on the electrode location. Therefore, fixed filtering parameters for all recording areas would naturally hinder the true overall performance of an ANC scheme for artifact removal. We treat each electrode as a separate sub-system to be filtered, and without the loss of generality, they are assumed to be uncorrelated and uncoupled. Main results. Our results show over 95-99.9% correlation between the raw and processed signals at non-ocular artifact regions, and depending on the contamination profile, 40-70% correlation when ocular artifacts are dominant. We also compare our results with the offline independent component analysis and artifact subspace reconstruction methods, and show that some local quantities are handled better by our sample-adaptive real-time framework. Decoding performance is also compared with multi-day experimental data from 2 subjects, totaling 19 sessions, with and without &${H}\infty }$; filtering of the raw data. Significance. The proposed method allows real-time adaptive artifact removal for EEG-based closed-loop BMI applications and mobile EEG studies in general, thereby increasing the range of tasks that can be studied in action and context while reducing the need for discarding data due to artifacts. Significant increase in decoding performances also justify the effectiveness of the method to be used in real-time closed-loop BMI applications. Objective. Non-invasive measurement of human neural activity based on the scalp electroencephalogram (EEG) allows for the development of biomedical devices that interface with the nervous system for scientific, diagnostic, therapeutic, or restorative purposes. However, EEG recordings are often considered as prone to physiological and non-physiological artifacts of different types and frequency characteristics. Among them, ocular artifacts and signal drifts represent major sources of EEG contamination, particularly in real-time closed-loop brain-machine interface (BMI) applications, which require effective handling of these artifacts across sessions and in natural settings. Approach. We extend the usage of a robust adaptive noise cancelling (ANC) scheme ( filtering) for removal of eye blinks, eye motions, amplitude drifts and recording biases simultaneously. We also characterize the volume conduction, by estimating the signal propagation levels across all EEG scalp recording areas due to ocular artifact generators. We find that the amplitude and spatial distribution of ocular artifacts vary greatly depending on the electrode location. Therefore, fixed filtering parameters for all recording areas would naturally hinder the true overall performance of an ANC scheme for artifact removal. We treat each electrode as a separate sub-system to be filtered, and without the loss of generality, they are assumed to be uncorrelated and uncoupled. Main results. Our results show over 95-99.9% correlation between the raw and processed signals at non-ocular artifact regions, and depending on the contamination profile, 40-70% correlation when ocular artifacts are dominant. We also compare our results with the offline independent component analysis and artifact subspace reconstruction methods, and show that some local quantities are handled better by our sample-adaptive real-time framework. Decoding performance is also compared with multi-day experimental data from 2 subjects, totaling 19 sessions, with and without filtering of the raw data. Significance. The proposed method allows real-time adaptive artifact removal for EEG-based closed-loop BMI applications and mobile EEG studies in general, thereby increasing the range of tasks that can be studied in action and context while reducing the need for discarding data due to artifacts. Significant