Meditation Enhances Small-World Network Efficiency: MEG-Based Evidence from Attention and Control Systems

Abstract

Introduction:

Brain networks and meditation have recently gained attention, with studies suggesting that more efficiently organized meditation brain networks are linked to better cognitive performance. This efficiency is exemplified in small-world brain networks, which combine local segregation with global integration, facilitating optimal information processing. This study examines the small-world propensity (SWP), a marker of neural efficiency, among three functional brain networks: the default mode network (DMN), fronto-parietal network (FPN), and attention network (AN) in three groups: advanced meditators (AM), beginner meditators (BM), and control meditators (CM).

Methods:

Using magnetoencephalography (MEG), we recorded 10-min meditation sessions from AM and BM groups practicing Surat-Shabda-Yoga meditation at different stages. The CM (baseline group), with no formal training in meditation, had introductory exposure to “four chakra meditation” and practiced the same. SWP was computed using coherence-based connectivity measures across frequencies ranging from 4 to 45 Hz during stable meditative states.

Results:

Significant differences were observed between meditators and non-meditators, with AM and BM groups compared with the CM group. Specifically, the AN in the AM group compared with CM exhibited higher SWP at the beta frequency range (19 Hz), while the FPN in the BM group compared with the CM showed increased SWP at the theta frequency range (8 Hz).

Discussion:

These findings highlight how meditation engages the brain’s intrinsic network architecture in a frequency- and stage-specific manner, supporting efficient information processing and offering a scientific basis for its cognitive and regulatory benefits.

Impact Statement

This study reveals how meditation naturally resonates with the brain’s intrinsic architecture, promoting efficient network organization through small-world topology. Using MEG and coherence-based connectivity, we demonstrate frequency-specific adaptations in key functional networks such as DMN, FPN, and -AN across meditation stages. These changes highlight how meditation leverages neural connectivity for optimized information processing by linking contemplative practice to intellectual benefits. It contributes to the field of brain connectivity by positioning meditation as a modulator of functional network dynamics with potential cognitive applications.

Keywords

functional connectivity graph analysis MEG neural efficiency small-world network Surat-Shabda-Yoga meditation

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