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tended to be associated with time until death (p

=

0.09), suggesting

that TNF

a

levels account for some E2 variance influencing mortal-

ity. Acute serum TNF

a

and E2 were highly correlated (r

=

0.54,

p

= <

0.001) among non-survivors, but not among survivors (r

=

0.10,

p

=

0.38). Sub-acute serum TNF

a

and E2 were not correlated (r

=

-

0.08, p

=

0.64). Acute serum and CSF TNF

a

showed a modest

correlation (r

=

0.21, p

=

0.05), but age-adjusted CSF TNF

a

levels

were not associated with mortality (p

=

0.07). Acute serum TNF

a

was associated with E2 and 6-month mortality risk, suggesting

possible systemic TNF

a

mortality effects. Future studies should

examine whether acute serum TNF

a

manipulation might impact

acute E2 production and survival post-TBI.

Keywords: rehabilomics, Tumor Necrosis Factor-

a

, estradiol, se-

rum

C7-19

ANTI-INFLAMMATORY DRUGS SHIFT PROPORTIONS OF

ACTIVATED MICROGLIA FOLLOWING EXPERIMENTAL

DIFFUSE BRAIN INJURY

Jack Reddaway

3,1,2

, Jenna Ziebell

1,2

, Megan Evilsizor

1,2

, Aida

Khodadad

1,2

, Ryan Hart

1,2

, Jonathan Lifshitz

1,2

1

University of Arizona, Child Health, Phoenix, USA

2

Barrow Neurological Institute at Phoenix Children’s Hospital, Child

Health, Phoenix, USA

3

University of Bath, Biology and Biochemistry, Bath, UK

Neuroinflammation contributes to secondary pathology of diffuse

traumatic brain injury (TBI). If not tightly controlled, neuroinflamma-

tion may modify the function of neuronal circuits. Circuits govern be-

havior; with alterations to circuits behavioral morbidities can eventuate.

We hypothesized that over the counter anti-inflammatory drugs would

mitigate neuroinflammation (microglial activation) thus reducing be-

havioral morbidities following experimental diffuse TBI in rats. To

model moderate diffuse TBI, adult male rats were subjected to mid-

line fluid percussion injury. Fifteen minutes post-injury, rats were

injected (intraperitonealy) with acetaminophen (40 or 20 mg/kg), as-

pirin (20 or 10 mg/kg), ibuprofen (60 or 20 mg/kg) or equal volume

vehicle. Subsequent injections were given twice daily for one week.

Sham rats were not included, as no changes in neuroinflammation

occur with surgery. Brains were collected 7 days post-injury (dpi), and

immunostained for microglia (Iba-1). Microglial proportions (rami-

fied, activated, rod or amoeboid) were analyzed in the sensory cortex,

a region harboring neuropathology. Sensory cortex of vehicle-treated

rats had predominantly activated microglia. Acetaminophen and

ibuprofen treated rats, showed a shift in the proportion of activated

microglia towards ramified morphology in sensory cortex. Whereas,

aspirin-treated rats showed a shift in proportion of activated microglia

to rod microglia in sensory cortex. To determine the effects of treat-

ment on neuroinflammation and behavior, an additional group of rats

were brain-injured and treated with acetaminophen (40 mg/kg), aspi-

rin (20 mg/kg), or vehicle. Treatments were chosen due to effective-

ness in shifting microglial proportions without excessive weight loss

(noted in ibuprofen groups). Behavioral morbidity was assessed in

brain-injured rats via the whisker nuisance task at 28 dpi. Over the

counter anti-inflammatory drugs have the capacity to alter neuroin-

flammation. We suggest that shifts in proportions away from activated

microglia will be associated with reduced behavioral morbidities.

Partially supported by NIH NINDS R01NS065052 and PCH Mission

Support Funds.

Keywords: Microglia, Anti-inflammatory drugs, Behavioral mor-

bidity, Diffuse brain injury

C7-20

P75NTR MEDIATES SYSTEMIC INFLAMMATORY RE-

SPONSES BY MODULATING DIFFERENTIATION OF MYE-

LOID CELLS

Sangmi Lee

1

, Neel Singhal

1

, Amity Lin

1

, Jeff Sacramento

1

, Leda

Mannent

2

, Marie-Noelle Castel

2

, Benoit Canolle

2

, Sandrine Delbary-

Gossart

2

, Badia Ferzaz

2

, Jacqueline Bresnahan

1

, Michael Beattie

1

1

University of California San Francisco, Brain and Spinal Injury

Center, Department of Neurological Surgery, San Francisco, USA

2

Sanofi, R&D, Chilly-Mazarin, France

Traumatic brain injury (TBI) leads to pro-inflammatory responses in

both CNS and peripheral organs. The inflammatory responses may be

involved in the subsequent development of clinical systemic inflam-

matory response syndrome, which eventually causes immune dys-

function and increases susceptibility to infection in chronic TBI

patients.

Previously, we found that blocking the p75NTR signaling pathway

by SARA, a selective p75NTR antagonist, inhibits tissue damage and

increases functional behavioral outcomes after cortical contusion in-

jury (CCI) TBI in rats. Strikingly, blocking p75NTR signaling reduces

microglia activation as well as leukocyte trafficking into the injured

brain.

Here, we demonstrated the possible role of p75NTR in peripheral

immune cell responses after TBI. Using a CCI-TBI model in C57Bl/6

WT mice, flow cytometric analysis showed that the population of

inflammatory monocytes (CD11b

+

Ly6C

high

) was significantly in-

creased in circulation and the injured brain at 1 week, but down-

regulated at 6 weeks after TBI. However, the population of mature

myeloid cells (CD45

high

CD11b

+

, CD45

high

CD11b

+

F480

+

and

CD45

high

CD11b

+

CD11c

+

) was significantly increased and accumu-

lated in the injured brain for 6 weeks after TBI. Interestingly, in-

flammatory monocytes (CD11b

+

Ly6C

high

) were accumulated in

spleen after TBI. We also demonstrated significantly increased gene

expression of pro-inflammatory mediators by qRT-PCR in spleen after

TBI. Interestingly, mice treated with daily SARA reduced the number

of inflammatory monocytes/macrophages in circulation, the injured

brain, and spleen. In addition, SARA treatment results on the inhi-

bition of TBI-induced pro-inflammatory mediators in the spleen.

Further, we found that TBI reduces TCR signaling, which was re-

versed by SARA.

Together, our new findings suggest that p75NTR mediates pro-

inflammatory responses by modulating myeloid differentiation in

circulation and SARA restores T cell function in spleen, which is

critical for immune susceptibility and may contribute to the thera-

peutic effects of SARA after TBI.

Keywords: p75NTR, traumatic brain injury, systemic inflammation,

inflammatory monocytes

C7-21

SIMULTANEOUS EXPRESSION OF M1/M2 MACROPHAGE

POLARIZATION PHENOTYPES FOLLOWING TBI

Lara-Kirstie Riparip,

Josh Morganti

, Susanna Rosi

UCSF, Neurosurgery, San Francisco, USA

Focal traumatic brain injury induces a wide array of inflammatory

responses principally mediated by cells of the innate immune sys-

tem, such as microglia and macrophages. Much attention has been

paid as of late to categorize the neuroinflammatory response fol-

lowing TBI within the linear constraints of macrophage polarization

A-93