increase in decoding performances also justify the effectiveness of the method to be used in real-time closed-loop BMI applications. Non-invasive measurement of human neural activity based on the scalp electroencephalogram (EEG) allows for the development of biomedical devices that interface with the nervous system for scientific, diagnostic, therapeutic, or restorative purposes. However, EEG recordings are often considered as prone to physiological and non-physiological artifacts of different types and frequency characteristics. Among them, ocular artifacts and signal drifts represent major sources of EEG contamination, particularly in real-time closed-loop brain-machine interface (BMI) applications, which require effective handling of these artifacts across sessions and in natural settings. We extend the usage of a robust adaptive noise cancelling (ANC) scheme ([Formula: see text] filtering) for removal of eye blinks, eye motions, amplitude drifts and recording biases simultaneously. We also characterize the volume conduction, by estimating the signal propagation levels across all EEG scalp recording areas due to ocular artifact generators. We find that the amplitude and spatial distribution of ocular artifacts vary greatly depending on the electrode location. Therefore, fixed filtering parameters for all recording areas would naturally hinder the true overall performance of an ANC scheme for artifact removal. We treat each electrode as a separate sub-system to be filtered, and without the loss of generality, they are assumed to be uncorrelated and uncoupled. Our results show over 95-99.9% correlation between the raw and processed signals at non-ocular artifact regions, and depending on the contamination profile, 40-70% correlation when ocular artifacts are dominant. We also compare our results with the offline independent component analysis and artifact subspace reconstruction methods, and show that some local quantities are handled better by our sample-adaptive real-time framework. Decoding performance is also compared with multi-day experimental data from 2 subjects, totaling 19 sessions, with and without [Formula: see text] filtering of the raw data. The proposed method allows real-time adaptive artifact removal for EEG-based closed-loop BMI applications and mobile EEG studies in general, thereby increasing the range of tasks that can be studied in action and context while reducing the need for discarding data due to artifacts. Significant increase in decoding performances also justify the effectiveness of the method to be used in real-time closed-loop BMI applications. Non-invasive measurement of human neural activity based on the scalp electroencephalogram (EEG) allows for the development of biomedical devices that interface with the nervous system for scientific, diagnostic, therapeutic, or restorative purposes. However, EEG recordings are often considered as prone to physiological and non-physiological artifacts of different types and frequency characteristics. Among them, ocular artifacts and signal drifts represent major sources of EEG contamination, particularly in real-time closed-loop brain-machine interface (BMI) applications, which require effective handling of these artifacts across sessions and in natural settings.OBJECTIVENon-invasive measurement of human neural activity based on the scalp electroencephalogram (EEG) allows for the development of biomedical devices that interface with the nervous system for scientific, diagnostic, therapeutic, or restorative purposes. However, EEG recordings are often considered as prone to physiological and non-physiological artifacts of different types and frequency characteristics. Among them, ocular artifacts and signal