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enhanced survival of NSC. We used a controlled cortical impact device

to perform a TBI on immune-competent rats. Human NSCs were

transplanted into the rats 2 days after injury using FasL releasing aga-

rose hydrogels. The ability of FasL releasing hydrogels to induce T-cell

apoptosis and enhance NSC survival was analyzed 2 and 4 weeks after

injury (n

=

5 per animal group at each time point). Human NSC injec-

tions using cell media or agarose hydrogels were used as controls. We

found a significant enhancement of CD8

+

T cells expressing the apo-

ptosis marker caspase 8 in the rats injected with FasL releasing hy-

drogels in comparison to the control groups at 2 weeks post-injury.

Furthermore, the rats injected with FasL releasing hydrogels showed an

increase in the survival of human NSC at 2 and 4 weeks post-injury.

These results suggest that the FasL releasing hydrogels were successful

creating an immune-privileged zone around the NSC transplantation

site. The development of cell carrier strategies to induce localized

immune-suppression represents a novel approach to enhancing the

survival and efficacy of stem cell transplantation without systemically

affecting the patients’ immune system.

Keywords: Immune-suppression, xenografts, neural stem cell,

Traumatic brain injury

C7-05

ANALYSIS OF IBA-1 AND INFLAMMATORY RESPONSE IN

YOUNG ADULT MICE AFTER MILD TRAUMATIC BRAIN

INJURY

Michael Pezzillo

1,2

, Jennifer Charlton

1

, Alana Conti

1,2

1

John D DIngell VA Medical Center/Wayne State University School of

Medicine, Dept of Neurosurgery, Detroit, USA

2

Wayne State University School of Medicine, Dept of Psychiatry,

Detroit, USA

Mild traumatic brain injury (mTBI) makes up 70–80% of all TBI

cases in the USA. While mTBI’s deficits are often subtle, many

patients experience long-term neurological, cognitive, and behav-

ioral problems following injury. This study highlights the imperative

need to reduce the consequences of mTBI by examining the in-

flammatory response and upregulation of the ionized calcium-bind-

ing adaptor molecule 1 (Iba-1) in activated microglia. A mouse

model of mTBI was used to measure Iba-1 levels in various brain

regions to determine the specific time point, location and severity of

inflammation.

Anesthetized male young adult mice were administered a mild,

midline impact over intact skull and sham surgery was used as a

control. Brains were harvested at 6, 24, 48, and 72-hours, and 7-day

time points post-injury (n

=

3 per time point) and tissues prepared for

immunohistochemistry using antibodies against Iba-1.

Qualitative analysis was completed through the examination of the

morphological state of the microglia identified by positive Iba-1

staining. Microglia were classified as ramified (spiny) as unactivated

or amoeboid (smooth) as activated microglia. The degree of inflam-

mation was categorized as

+

(mild),

++

(moderate), and

+ + +

(severe)

and the state of activated response was measured.

Analysis established the greatest activated response occurred be-

tween 24 and 48-hours in mTBI mice. At these time points the

impact site, arcuate nucleus, and optic tract demonstrated the highest

degrees of inflammation in mTBI mice when compared with sham

controls. Also at the same time point, the nucleus accumbens, corpus

callosum, caudate putamen, and cortex demonstrated a moderate

response when compared with sham controls. The initial point of

increase in microglia activation was noted at the 24-hour time point,

except the optic tract, which had a robust response at the 6-hour time

point. The data may suggest parameters for a therapeutic window,

where targeted reduction in inflammation may limit the effects of

mTBI.

Keywords: mTBI, Iba-1, inflammatory response, immunohisto-

chemistry

C7-06

PERIPHERAL IMMUNE RESPONSE AFTER PEDIATRIC

TRAUMATIC BRAIN INJURY IN RABBIT

Lindsey Rasmussen

, Zhi Zhang, Manda Saraswati, Sujatha Kannan,

Courtney Robertson

Johns Hopkins Hospital, Anesthesiology and Critical Care Medicine,

Baltimore, USA

Background:

Increased levels of inflammatory cytokines and bio-

markers from the cerebral spinal fluid and brain have been found

following traumatic brain injury (TBI) in humans and in animal

models. However, inflammatory changes outside the brain in the pe-

ripheral immune system after TBI are less well studied. More spe-

cifically, the peripheral inflammatory response in pediatric TBI

remains largely unknown.

Objective:

To define changes in pro and anti-inflammatory pro-

cesses in the peripheral immune system in the acute and sub-acute

time period following pediatric TBI.

Methods:

Rabbit kits (n

=

64) from the same litter were randomly

divided into naı¨ve (no intervention), sham (craniotomy alone), and

TBI (controlled cortical impact; 6 mm impactor tip; 5.5 m/s, 2 mm

depth) groups. Spleens and peripheral blood were collected at 6 hrs, 1

day, 3 days, and 7 days post-injury. The mRNA levels of TNF-alpha,

IL1-Beta, IL10, IL-4, IL-6, YM1 and TGF-beta in the spleens and

peripheral blood were analyzed by real-time PCR. Spleens also un-

derwent immunohistochemical analysis for presence and quantifica-

tion of inflammatory cells.

Results:

Results show a decrease in anti-inflammatory cytokines

present in the TBI spleens at 6 hr and 1 day with no significant change

in pro-inflammatory cytokines, compared with naı¨ve and sham

groups. YM1 was found to be significantly increased in spleens 7 days

post injury. Aside from YM1, no change in pro or anti-inflammatory

cytokines was noted in the spleens at 3 or 7 days post injury.

Conclusion:

The response of the pediatric peripheral immune

system to TBI is differentially regulated following insult. Anti-

inflammatory cytokines circulating peripherally appear to preferen-

tially attenuate in the acute period post TBI. Recognition of these

alterations in the peripheral immune system may direct peripherally

administered therapies and testing for TBI in the future.

Keywords: traumatic brain injury, spleen, cytokine, inflammation

C7-07

NEUROINFLAMMATION IN A RABBIT MODEL OF PEDIA-

TRIC TRAUMATIC BRAIN INJURY

Zhi Zhang

, Manda Saraswati, Raymond Koehler, Courtney

Robertson, Sujatha Kannan

Johns Hopkins School of Medicine, ACCM, Baltimore, USA

Neuroinflammation following TBI is a major player in the secondary

response post-injury contributing to widespread cell death and tissue loss.

Microglial distribution and function in the developing brain plays an

important role in the inflammatory response following TBI in the im-

mature brain. In this study, we evaluated the sequential inflammatory

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