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| ID | Type | Description | Link |
|---|---|---|---|
| 12-CC-0139 |
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Objective: In this study we will develop and apply imaging techniques to perform the first three-dimensional (3-D) measurements of brain biomechanics during mild head movement in healthy human subjects. Biomechanics is the application of mechanics, or the physical principles in action when force is applied to an object, to the anatomical structure and/or function of organisms. Such techniques will be invaluable for building computational models of brain biomechanics, understanding variability of brain biomechanics across individual characteristics, such as age and sex, and determining brain sub-structures at risk for damage when movement of the head is accelerated, such as during a traumatic event.
Study Population: Measurements will be performed on 90 healthy men and women aged 18-65.
Design: We will build upon the model pioneered by our collaborator, Dr. Philip Bayly. The model places a human subject in a magnetic resonance (MR) scanner with one of two head support units that allows a specific range of motion. Each head support is latched such that it can be released by the subject, and results in either a rotation of the head of approximately 30 degrees or a flexion-extension of the head of approximately 4 degrees. Although both supports are weighted so that the motion is repeatable if the subject is relaxed, the subject can easily counteract the weight. The resulting acceleration/deceleration is small (in the range of normal activities, such as turning one's head during swimming) and has been validated and used in other human investigations of brain biomechanics. The subject repeats the motion multiple times during the MR scan under their own volition and desired pace to measure motion of the head and brain.
Outcome measures: This project is a pilot study evaluating the potential of extracting three-dimensional estimates of brain deformation, such as strain measurements, using MR imaging. A primary outcome of this project will be a fast MR acquisition sequence for measuring 3-D brain deformation. The sequence will be evaluated by applying the protocol to human subjects, followed by preliminary quantification of the reproducibility and stability of deformation measurements.
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Objective
In this study we will develop and apply imaging techniques to perform the first three-dimensional (3-D) measurements of brain biomechanics during mild head movement in healthy human subjects. Biomechanics is the application of mechanics, or the physical principles in action when force is applied to an object, to the anatomical structure and/or function of organisms. Such techniques will be invaluable for building computational models of brain biomechanics, understanding variability of brain biomechanics across individual characteristics, such as age and sex, and determining brain sub-structures at risk for damage when movement of the head is accelerated, such as during a traumatic event. Using the developed imaging techniques above, we will acquire a sufficient number of data sets to create templates of the average brain response and stiffness based on age and sex. Anonymized raw and processed data will be made publicly available to improve computational models of brain biomechanics.
Study Population
Measurements will be performed on 194 healthy men and women aged 18-65.
Design
We will build upon the model pioneered by our collaborator, Dr. Philip Bayly. The model places a human subject in a magnetic resonance (MR) scanner with one of two head support units that allows a specific range of motion. Each head support is latched such that it can be released by the subject, and results in either a rotation of the head of approximately 30 degrees or a flexion-extension of the head of approximately 4 degrees. Although both supports are weighted so that the motion is repeatable if the subject is relaxed, the subject can easily counteract the weight. The resulting acceleration/deceleration is small (in the range of normal activities, such as turning one's head during swimming) and has been validated and used in other human investigations of brain biomechanics. The subject repeats the motion multiple times during the MR scan under their own volition and desired pace to measure motion of the head and brain. Additionally, we will use a type of MRI called magnetic resonance elastography (MRE), which measures brain motion in response to mild head vibration, to investigate brain stiffness.
Outcome measures
This project is a study evaluating the potential of extracting three-dimensional estimates of brain deformation, such as strain measurements and stiffness, using MR imaging. A primary outcome of this project will be MRI techniques for characterizing 3-D brain biomechanics. The techniques will be evaluated by applying the protocol to human subjects, followed by preliminary quantification of the reproducibility and stability of deformation and stiffness measurements. Acquired data will be made publicly available for use by the research community.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Healthy Volunteers | Healthy men and women aged 18-65 |
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| Measure | Description | Time Frame |
|---|---|---|
| technical development of a method for providing three-dimensional measurements of brain biomechanics in vivo using MR imaging. | Primary outcome of this project will be a fast MR acquisition sequence for measuring 3-D brain deformation. The sequence will be evaluated by applying the protocol to human subjects, followed by preliminary quantification of the reproducibility and stability of deformation measurements | Day 1 of study |
| Measure | Description | Time Frame |
|---|---|---|
| Measure of preliminary database of brain deformation | A preliminary database of brain deformation measurements from a healthy cohort will allow initial characterization of the variability of brain response across sex and age. | End of study |
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EXCLUSION CRITERIA:
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Healthy volunteers between age 18 and 65.
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| Name | Affiliation | Role |
|---|---|---|
| Daniel S Reich, M.D. | National Institutes of Health Clinical Center (CC) | Principal Investigator |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| National Institutes of Health Clinical Center | Bethesda | Maryland | 20892 | United States |
| PubMed Identifier | Type | Citation | Retractions |
|---|---|---|---|
| 8073323 | Background | Allen ME, Weir-Jones I, Motiuk DR, Flewin KR, Goring RD, Kobetitch R, Broadhurst A. Acceleration perturbations of daily living. A comparison to 'whiplash'. Spine (Phila Pa 1976). 1994 Jun 1;19(11):1285-90. doi: 10.1097/00007632-199405310-00017. | |
| 16083352 | Background | Bayly PV, Cohen TS, Leister EP, Ajo D, Leuthardt EC, Genin GM. Deformation of the human brain induced by mild acceleration. J Neurotrauma. 2005 Aug;22(8):845-56. doi: 10.1089/neu.2005.22.845. |
| Label | URL |
|---|---|
| NIH Clinical Center Detailed Web Page | View source |
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We are working on deciding if we will share IPD.
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| ID | Term |
|---|---|
| D000070642 | Brain Injuries, Traumatic |
| D006259 | Craniocerebral Trauma |
| ID | Term |
|---|---|
| D001930 | Brain Injuries |
| D001927 | Brain Diseases |
| D002493 | Central Nervous System Diseases |
| D009422 | Nervous System Diseases |
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| 19446645 | Background | Brun CC, Lepore N, Pennec X, Lee AD, Barysheva M, Madsen SK, Avedissian C, Chou YY, de Zubicaray GI, McMahon KL, Wright MJ, Toga AW, Thompson PM. Mapping the regional influence of genetics on brain structure variability--a tensor-based morphometry study. Neuroimage. 2009 Oct 15;48(1):37-49. doi: 10.1016/j.neuroimage.2009.05.022. Epub 2009 May 14. |
| 34157896 | Derived | Gomez AD, Bayly PV, Butman JA, Pham DL, Prince JL, Knutsen AK. Group characterization of impact-induced, in vivo human brain kinematics. J R Soc Interface. 2021 Jun;18(179):20210251. doi: 10.1098/rsif.2021.0251. Epub 2021 Jun 23. |
| D020196 |
| Trauma, Nervous System |
| D014947 | Wounds and Injuries |