drifts represent major sources of EEG contamination, particularly in real-time closed-loop brain-machine interface (BMI) applications, which require effective handling of these artifacts across sessions and in natural settings.We extend the usage of a robust adaptive noise cancelling (ANC) scheme ([Formula: see text] filtering) for removal of eye blinks, eye motions, amplitude drifts and recording biases simultaneously. We also characterize the volume conduction, by estimating the signal propagation levels across all EEG scalp recording areas due to ocular artifact generators. We find that the amplitude and spatial distribution of ocular artifacts vary greatly depending on the electrode location. Therefore, fixed filtering parameters for all recording areas would naturally hinder the true overall performance of an ANC scheme for artifact removal. We treat each electrode as a separate sub-system to be filtered, and without the loss of generality, they are assumed to be uncorrelated and uncoupled.APPROACHWe extend the usage of a robust adaptive noise cancelling (ANC) scheme ([Formula: see text] filtering) for removal of eye blinks, eye motions, amplitude drifts and recording biases simultaneously. We also characterize the volume conduction, by estimating the signal propagation levels across all EEG scalp recording areas due to ocular artifact generators. We find that the amplitude and spatial distribution of ocular artifacts vary greatly depending on the electrode location. Therefore, fixed filtering parameters for all recording areas would naturally hinder the true overall performance of an ANC scheme for artifact removal. We treat each electrode as a separate sub-system to be filtered, and without the loss of generality, they are assumed to be uncorrelated and uncoupled.Our results show over 95-99.9% correlation between the raw and processed signals at non-ocular artifact regions, and depending on the contamination profile, 40-70% correlation when ocular artifacts are dominant. We also compare our results with the offline independent component analysis and artifact subspace reconstruction methods, and show that some local quantities are handled better by our sample-adaptive real-time framework. Decoding performance is also compared with multi-day experimental data from 2 subjects, totaling 19 sessions, with and without [Formula: see text] filtering of the raw data.MAIN RESULTSOur results show over 95-99.9% correlation between the raw and processed signals at non-ocular artifact regions, and depending on the contamination profile, 40-70% correlation when ocular artifacts are dominant. We also compare our results with the offline independent component analysis and artifact subspace reconstruction methods, and show that some local quantities are handled better by our sample-adaptive real-time framework. Decoding performance is also compared with multi-day experimental data from 2 subjects, totaling 19 sessions, with and without [Formula: see text] filtering of the raw data.The proposed method allows real-time adaptive artifact removal for EEG-based closed-loop BMI applications and mobile EEG studies in general, thereby increasing the range of tasks that can be studied in action and context while reducing the need for discarding data due to artifacts. Significant increase in decoding performances also justify the effectiveness of the method to be used in real-time closed-loop BMI applications.SIGNIFICANCEThe proposed method allows real-time adaptive artifact removal for EEG-based closed-loop BMI applications and mobile EEG studies in general, thereby increasing the range of tasks that can be studied in action and context while reducing the need for discarding data due to artifacts. Significant increase in decoding performances also justify the effectiveness of the method to be used in real-time closed-loop BMI applications. |
