Courses:

Functional Magnetic Resonance Imaging: Data Acquisition and Analysis >> Content Detail



Syllabus



Syllabus


Amazon logo When you click the Amazon logo to the left of any citation and purchase the book (or other media) from Amazon.com, MIT OpenCourseWare will receive up to 10% of this purchase and any other purchases you make during that visit. This will not increase the cost of your purchase. Links provided are to the US Amazon site, but you can also support OCW through Amazon sites in other regions. Learn more.

This page includes the course calendar.



Course Overview


This team taught, multidisciplinary course covers the fundamentals of magnetic resonance imaging relevant to the conduct and interpretation of human brain mapping studies. The challenges inherent in advancing our knowledge about brain function using fMRI are presented first to put the work in context. The course then provides in depth coverage of the physics of image formation, mechanisms of image contrast, and the physiological basis for image signals. Parenchymal and cerebrovascular neuroanatomy and application of sophisticated structural analysis algorithms for segmentation and registration of functional data are discussed. Additional topics include fMRI experimental design including block design, event related and exploratory data analysis methods, building and applying statistical models for fMRI data. Human subjects issues including informed consent, institutional review board requirements and safety in the high field environment are presented.



Prerequisites


Linear Algebra (e.g. 18.06) and Differential Equations (e.g. 18.03). Introductory or college level courses in neurobiology (e.g. 9.01), physiology, probability (e.g. 6.041), and physics (e.g. 8.01 and 8.02) are preferred.



Required Textbook


Amazon logo Huettel, S. A., A. W. Song, and G. McCarthy. Functional Magnetic Resonance Imaging. Sunderland, MA: Sinauer Associates, Inc., 2004. ISBN: 9780878932887.

This book will be supplemented by readings in the research literature and other books.



Course Format


The course employs two 60 minutes lectures per week, along with weekly laboratory and recitation sessions. Laboratory sessions will include fMRI data acquisition sessions and data analysis workshops. Assignments include reading of the primary textbook chapters and primary literature, fMRI data analysis in the laboratory, and several problem sets.

The majority of the computer labs will be run using Neurolens fMRI Analysis software, Slicer software, and MATLAB®.



Calendar



SES #LECTURESLABSDISCUSSIONSKEY DATES
Overview (Primary faculty: Randy Gollub)
1

Introduction to the course (Gollub)

Introduction to fMRI (Rosen)

Functional neural systems (Primary faculty: Brad Dickerson)
2

MRI safety training (Gollub)

Lab 1: fMRI acquisition labs I, II (S. Gabrieli, Triantafyllou)

Problem set 1 out
3Neural systems I, II (Dickerson)
4Neural systems III (Dickerson)Lab 2: intro to fMRI data and analysis (Bolar)
Imaging physiology (Primary faculty: Randy Gollub)
5Respiratory and cardiovascular physiology impact on fMRI (Banzett)

Human subject safety issues (Gollub)

Problem set 1 due

Problem set 2 out

6Cerebrovascular anatomy and neural regulation of CNS blood flow (Dickerson)Concurrrent learning and imaging (J. Gabrieli)
7Neurovascular coupling; global vs. regionally specific changes in CBF and metabolism (Dickerson)Lab 3: improving fMRI signal detection using physiological data (Melcher)Lab 2 due
Physics of image acquisition (Primary faculty: Larry Wald, Karl Helmer)
8MRI physics I (Helmer)Parallel imaging (Sodickson)
9MRI physics II and III (Wald)

Problem set 2 due

Problem set 3 out

10Physics of diffusion weighted imaging (Helmer)Lab 4: the life cycle of medical imaging data (Pujol)
11Clinical applications of perfusion weighted imaging (Sorensen)Understanding the issues in the controversial papers on face perception in autism (Hadjikhani)Lab 3 due
12Lab 5: MRI physics lab I, II (Wald, Triantafyllou)
13Quantitative fMRI: CBV, CBF, and ASL (Mandelville)Modeling the BOLD signal: CBV/CBF methods and applications (Mandeville)
Experimental design (Primary faculty: Robert Savoy)
14General principles of experimental design I (Savoy)Lab 6: diffusion weighted imaging workshop (Pujol)Lab 4 due
15General principles of experimental design II (Savoy)fMRI investigation of memory (Buckner)
16Psychological state variables in imaging (Savoy)Primer: matrix algebra for fMRI data (Greve)Problem set 3 due
Mid-term exam
Statistical analysis (Primary faculty: Doug Greve, Mark Vangel, Anastasia Yendiki)
17

Stats I (Greve)

Lab 7: statistical analysis of fMRI data, part I (Yendiki)Problem set 4 out
18Stats II (Greve)Reconciling discrepent fMRI findings (Manoach)Lab 5 due
19Stats III (Greve)Lab 7: statistical analysis of fMRI data, part II (Yendiki)Lab 6, 7 part I due
20Beyond the GLM; exploring connectivity in fMRI data (Vangel, Greve)Linking blood flow to neural activity (Moore)
21Stats IV (Greve)Lab 7: statistical analysis of fMRI data, part III (Yendiki)
22Stats V (Vangel)fMRI evaluation of neural plasticity in somatosensory cortical representation (Napadow)Problem set 4 due
Structural and functional analysis (Primary faculty: David Salat)
23Spatial normalization for anatomical analysis (Kennedy)Lab 7: statistical analysis of fMRI data, part IV (Yendiki)Lab 7 part II, part III due
24Diffusion tensor imaging applications (Gollub)fMRI investigation of visual processing (Kanwisher)

Problem set 4 due

Lab 7 part IV due after two days

25Surface based anatomical analysis (Salat)Final exam preparation (Bolar)
26Future directions in functional neuroimaging (Gollub)Extra TA office hours (Bolar)
Final exam

 








© 2009-2020 HigherEdSpace.com, All Rights Reserved.
Higher Ed Space ® is a registered trademark of AmeriCareers LLC.