AQMFB-DWT: A Preprocessing Technique for Removing Blink Artifacts Before Extracting Pain-evoked Potential EEG.

Wenjia GAO; Dan LIU; Qisong WANG; Yongping ZHAO; Jinwei SUN

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AQMFB-DWT: A Preprocessing Technique for Removing Blink Artifacts Before Extracting Pain-evoked Potential EEG.

Author: Wenjia GAO ¹ ; Dan LIU ² ; Qisong WANG ³ ; Yongping ZHAO ¹ ; Jinwei SUN ¹
Author Information

1. Harbin Institute of Technology, Harbin, 150001, China.
2. Harbin Institute of Technology, Harbin, 150001, China. liudan@hit.edu.cn.
3. Harbin Institute of Technology, Harbin, 150001, China. wangqisong@hit.edu.cn.
Publication Type:Journal Article
Keywords: Adaptive quadrature mirror filter banks; Blink artifact removal; Discrete wavelet transformation; Pain-evoked potential electroencephalography
MeSH: Humans; Artifacts; Blinking/physiology*; Electroencephalography/methods*; Pain/diagnosis*; Male; Wavelet Analysis; Adult; Female; Evoked Potentials/physiology*; Young Adult; Brain/physiopathology*; Pain Measurement/methods*; Signal Processing, Computer-Assisted
From: Neuroscience Bulletin 2025;41(12):2285-2295
CountryChina
Language:English
Abstract: The pain-evoked potential electroencephalogram (EEG) is an effective electrophysiological indicator for pain assessment, yet its extraction is challenging due to interference from background activity and involuntary blinks. Although existing blink artifact-removal methods show efficacy, they face limitations such as the need for reference signals, neglect of individual differences, and reliance on user input, hindering their practical application in clinical pain assessments. In this paper, we propose a novel framework applying adaptive quadrature mirror filter banks (AQMFB) with discrete wavelet transform (DWT) to remove blink artifacts in pain EEG. Unlike traditional DWT methods that apply fixed wavelets across subjects, our method adapts wavelet construction based on the characteristics of EEG. Experimental results demonstrate that AQMFB-DWT outperforms four leading methods in removing blink artifacts with minimal distortion of pain information, all within an acceptable processing time. This technique is a valuable preprocessing step for enhancing the extraction of pain-evoked potentials.