Evaluation of the Use of a Bioengineered Hydrogel Containing Hyaluronan to Reduce Inflammation and Scarring following Spinal Cord Injury Associated with Arachnoiditis

Austin, James W.

10 December 2012

Background: Spinal cord injury (SCI) is heterogeneous in nature and can be complicated by inflammation and scarring in the subarachnoid space (arachnoiditis). The constellation of traumatic injury and arachnoiditis can lead to extensive intraparenchymal cysts or post-traumatic syringomyelia (PTS), due to alterations in fluid flow and pressure dynamics in the subarachnoid space. Hypothesis: Intrathecal injection of a bioengineered hydrogel containing hyaluronan (HA) will improve functional recovery following severe spinal cord injury associated with arachnoiditis. Methods: Acute to subacute pathophysiological events were characterized in non-injured sham rats, rats receiving a clip compression/contusion injury (SCI), rats receiving an intrathecal kaolin injection (Arachnoiditis) and in rats receiving SCI plus kaolin injection (PTS). Next, a HA containing hydrogel (HAMC) or artificial cerbralspinal fluid (aCSF) control was injected into the subarachnoid space 24 hours following PTS injury. To assess treatment efficacy, subacute pathophysiology was assessed as was long-term neurobehavioural and neuroanatomical recovery. Finally, in vitro studies examined the effect of HA on TLR4 activation using lipopolysaccharide in primary rat microglial cultures. Results: PTS animals exhibited a greater parenchymal injury response as compared to the sum of SCI alone or arachnoiditis alone. Injection of HAMC reduced the extent of scarring and inflammation in the subarachnoid space and improved neurobehavioural and neuroanatomical recovery relative to aCSF controls. These improvements were associated with reduced chondroitin sulfate proteoglycan and IL-1α expression and a trend towards and axonal preservation. In vitro studies demonstrated that HA is capable of reducing TLR4 mediated inflammation in microglia. Conclusions: Acute arachnoiditis potentiates the intensity of intraparenchymal inflammatory and scarring events following SCI. When HAMC was injected intrathecally following PTS injury, it mitigated some of the pernicious effects of arachnoiditis. Part of the therapeutic action of HAMC can be attributed to the ability of HA to reduce TLR4 mediated inflammation in microglia, possibly through an extracellular mechanism.

Spinal cord injury

Inflammation

Microglia

Hyaluronan

Arachnoiditis

Post-traumatic syringomyelia

Scarring

0317

Evaluation of the Use of a Bioengineered Hydrogel Containing Hyaluronan to Reduce Inflammation and Scarring following Spinal Cord Injury Associated with Arachnoiditis

Austin, James W.

10 December 2012

Background: Spinal cord injury (SCI) is heterogeneous in nature and can be complicated by inflammation and scarring in the subarachnoid space (arachnoiditis). The constellation of traumatic injury and arachnoiditis can lead to extensive intraparenchymal cysts or post-traumatic syringomyelia (PTS), due to alterations in fluid flow and pressure dynamics in the subarachnoid space. Hypothesis: Intrathecal injection of a bioengineered hydrogel containing hyaluronan (HA) will improve functional recovery following severe spinal cord injury associated with arachnoiditis. Methods: Acute to subacute pathophysiological events were characterized in non-injured sham rats, rats receiving a clip compression/contusion injury (SCI), rats receiving an intrathecal kaolin injection (Arachnoiditis) and in rats receiving SCI plus kaolin injection (PTS). Next, a HA containing hydrogel (HAMC) or artificial cerbralspinal fluid (aCSF) control was injected into the subarachnoid space 24 hours following PTS injury. To assess treatment efficacy, subacute pathophysiology was assessed as was long-term neurobehavioural and neuroanatomical recovery. Finally, in vitro studies examined the effect of HA on TLR4 activation using lipopolysaccharide in primary rat microglial cultures. Results: PTS animals exhibited a greater parenchymal injury response as compared to the sum of SCI alone or arachnoiditis alone. Injection of HAMC reduced the extent of scarring and inflammation in the subarachnoid space and improved neurobehavioural and neuroanatomical recovery relative to aCSF controls. These improvements were associated with reduced chondroitin sulfate proteoglycan and IL-1α expression and a trend towards and axonal preservation. In vitro studies demonstrated that HA is capable of reducing TLR4 mediated inflammation in microglia. Conclusions: Acute arachnoiditis potentiates the intensity of intraparenchymal inflammatory and scarring events following SCI. When HAMC was injected intrathecally following PTS injury, it mitigated some of the pernicious effects of arachnoiditis. Part of the therapeutic action of HAMC can be attributed to the ability of HA to reduce TLR4 mediated inflammation in microglia, possibly through an extracellular mechanism.

Spinal cord injury

Inflammation

Microglia

Hyaluronan

Arachnoiditis

Post-traumatic syringomyelia

Scarring

0317

The Role of Betaine Focused Fluid Osmoregulation in Syringomyelia Post Spinal Cord Injury

Pukale, Dipak Dadaso

05 June 2022

No description available.

Biomedical Research

Biomedical Engineering

Biochemistry

Chemical Engineering

Syringomyelia

post-traumatic syringomyelia (PTSM)

syrinx

spinal cord injury (SCI)

betaine

betaine/GABA transporter 1 (BGT1)

choline dehydrogenase (CHDH)

fluid osmoregulation

choroid plexus organoid

gait analysis