| Author | Grossman, Robert G Contreras-Vidal, Jose Luis Kilicarslan, Atilla |
| Author_xml | – sequence: 1 givenname: Atilla surname: Kilicarslan fullname: Kilicarslan, Atilla email: akilica2@central.uh.edu organization: Houston Methodist Research Institute , Houston Methodist Hospital, Houston, TX, USA – sequence: 2 givenname: Robert G surname: Grossman fullname: Grossman, Robert G email: RGrossman@houstonmethodist.org organization: Department of Neurosurgery , Houston Methodist Hospital, Houston, TX, USA – sequence: 3 givenname: Jose Luis surname: Contreras-Vidal fullname: Contreras-Vidal, Jose Luis email: JLContreras-Vidal@uh.edu organization: Houston Methodist Research Institute , Houston Methodist Hospital, Houston, TX, USA |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/26863159$$D View this record in MEDLINE/PubMed |
| BookMark | eNqFkT1v3DAMhoUgRfPVn9BCYxfnKMuWbHQKgmtSIECXdo1A21Sg1JZcSU7Qf18f7pqhy00kyOfhwPeCnfrgibGPAq4FNM1G6EoUZa1gI-Sm3ECpQMgTdn6Y1-XpW6_gjF2k9AwghW7hPTsrVaOkqNtz9njDY-iWlDkOOGf3QnwgH1xy_onbiBO9hviL2xB5JByL7CbiGLOz2Od1NIUXHLnzPPU4zny7veMTYVrWDfmcrtg7i2OiD4d6yX5-3f64vS8evt99u715KHrZVLmopUZFZBGgUarpWlGhBt1B1eu6g84qHAS1etDYWahtu4JVZ1GV1aCUkPKSfd7fnWP4vVDKZnKpp3FET2FJRjRlXVVKrOxRVGvZgJatXtFPB3TpJhrMHN2E8Y_5974VqPdAH0NKkewbIsDsYjK7CMwuAiOkKc0-ptX78p_Xu4zZBZ8juvGoLfa2C7N5Dkv062uPOH8BTHalBg |
| CODEN | JNEIEZ |
| CitedBy_id | crossref_primary_10_1109_TCDS_2024_3431224 crossref_primary_10_1016_j_eswa_2016_10_009 crossref_primary_10_1007_s11277_018_5929_5 crossref_primary_10_1088_1741_2560_13_3_036022 crossref_primary_10_1007_s11465_022_0684_4 crossref_primary_10_1016_j_bspc_2018_02_021 crossref_primary_10_1186_s12984_024_01342_9 crossref_primary_10_1016_j_isci_2023_106675 crossref_primary_10_3389_fbioe_2020_00735 crossref_primary_10_3389_fnbot_2020_00048 crossref_primary_10_1002_ima_22178 crossref_primary_10_3390_s25051322 crossref_primary_10_3390_mps4030048 crossref_primary_10_1007_s12204_022_2452_3 crossref_primary_10_1088_1741_2552_ad1782 crossref_primary_10_3390_sym13091746 crossref_primary_10_1088_1741_2552_ac7b4b crossref_primary_10_3390_s23135930 crossref_primary_10_1016_j_neucli_2017_10_059 crossref_primary_10_1088_1741_2552_ab0ab5 crossref_primary_10_3390_bios12080555 crossref_primary_10_1007_s11042_019_07914_5 crossref_primary_10_1080_2326263X_2016_1275488 crossref_primary_10_1080_03772063_2020_1725657 crossref_primary_10_3390_app11094106 crossref_primary_10_1155_2016_4069790 crossref_primary_10_3389_fncom_2022_1006763 crossref_primary_10_3390_s22155867 crossref_primary_10_1088_1741_2552_ac6ca9 crossref_primary_10_1142_S0129065720500380 crossref_primary_10_3390_s24206645 crossref_primary_10_1016_j_bspc_2020_102337 crossref_primary_10_1109_RBME_2023_3296938 crossref_primary_10_17979_ja_cea_2024_45_10911 crossref_primary_10_1016_j_cmpb_2024_108332 crossref_primary_10_1038_s42003_021_01768_0 crossref_primary_10_1186_s12911_020_01307_7 crossref_primary_10_1038_sdata_2018_74 crossref_primary_10_12688_f1000research_123515_4 crossref_primary_10_12688_f1000research_123515_3 crossref_primary_10_7717_peerj_4380 crossref_primary_10_12688_f1000research_123515_2 crossref_primary_10_12688_f1000research_123515_1 crossref_primary_10_1186_s12868_024_00864_1 crossref_primary_10_1038_s41597_024_04010_8 crossref_primary_10_1109_TNSRE_2020_3040264 crossref_primary_10_1109_ACCESS_2018_2842082 crossref_primary_10_1038_s41598_017_09187_0 crossref_primary_10_1088_1741_2552_ab2b61 crossref_primary_10_1088_1741_2552_ab4063 crossref_primary_10_3390_s23198214 crossref_primary_10_1038_s41598_020_60932_4 crossref_primary_10_1016_j_neuroimage_2018_03_048 