(

p

cluster

<

0.005,

p

voxel

<

0.005). This resulted in spatially distinct

correlation patterns of amygdala connectivity with the Buckley cog-

nitive, affective and somatic factors of the Beck Depression In-

ventory-II. These results indicate that amygdala connectivity may be a

potentially effective neuroimaging biomarker for comorbid depressive

symptoms among chronic TBI individuals.

Keywords: Amgydala, fMRI, Resting-state, functional connectivity,

Depression, TBI

T1-17

SLOWED CALLOSAL FUNCTION IN TBI LINKED TO

IMPAIRED WHITE MATTER INTEGRITY

Emily Dennis

1

, Monica Ellis

2,9

, Sarah Marion

9

, Claudia Kernan

2

,

Talin Babikian

2

, Richard Mink

3

, Christopher Babbitt

4

, Jeffrey

Johnson

5

, Christopher Giza

6

, Paul Thompson

1,7

, Robert Asarnow

8

1

Keck SOM USC, IGC, NII, Los Angeles, USA

2

UCLA, Dept. Psychiatry Biobehav Sciences, Los Angeles, USA

3

Harbor-UCLA Medical Center & Los Angeles BioMedical Research

Institute, Torrance, USA

4

Miller Children’s Hospital, Long Beach, USA

5

LAC

+

USC Medical Center, Dept. Pediatrics, Los Angeles, USA

6

Mattel Children’s Hospital, UCLA Brain Injury Research Center,

Dept. Neurosurg, Div. Ped Neurol, Los Angeles, USA

7

USC, Dept. Neurology, Pediatrics, Psychiatry, Radiology, En-

gineering, and Ophthalmology, Los Angeles, USA

8

UCLA, Dept. Psychology, Los Angeles, USA

9

Fuller Theological Seminary, Grad School Psychology, Pasadena,

USA

The corpus callosum is the most widely reported area of disruption

in traumatic brain injury (TBI). Here we present data linking dis-

rupted corpus callosum (CC) integrity to slowed callosal function in

pediatric moderate/severe TBI in the post-acute phase (1–6 months

post injury). We examined 63 participants: 32 TBI (mean age

=

14.2,

9 female), and 31 controls (mean age

=

14.9, 14 female). We used

visual ERPs (event related potentials) to measure IHTT (inter-

hemispheric transfer time, msec). EEG was recorded during a visual

pattern matching task. To assess white matter integrity, we used a

method developed in our lab, autoMATE (automated multi-atlas

tract extraction), to generate along-tract measures of fiber integrity.

The distribution of IHTTs showed a bimodal distribution within the

TBI group: some had IHTTs within 1.5 SD from the control mean,

but others differed significantly (group cut-off

=

18 msec min). We

ran an element-wise linear regression testing for differences in FA

and MD between the IHTT-slow TBI group and controls, and the

IHTT-normal TBI group and controls. IHTT-slow and control

groups differed significantly: the IHTT-slow group had lower FA

and higher MD across large areas of the CC and beyond. There were

minimal differences in FA between the IHTT-normal and control

groups, and none in MD. Our results indicate that TBI can cause

damage to myelin integrity, impairing the function of those tracts.

Keywords: IHTT, ERP, DTI, pediatric, traumatic brain injury,

corpus callosum

T1-18

INTRANASAL INSULIN TREATMENT OF TRAUMATIC

BRAIN INJURY: EFFECTS ON MEMORY AND CEREBRAL

METABOLISM

Fiona Brabazon

1

, Colin Wilson

2

, Shalini Jaiswal

2

, William H. Frey

3

,

Kimberly Byrnes

1,4

1

USUHS, Neuroscience Graduate Program, Bethesda, USA

2

USUHS, Department of Radiology, Bethesda, USA

3

University of Minnesota, Department of Neurology, Oral Biology

and Neuroscience, Minneapolis, USA

4

USUHS, Department of Anatomy, Physiology, and Genetics, Be-

thesda, USA

Traumatic brain injury (TBI) is often followed by a period of ce-

rebral hypometabolism. Impaired cerebral glucose uptake directly

affects long term patient outcome and is associated with cognitive

and physical deficits. Intranasal insulin, which bypasses the blood

brain barrier (BBB) to directly treat the brain, increases cerebral

glucose uptake in Alzheimer’s disease patients, and significantly

improves memory function in these patients. Our preliminary data

has demonstrated that 7 days of intranasal insulin treatment in-

creased speed of completion of a beam walk task in a rodent model

of TBI and increased viability of neurons and the number of anti-

inflammatory microglia in the hippocampus. We therefore hypoth-

esized that intranasal insulin would rescue cerebral metabolic

function and cognitive deficit resulting from TBI in a chronic

treatment model.

Adult male Sprague Dawley rats were exposed to a moderate

controlled cortical impact (CCI) injury followed by intranasal insulin

or saline treatment beginning 4 hours post-injury and continuing with

daily administration for 14 days. Positron emission tomography (PET)

scanning of radioactively labeled glucose (FDG

18

) was performed

prior to injury and again at 48 hours and 10 days post-injury. A

significant depression in glucose uptake was observed in both insulin

and saline treated groups, but a trend towards returning to baseline

values was observed in the ipsilateral hippocampus and hypothalamus

of the insulin treated group at 10 days post injury. Cognitive testing

with the Morris water maze revealed that intranasal insulin signifi-

cantly increased memory function in comparison to saline treatment,

as measured by probe trial island crosses. An analysis of the search

strategy used during the probe trial revealed that the insulin treated

animals performed significantly better than saline treated animals.

Tissue was also collected for assessment of macrophage and astrocyte

activity and neuronal viability.

Overall, we now show that intranasal insulin increases memory

function and has the potential to increase cerebral glucose uptake after

TBI. These data support our hypothesis that intranasal insulin, a drug

approved for clinical trials for the treatment of Alzheimer’s disease, is

effective in improving outcome following TBI.

Keywords: memory, insulin, PET, FDG18

T1-19

THE ROLE OF THE ATP-SENSITIVE POTASSIUM CHAN-

NEL IN THE VASCULAR DYSFUNCTION ASSOCIATED

WITH REPETITIVE MILD TRAUMATIC BRAIN INJURY

Masaki Todani

1,2

, Enoch Wei

1

, John Povlishock

1

1

Virginia Commonwealth University, Anatomy and Neurobiology,

Richmond, USA

2

Yamaguchi University Hospital, Advanced Medical Emergency and

Critical Care Center, Ube, Japan

Traumatic brain injury (TBI) has been associated with impaired ATP-

sensitive potassium (K

ATP

) channel function in both the neuronal and

vascular compartments. Both L-arginine and L-lysine are required to

activate the K

ATP

channel and exert both neuronal and vascular pro-

tection. While these protective effects have been confirmed following

uncomplicated TBI, their potential beneficial effects following re-

petitive TBI have not been established. In this study, we investigated

A-8