T1-03

COMPUTATIONAL MODELING AND VALIDATION OF

BRAIN DEFORMATION IN HUMAN VOLUNTEERS WITH

RELEVANCE TO TRAUMATIC BRAIN INJURY

Shailesh Ganpule

1

, Nitin Daphalapurkar

1

, Andrew Knutsen

2

, Dzung

L. Pham

2

, K.T. Ramesh

1

1

Johns Hopkins University, Hopkins Extreme Materials Institute,

Baltimore, USA

2

The Henry M. Jackson Foundation for the Advancement of Military

Medicine, Radiology and Imaging Sciences, Bethesda, USA

Background:

Knowledge of how brain deforms under physical forces

is critical for understanding mechanics of TBI and for developing

methods of prevention. The objective of this work is to compare

deformation field obtained from the computer simulations with the

experimental measurements of full-field deformation field in human

brains.

Methods:

To this end, we have developed subject-specific com-

putational models of the human brain in human volunteers for which

experimentally measured in vivo brain deformations are also avail-

able. For computational modeling of each subject, we incorporate

information on brain morphology and white matter anisotropy from

acquired T1-weighted and DTI scans, respectively. Computational

simulations are performed using the Material Point Method (MPM).

Loading conditions for the simulations are obtained directly from the

experiments. The experiments involved sub-injurious rotational ac-

celeration of the head about the inferior/superior axis with a peak

angular accelerations of 200–250 rad/s

2

. Dynamic deformation in each

subject was measured using tagged MRI during the accelerations.

Results:

The results of simulations are compared against the ex-

perimentally measured in vivo deformations (displacement and strain

fields). Good agreement was seen between the simulations and the

experiments in terms of predicted deformation patterns. Simulation

results suggest that in these cases the brain deformation is dominated

by shearing modes with peak shearing strains on the order of 4–6% in

various substructures of the brain. It is also observed that global

shearing of a brain tissue leads to local stretching in various sub-

structures of the brain. Subject specific changes in morphology and

anisotropy of brain tissue had an effect on the predicted local defor-

mation pattern, although the global deformation pattern remained

similar.

Conclusion:

By combining state-of-the-art neuroimaging tech-

niques with the computational mechanics based analysis, we elucidate

mechanics of brain deformation in a living human brain.

Keywords: Brain Biomechanics, Computational Model, Tagged

MRI, Validation

T1-04

ADOLESCENT BRAIN INJURY INDUCES CHRONIC MESO-

LIMBIC NEUROINFLAMMATION THAT COINCIDES WITH

ENHANCED ADDICTION-LIKE BEHAVIOR IN MICE

Steven Merkel

1,2

, Christopher Tallarida

2,4

, Roshanak Razmpour

1

,

Evan Lutton

1

, Yuri Persidsky

1,2

, Scott Rawls

2,4

, Servio Ramirez

1–3

1

Temple University School of Medicine, Department of Pathology and

Laboratory Medicine, Philadelphia, USA

2

Temple University School of Medicine, Center for Substance Abuse

Research, Philadelphia, USA

3

Shriners Hospitals, Pediatric Research Center, Philadelphia, USA

4

Temple University School of Medicine, Department of Pharmacol-

ogy, Philadelphia, USA

Substance use disorder is one of the most prevalent clinical psychiatric

diagnoses among traumatic brain injury (TBI) patients. Recent epide-

miological data suggests that 1) patients sustaining adolescent TBIs

experience greater behavioral issues with substance abuse than control

subjects, and 2) a history of TBI appears to be a possible risk factor

contributing to the onset of cocaine use. Notably, virtually no data exists

examining whether the preference for illicit drugs of abuse is affected

by adolescent brain injury. Using the controlled cortical impact model

of TBI coupled with the conditioned place preference (CCP) assay, we

test the hypothesis that brain injury during adolescence exacerbates the

reinforcing properties of cocaine in adulthood by affecting function of

the reward pathway. Six-week old, male C57BL/6 mice sustained a

single impact TBI of varying severity (mild or moderate) to the right

somatosensory cortex. CPP pre-testing began 2 weeks post-TBI, fol-

lowed by 6 days of intraperitoneal cocaine administration (10mg/kg).

The place preference shift was significantly enhanced in all treatment

groups receiving cocaine compared to saline controls; furthermore, a

moderate TBI during adolescence caused a significant increase in the

place preference shift compared to non-surgical cocaine controls. Few

reports have examined the presence and potential of mesolimbic neu-

ropathology following brain injury. Using GFAP and IBA-1 immuno-

fluorescence, we have observed persistent neuroinflammatory responses

in the nucleus accumbens and ventral tegmental area following TBI.

These results suggest that sustaining a moderate TBI during adoles-

cence may augment addiction-like behavior in adulthood possibly re-

lated to mesolimbic neuroinflammation.

Keywords: Controlled Cortical Impact, Conditioned Place Pre-

ference, Cocaine, Mesolimbic Nuclei, Astrocyte, Microglia

T1-05

COGNITIVE DEFICITS DEVELOP 30D AFTER TBI AND ARE

EXAGGERATED BY MICROGLIA-ASSOCIATED RE-

ACTIVITY TO PERIPHERAL IMMUNE CHALLENGE

Megan Muccigrosso

1

, Joni Ford

1

, Chris Burnsides

1

, Ashley Fenn

1

,

Phillip Popovich

1

, Jonathan Lifshitz

2

, Rohan Walker

3

, Daniel

Eiferman

1

, Jonathan Godbout

1

1

The Ohio State University, Neuroscience, Columbus, USA

2

Arizona University, Barrow Neurological Institute, Phoenix, USA

3

The University of Newcastle, Biomedical Sciences, New Castle,

Australia

Traumatic brain injury (TBI) elicits immediate neuroinflammatory

events that contribute to acute cognitive, motor, and behavioral dis-

turbance. Despite resolution of these acute complications, cognitive

impairment can develop after TBI. We have reported that a moderate

midline fluid-percussion injury leads to a population of ‘‘primed’’

(MHCII

+

) microglia that develop and persist 1 month after injury.

Moreover, these primed microglia are hyper-reactive to immune

challenge and this is associated with amplified neuroinflammation and

onset of depressive-like behavior. Therefore, the objective of this

study was to determine the degree to which microglia priming and

immune-reactivity causes cognitive impairment. Using the Barnes

maze, a hippocampal-dependent learning-memory task, we show that

a diffuse TBI interrupts retrograde memory acutely 7d after injury.

Yet 7d after injury there were no acute deficits in anterograde learn-

ing. By 30d after TBI, however, significant anterograde learning im-

pairments developed in TBI mice in the acquisition of the memory

task. Moreover these cognitive deficits at 30d after TBI were exag-

gerated by peripheral immune challenge. For instance, 72h after LPS

injection, TBI-LPS mice had more errors, increased time to find the

escape, and spent less time in the escape quadrant during the probe

trial. These deficits were not associated with alteration in the number

A-3