crossref_primary_10_1080_00222895_2024_2373241 crossref_primary_10_1088_1741_2560_13_3_036006 crossref_primary_10_3390_app12010415 crossref_primary_10_3390_s17122725 crossref_primary_10_1016_j_bspc_2021_102741 crossref_primary_10_1177_00187208221141175 crossref_primary_10_1038_s41597_023_02243_7 crossref_primary_10_3389_fnins_2023_1154480 crossref_primary_10_1016_j_bspc_2022_103838 crossref_primary_10_1109_JBHI_2020_2965858 crossref_primary_10_1371_journal_pone_0165168 crossref_primary_10_3390_signals5020018 crossref_primary_10_1002_jdn_10166 crossref_primary_10_1016_j_physa_2016_11_105 crossref_primary_10_3389_fnhum_2017_00527 crossref_primary_10_3390_app11125573 crossref_primary_10_1088_1741_2552_ab9842 crossref_primary_10_4995_riai_2018_9861 crossref_primary_10_1186_s12984_017_0268_4 crossref_primary_10_1016_j_neuroimage_2022_119774 crossref_primary_10_1109_TBME_2019_2930186 crossref_primary_10_3389_fnins_2020_577160 crossref_primary_10_3389_fnhum_2021_749017 crossref_primary_10_1016_j_bbe_2021_06_007 crossref_primary_10_1109_TBME_2019_2921766 crossref_primary_10_1007_s00034_024_02936_3 crossref_primary_10_1007_s00221_024_06884_x crossref_primary_10_3389_fnins_2021_566004 crossref_primary_10_1038_s41598_021_89297_y crossref_primary_10_1080_17518423_2020_1756005 crossref_primary_10_1088_1741_2552_aaa8c0 crossref_primary_10_1088_1741_2552_aad7d7 |
| Cites_doi | 10.1002/9780470740156 10.1016/j.neuroimage.2009.06.023 10.1016/S1388-2457(00)00533-2 10.1016/j.clinph.2006.10.019 10.1109/TITB.2012.2207400 10.1073/pnas.1314681110 10.1007/BF02344717 10.1111/j.1469-8986.2010.01009.x 10.1016/j.jneumeth.2006.04.024 10.1109/TBME.2012.2225427 10.1109/ICASSP.1995.480332 10.1109/LSP.2005.859526 10.1109/IEMBS.2008.4650346 10.1109/EMBC.2013.6610821 10.1109/NER.2009.5109371 10.1049/iet-spr.2010.0135 10.1016/S0987-7053(00)00055-1 10.1109/NNSP.1998.710633 |
| ContentType | Journal Article |
| Copyright | 2016 IOP Publishing Ltd |
| Copyright_xml | – notice: 2016 IOP Publishing Ltd |
| DBID | AAYXX CITATION CGR CUY CVF ECM EIF NPM 7X8 7SC 8FD JQ2 L7M L~C L~D |
| DOI | 10.1088/1741-2560/13/2/026013 |
| DatabaseName | CrossRef Medline MEDLINE MEDLINE (Ovid) MEDLINE MEDLINE PubMed MEDLINE - Academic Computer and Information Systems Abstracts Technology Research Database ProQuest Computer Science Collection Advanced Technologies Database with Aerospace Computer and Information Systems Abstracts Academic Computer and Information Systems Abstracts Professional |
| DatabaseTitle | CrossRef MEDLINE Medline Complete MEDLINE with Full Text PubMed MEDLINE (Ovid) MEDLINE - Academic Computer and Information Systems Abstracts Technology Research Database Computer and Information Systems Abstracts – Academic Advanced Technologies Database with Aerospace ProQuest Computer Science Collection Computer and Information Systems Abstracts Professional |
| DatabaseTitleList | Computer and Information Systems Abstracts MEDLINE MEDLINE - Academic |
| Database_xml | – sequence: 1 dbid: NPM name: PubMed url: https://proxy.k.utb.cz/login?url=http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed sourceTypes: Index Database – sequence: 2 dbid: EIF name: MEDLINE url: https://proxy.k.utb.cz/login?url=https://www.webofscience.com/wos/medline/basic-search sourceTypes: Index Database |
| DeliveryMethod | fulltext_linktorsrc |
| Discipline | Anatomy & Physiology |
| DocumentTitleAlternate | A robust adaptive denoising framework for real-time artifact removal in scalp EEG measurements |
| EISSN | 1741-2552 |
| EndPage | 26028 |
| ExternalDocumentID | 26863159 10_1088_1741_2560_13_2_026013 jneaa1258 |
| Genre | Research Support, Non-U.S. Gov't Journal Article Research Support, N.I.H., Extramural |
