Active delineation of Meyer's loop using oriented priors through MAGNEtic tractography (MAGNET).

Maxime Chamberland, Benoit Scherrer, Sanjay P Prabhu, Joseph Madsen, David Fortin, Kevin Whittingstall, Maxime Descoteaux, Simon K Warfield

January 2017 Hum Brain Mapp

Synopsis of Social media discussions

The discussions feature positive remarks like 'amazing work' and note the clever use of MAGNET in combining visual data, indicating interest and recognition of its practical implications. The tone suggests a respect for the technical advancement but stops short of broad revolutionary impact, reflecting moderate engagement and perceived influence.

A
Agreement
 Neither agree nor disagree

The posts express positive recognition of the study, but do not show strong disagreement or opposition.

I
Interest
 Moderate level of interest

The discussions indicate some curiosity, especially around the innovative technique MAGNET, but overall engagement remains moderate.

E
Engagement
 Moderate level of engagement

Posts include specific mentions of the researcher's work and its applications, showing some thoughtful engagement.

I
Impact
 Moderate level of impact

The discussions highlight the significance of MAGNET's improvements for neurosurgical planning, suggesting moderate to high perceived impact.

Social Mentions

YouTube

2 Videos

Twitter

3 Posts

Metrics

Video Views

3,777

Total Likes

41

Extended Reach

7,022

Social Features

5

Timeline: Posts about article

Top Social Media Posts

Posts referencing the article

Real-time Fiber Tracking and Visualization with FiberNavigator

Real-time Fiber Tracking and Visualization with FiberNavigator

Realtime tractography and visualization demo tutorial using the FiberNavigator. Explore advanced neuroimaging techniques for identifying and analyzing neural pathways, enhancing neurosurgical planning.

Maxime Chamberland

July 12, 2017

2,420 views

Enhanced Meyer's Loop Mapping with Magnetic Tractography

Enhanced Meyer's Loop Mapping with Magnetic Tractography

This video explains how MAGNETic Tractography improves the identification of Meyer's loop, a key part of the optic radiation, by using anatomical priors to overcome traditional MRI limitations. This advancement enhances preoperative planning to prevent vision loss in neurosurgery.

Maxime Chamberland

September 20, 2016

1,358 views

  • Thijs Dhollander
    @ThijsDhollander (Twitter)

    RT @MaxChamb: Amazing work by @dmitri_shastin on combining post-op visual fields with #tractography. Clever use of MAGNET
    view full post

    December 11, 2019

    3

  • Dmitri Shastin
    @dmitri_shastin (Twitter)

    RT @MaxChamb: Amazing work by @dmitri_shastin on combining post-op visual fields with #tractography. Clever use of MAGNET
    view full post

    December 11, 2019

    3

  • Maxime Chamberland
    @MaxChamb (Twitter)

    Amazing work by @dmitri_shastin on combining post-op visual fields with #tractography. Clever use of MAGNET
    view full post

    December 11, 2019

    17

    3

Abstract Synopsis

  • The article discusses how MAGNETic Tractography (MAGNET) improves the identification of Meyers loop, a crucial part of the optic radiation, by incorporating anatomical knowledge to overcome limitations of traditional diffusion MRI tractography, especially in highly curved and crossing fiber regions.
  • The authors introduce a new ROI mechanism that provides oriented priors, enhancing the accuracy of Meyers loop delineation, which is essential for neurosurgical planning to avoid vision deficits during temporal lobe surgeries.
  • Results from the study show that MAGNET outperforms standard deterministic tractography, achieving more complete coverage of Meyers loop and reducing key measurement distances by 1.67 mm, demonstrating its potential for improving preoperative assessments in children.]