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a clinical setting. Li and VAP robustly improved neurological re-

covery when given soon in this model that mimics a ploytraumatic

clinical situation.

Keywords: Hypotension, Lithium, Valproate, Mild Traumatic Brain

D8-05

LOWERING TUMOR NECROSIS FACTOR-

a

SYNTHESIS

AMELIORATES NEURONAL AND COGNITIVE LOSS

AFTER MILD TRAUMATIC BRAIN INJURY IN MICE

Barry Hoffer

1

, Alan Hoffer

1

, Renana Baratz

2

, Chaim Pick

2

, Nigel

Greig

3

1

Case Western Reserve University, Neurosurgery, Cleveland, USA

2

Sackler School of Medicine, Tel-Aviv University, Anatomy, Tel Aviv,

Israel

3

National Institute on Aging, National Institutes of Health, Drug

Design & Development Section, Baltimore, USA

Treatment of traumatic brain injury (TBI) represents an unmet medical

need, as no effective pharmacological treatment currently exists. De-

velopment of such a treatment requires a fundamental understanding of

the pathophysiological mechanisms that underpin the sequelae resulting

from TBI, particularly the ensuing neuronal cell death and cognitive

impairments. Tumor necrosis factor-alpha (TNF-a) is a cytokine that is

a master regulator of systemic and neuro inflammatory processes. TNF-

a levels are reported rapidly elevated post TBI and, potentially, can lead

to secondary neuronal damage. To evaluate the role of TNF-a in TBI,

particularly as a drug target, the present study evaluated time-dependent

TNF-a levels in brain in a mouse closed head 50 g weight-drop mild

TBI (mTBI) model in the presence and absence of post-treatment with

an experimental TNF-a synthesis inhibitor, 3,6’-dithiothalidomide.

Brain TNF-

a

levels peaked at 12 hr post injury, and returned to baseline

by 18 hr. This was accompanied by neuronal loss and an increase in

astrocyte number (evaluated by NeuN and GFAP immunostaining re-

spectively), as well as an elevation in the apoptotic death marker BID

at 72 hr. Impairments in measures of cognition, evaluated by novel

object recognition and passive avoidance paradigms, were evident at 7

days after injury. Treatment with the TNF-

a

synthesis inhibitor 3,6’-

dithiothalidomide 1 hr post injury prevented the mTBI-induced TNF-

a

elevation and ameliorated the neuronal loss (NeuN), elevations in as-

trocyte number (GFAP) and BID, and cognitive impairments. Cognitive

impairments were prevented by treatment as late as 12 hr post mTBI,

but were not reversed when treatment was delayed until 18 hr. These

results suggest that pharmacologically limiting the generation of TNF-

a

post mTBI may mitigate secondary damage and define a time window

of up to 12 hr to achieve this reversal.

Keywords: Neuroprotection, Inflammation, Neurodegeneration,

Cognition

D8-06

BIODEGRADABLE NEURO-SPINAL SCAFFOLD PRE-

SERVES SPINAL CORD ARCHITECTURE FOLLOWING

SPINAL CONTUSION INJURY IN RATS

Richard Layer

, Alex Aimetti, Pamela Podell, Simon Moore, Thomas

Ulich

InVivo Therapeutics, Research, Cambridge, USA

Severe spinal cord injury (SCI) is accompanied by disruption of

spinal cord architecture, including cystic cavitation and tissue loss.

We hypothesized that implantation of a biodegradable, biomaterial

scaffold into the injured spinal cord could serve as a locus for ap-

positional healing and tissue remodeling that would preserve spinal

cord architecture. We evaluated the effect of implantation of scaf-

folds composed of a block copolymer of poly(lactic-co-glycolic

acid) and poly(L-lysine) (PLGA-PLL) on preservation of spinal ar-

chitecture in a rat contusion model of severe spinal cord injury

(SCI). A spinal T10 contusion injury was created in female Sprague-

Dawley rats with a Precision Systems IH Impactor (220 kDyn).

Cylindrical scaffolds (1.0 mm diameter, 2.0 mm length) were surgi-

cally implanted at the lesion site between 24 and 72 hours later.

Body weight, development of mechanical allodynia, and recovery of

coordinated hind limb function using the Basso, Beattie, and Bres-

nahan (BBB) scale were evaluated for 12 weeks. Spinal architecture

was evaluated at 12 weeks by morphometric analysis of parafor-

maldehyde fixed frozen sections (20

l

m) stained with hematoxylin &

eosin (H&E). Scaffold implantation did not result in mechanical

allodynia, did not impair body weight gain, and did not interfere with

partial recovery from full hind-limb paralysis. Histological analysis

revealed that rats in the non-treated control group developed large

cavities surrounded by a rim of spared tissue. In contrast, in rats

treated with scaffold implantation surgery, cavity volume decreased

by 86% and spared tissue width increased by 44%. Although scaf-

folds were fully resorbed by 12 weeks after implantation, the amount

of remodeled tissue at the site of implantation in the lesion epicenter

increased by 111%. These results demonstrate that PLGA-PLL

scaffold implantation in the acutely injured spinal cord can reduce

cavitation, promote tissue sparing and remodeling, and act as a locus

for appositional healing. Scaffold implantation preserves spinal cord

architecture and may play an important role in combinatorial spinal

cord repair strategies.

Keywords: biomaterial, tissue engineering, scaffold, implantation,

biodegradable

D8-07

HYPERTONIC SALINE THERAPY AND DECOMPRESSIVE

SURGERY WITH MULTI-MODAL THERAPY IN ACUTE

SPINAL CORD INJURY

George Hanna

1

, Olaide Ajayi

1

, Nam Yoon

1

, Farbod Asgarzadie

1

,

Huitzilin Olmecah

2

1

Loma Linda University Health, Department of Neurological Surgery,

Loma Linda, USA

2

Loma Linda University Health, Neurosciences Intensive Care Unit,

Loma Linda, USA

Acute spinal cord injury is a debilitating condition that has signifi-

cant associated morbidity and mortality that has progressed to be-

coming a chronic medical condition with an estimated prevalence of

about 270,000 individuals and with an incidence of 12,000 new cases

each year in the United States. The majority of spinal cord injury

cases are secondary to trauma and permanent neurological deficits

are believed to be due to secondary injury most significantly due to

compressive forces and edema. Despite advances in intensive care

and refinement of surgical approaches, there are currently no widely

accepted medical or surgical interventions for managing spinal cord

edema. Interestingly, however, there has been generally more liter-

ature and data on decreasing cerebral edema, including the admin-

istration of hypertonic saline. There have been several basic science

articles written on the proposed efficacy of hypertonic saline ad-

ministration in decreasing spinal cord edema after acute spinal

cord injury but no known clinical studies to date. A review of the

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