| GrantInformation_xml | – fundername: National Institute of Neurological Disorders and Stroke (NINDS) grantid: R01NS075889-01 – fundername: The Cullen Foundation – fundername: Mission Connect project of TIRR Foundation – fundername: NINDS NIH HHS grantid: R01NS075889-01 – fundername: NINDS NIH HHS grantid: R01 NS075889 |
| GroupedDBID | --- 1JI 4.4 53G 5B3 5GY 5VS 5ZH 7.M 7.Q AAGCD AAJIO AAJKP AALHV AATNI ABHWH ABJNI ABQJV ABVAM ACAFW ACGFS ACHIP AEFHF AENEX AFYNE AKPSB ALMA_UNASSIGNED_HOLDINGS AOAED ASPBG ATQHT AVWKF AZFZN CEBXE CJUJL CRLBU CS3 DU5 EBS EDWGO EJD EMSAF EPQRW EQZZN F5P HAK IHE IJHAN IOP IZVLO KOT LAP M45 N5L N9A NT- NT. P2P PJBAE RIN RO9 ROL RPA SY9 W28 XPP AAYXX ADEQX CITATION 02O 1WK AERVB AHSEE ARNYC BBWZM CGR CUY CVF ECM EIF FEDTE HVGLF JCGBZ NPM Q02 RNS S3P 7X8 7SC 8FD JQ2 L7M L~C L~D |
| ID | FETCH-LOGICAL-c384t-537a6eefa008668b914a707b04c75b0bf6ad1e97d7abf05f9a004bfa624d66133 |
| IEDL.DBID | IOP |
| ISSN | 1741-2560 1741-2552 |
| IngestDate | Fri Jul 11 03:14:09 EDT 2025 Fri Jul 11 12:09:46 EDT 2025 Wed Feb 19 01:55:25 EST 2025 Thu Apr 24 22:50:06 EDT 2025 Tue Jul 01 01:58:36 EDT 2025 Wed Aug 21 03:33:55 EDT 2024 |
| IsPeerReviewed | true |
| IsScholarly | true |
| Issue | 2 |
| Language | English |
| LinkModel | DirectLink |
| MergedId | FETCHMERGED-LOGICAL-c384t-537a6eefa008668b914a707b04c75b0bf6ad1e97d7abf05f9a004bfa624d66133 |
| Notes | JNE-100863.R1 ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 |
| PMID | 26863159 |
| PQID | 1773807397 |
| PQPubID | 23479 |
| PageCount | 16 |
| ParticipantIDs | iop_journals_10_1088_1741_2560_13_2_026013 crossref_citationtrail_10_1088_1741_2560_13_2_026013 proquest_miscellaneous_1773807397 crossref_primary_10_1088_1741_2560_13_2_026013 pubmed_primary_26863159 proquest_miscellaneous_1825446161 |
| ProviderPackageCode | CITATION AAYXX |
| PublicationCentury | 2000 |
| PublicationDate | 2016-04-01 |
| PublicationDateYYYYMMDD | 2016-04-01 |
| PublicationDate_xml | – month: 04 year: 2016 text: 2016-04-01 day: 01 |
| PublicationDecade | 2010 |
| PublicationPlace | England |
| PublicationPlace_xml | – name: England |
| PublicationTitle | Journal of neural engineering |
| PublicationTitleAbbrev | JNE |
| PublicationTitleAlternate | J. Neural Eng |
| PublicationYear | 2016 |
| Publisher | IOP Publishing |
| Publisher_xml | – name: IOP Publishing |
| References | 11 12 13 Mullen T (6) 2013; 2013 14 Trieu P L (16) 2015 15 17 18 19 Jung T P (4) 1998 1 2 3 Jung T P (5) 1998 7 8 9 20 10 21 |
| References_xml | – ident: 7 doi: 10.1002/9780470740156 – start-page: 894 year: 1998 ident: 4 publication-title: Advances in Neural Information Processing Systems – ident: 2 doi: 10.1016/j.neuroimage.2009.06.023 – ident: 19 doi: 10.1016/S1388-2457(00)00533-2 – ident: 3 doi: 10.1016/j.clinph.2006.10.019 – ident: 8 doi: 10.1109/TITB.2012.2207400 – year: 2015 ident: 16 publication-title: 2015 Proc. Int. Conf. on Virtual Rehabilitation – ident: 21 doi: 10.1073/pnas.1314681110 – ident: 11 doi: 10.1007/BF02344717 – ident: 20 doi: 10.1111/j.1469-8986.2010.01009.x – ident: 1 doi: 10.1016/j.jneumeth.2006.04.024 – ident: 9 doi: 10.1109/TBME.2012.2225427 – ident: 12 doi: 10.1109/ICASSP.1995.480332 – ident: 13 doi: 10.1109/LSP.2005.859526 – ident: 14 doi: 10.1109/IEMBS.2008.4650346 – ident: 17 doi: 10.1109/EMBC.2013.6610821 – ident: 15 doi: 10.1109/NER.2009.5109371 – ident: 10 doi: 10.1049/iet-spr.2010.0135 – ident: 18 doi: 10.1016/S0987-7053(00)00055-1 – volume: 2013 start-page: 2184 year: 2013 ident: 6 publication-title: Conf. Proc.: Annual Int. Conf. IEEE Engineering in Medicine and Biology Society IEEE Engineering in Medicine and Biology Society Conf. – start-page: 63 year: 1998 ident: 5 publication-title: Neural Networks for Signal Processing VIII. Proc. 1998 IEEE Signal Processing Society Workshop doi: 10.1109/NNSP.1998.710633 |
| SSID | ssj0031790 |
| Score | 2.482498 |
| Snippet | Objective. Non-invasive measurement of human neural activity based on the scalp electroencephalogram (EEG) allows for the development of biomedical devices... Non-invasive measurement of human neural activity based on the scalp electroencephalogram (EEG) allows for the development of biomedical devices that interface... |
| SourceID | proquest pubmed crossref iop |
| SourceType | Aggregation Database Index Database Enrichment Source Publisher |
| StartPage | 26013 |
| SubjectTerms | Adult Blinking - physiology brain-computer interfaces brain-machine interfaces denoising EEG Electrodes Electroencephalography Electroencephalography - methods Electroencephalography - standards EOG Exercise Test - methods Exercise Test - standards Eye Movements - physiology Eyes Female Filtering Filtration Humans Male Real time real-time artifact removal Recording Scalp - physiology Signal Processing, Computer-Assisted |
| Title | A robust adaptive denoising framework for real-time artifact removal in scalp EEG measurements |
| URI | https://iopscience.iop.org/article/10.1088/1741-2560/13/2/026013 https://www.ncbi.nlm.nih.gov/pubmed/26863159 https://www.proquest.com/docview/1773807397 https://www.proquest.com/docview/1825446161 |
| Volume | 13 |
| hasFullText | 1 |
| inHoldings | 1 |
| isFullTextHit | |
| isPrint | |
| link | http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwpV1Lb9swDBbW7rLL2i7bmnYtNGDYYYAT25Il-RgM6WOHbocV6GmCaEtA0MQOGuew_fpSlp1uBdpi6M0wRIOmKPKjRFKEfLKxcsyYJEqdchFHJxKBEFmUF1ByK7iKoc22uBBnl_zbVXb1VxX_rF52pn-Ej6FRcBBhlxCnxoih8dPoqccJG6fjtikW2yIvmRLC32Fw_v1Hb4uZ7z8VSiIDSV_D89Bn_vFOW8jBw8CzdUAnO8T0rIe8k-vRuoFR8edeV8fn_Nsued2hUzoJ4_fIC1u9IYNJhZH54jf9TNt80XYjfkB-TehNDetVQ01plt5qUrRh9cxvPlDX53xRBMUUgek88rfYU8-Jr6XAV4salZzOKrpCNVnS6fSULu42LFdvyeXJ9OfXs6i7rSEqmOJNlDFphLXO-ChJKMgTbmQsIeaFzCAGJ0yZ2FyW0oCLM5fjQA7OiJSXCBIYe0e2q7qy-4TmzPIEUgkW5VE4bjDGgpxnhXUACtiQ8H6WdNG1Mvc3asx1e6SulPZy1F6OOmE61UGOQzLakC1DL4-nCL7gROluVa-eGvyx1xSNS9Sfu5jK1mskk9K39Ufk98gYH6lzgfh7SN4HNdvwmAolGMLOg_9h55C8QmwnQpLRB7Ld3KztEeKnBo7bJXILDXMKOg |
| linkProvider | IOP Publishing |
| linkToPdf | http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwpV1Lb9QwELbaIiEuvMpjgYKREAekbB52bOe4andpAZUeqNQTliexpYpuEnWzB_j1jONkEZXaCnGLIk80GY9nvrFnxoS8s4lyzJg0ypxyEUcnEoEQeVSUUHEruEqgz7Y4Foen_NNZfrZFDja1ME07mP4pPoZGwUGEQ0KcihFD46fRU8cpi7O4b4rF4rZy2-ROzgTzHfSPvp6M9pj5HlShLDKQjXU8133qLw-1jVxcDz57J7R4QOzIfsg9-TFddzAtf13p7Pi___eQ3B9QKp0Fmkdky9aPye6sxgh9-ZO-p33eaL8hv0u-z-hlA-tVR01lWm89Kdqy5txvQlA35n5RBMcUAepF5G-zp54bX1OBr5YNKjs9r-kK1aWl8_lHuvyzcbl6Qk4X82_7h9Fwa0NUMsW7KGfSCGud8dGSUFCk3MhEQsJLmUMCTpgqtYWspAGX5K7AgRycERmvECww9pTs1E1tnxNaMMtTyCRYlEnpuMFYCwqel9YBKGATwseZ0uXQ0tzfrHGh-6N1pbSXpfay1CnTmQ6ynJDphqwNPT1uI_iAk6WH1b26bfDbUVs0LlV__mJq26yRTErf3h8R4A1jfMTOBeLwCXkWVG3DYyaUYAg_X_wLO2_I3ZODhf5ydPz5JbmHcE-EvKNXZKe7XNs9hFQdvO5XzG9yAA-e |
| openUrl | ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.atitle=A+robust+adaptive+denoising+framework+for+real-time+artifact+removal+in+scalp+EEG+measurements&rft.jtitle=Journal+of+neural+engineering&rft.au=Kilicarslan%2C+Atilla&rft.au=Grossman%2C+Robert+G&rft.au=Contreras-Vidal%2C+Jose+Luis&rft.date=2016-04-01&rft.eissn=1741-2552&rft.volume=13&rft.issue=2&rft.spage=026013&rft_id=info:doi/10.1088%2F1741-2560%2F13%2F2%2F026013&rft_id=info%3Apmid%2F26863159&rft.externalDocID=26863159 |
| thumbnail_l | http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=1741-2560&client=summon |
| thumbnail_m | http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=1741-2560&client=summon |
| thumbnail_s | http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=1741-2560&client=summon |