Raised intrathecal pressure (ITP) after traumatic spinal cord injury (SCI) is a critically important aspect of injury development that may result in significantly greater tissue damage and worsened functional outcome. Raised ITP is caused by the accumulation of blood and/or water (edema), and while their occurrence after traumatic SCI has been well established, the relative contribution of both processes to the development of ITP after SCI has not yet been determined. Accordingly, the current study investigates the temporal profile of raised ITP after traumatic SCI in relation to both hemorrhage and edema development. A closed balloon compression injury was induced at T10 in New Zealand White rabbits. Animals were thereafter assessed for spinal water content (edema), ITP, lesion and hemorrhage volume, and albumin immunoreactivity from 5 h to 1 week post-SCI. Early increases in ITP at 5 h post-injury were associated with significant increases in blood volume. ITP, however, was maximal at 3 days post-SCI, at which time there was an associated significant increase in edema that persisted for 1 week. We conclude that raised ITP after traumatic SCI is initially driven by volumetric increases in hemorrhage, while edema becomes the primary driver of ITP at 3 days post-injury.
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References
1.
SharmaH.S., WinklerT., StalbergE., OlssonY., and DeyP.K. (1991). Evaluation of traumatic spinal cord edema using evoked potentials recorded from the spinal epidural space. An experimental study in the rat. J. Neurol. Sci., 102, 150–162.
2.
WinklerT., SharmaH.S., StalbergE., OlssonY. and NybergF. (1994). Opioid receptors influence spinal cord electrical activity and edema formation following spinal cord injury: experimental observations using naloxone in the rat. Neurosci. Res., 21, 91–101.
3.
SharmaH.S. (2005). Pathophysiology of blood-spinal cord barrier in traumatic injury and repair. Curr. Pharm. Des., 11, 1353–1389.
4.
NesicO., LeeJ., YeZ., UnabiaG.C., RafatiD., HulseboschC.E., and Perez-PoloJ.R. (2006). Acute and chronic changes in aquaporin 4 expression after spinal cord injury. Neuroscience, 143, 779–792.
5.
AtesO., CayliS.R., GursesI., TurkozY., TarimO., CakirC.O., and KocakA. (2007). Comparative neuroprotective effect of sodium channel blockers after experimental spinal cord injury. J. Clin. Neurosci., 14, 658–665.
6.
LeonardA.V., ThorntonE., and VinkR. (2013). Substance P as a mediator of neurogenic inflammation following balloon compression induced spinal cord injury. J. Neurotrauma, 30, 1812–1823.
7.
NemecekS., PetrR., SubaP., RozsivalV., and MelkaO. (1977). Longitudinal extension of oedema in experimental spinal cord injury—evidence for two types of post-traumatic oedema. Acta Neurochir. (Wien), 37, 7–16.
8.
DemediukP., LemkeM., and FadenA.I. (1990). Spinal cord edema and changes in tissue content of Na+, K+, and Mg2+ after impact trauma in rats. Adv. Neurol., 52, 225–232.
9.
SaadounS., BellB.A., VerkmanA.S., and PapadopoulosM.C. (2008). Greatly improved neurological outcome after spinal cord compression injury in AQP4-deficient mice. Brain, 131, 1087–1098.
10.
GoldsmithH.S. (2009). Treatment of acute spinal cord injury by omental transposition: a new approach. J. Am. Coll. Surg., 208, 289–292.
11.
LeviL., WolfA., and BelzbergH. (1993). Hemodynamic parameters in patients with acute cervical cord trauma: description, intervention, and prediction of outcome. Neurosurgery, 33, 1007–1017.
12.
ValeF.L., BurnsJ., JacksonA.B., and HadleyM.N. (1997). Combined medical and surgical treatment after acute spinal cord injury: results of a prospective pilot study to assess the merits of aggressive medical resuscitation and blood pressure management. J. Neurosurg., 87, 239–246.
13.
KwonB.K., CurtA., BelangerL.M., BernardoA., ChanD., MarkezJ.A., GorelikS., SlobogeanG.P., UmedalyH., GiffinM., NikolakisM.A., StreetJ., BoydM.C., PaquetteS., FisherC.G., and DvorakM.F. (2009). Intrathecal pressure monitoring and cerebrospinal fluid drainage in acute spinal cord injury: a prospective randomized trial. J. Neurosurg. Spine, 10, 181–193.
14.
BatchelorP.E., KerrN.F., GattA.M., CoxS.F., Ghasem-ZadehA., WillsT.E., SidonT.K., and HowellsD.W. (2011). Intracanal pressure in compressive spinal cord injury: reduction with hypothermia. J. Neurotrauma, 28, 809–820.
15.
MartinD., SchoenenJ., DelreeP., GilsonV., RogisterB., LeprinceP., StevenaertA., and MoonenG. (1992). Experimental acute traumatic injury of the adult rat spinal cord by a subdural inflatable balloon: methodology, behavioral analysis, and histopathology. J. Neurosci. Res., 32, 539–550.
16.
VanickyI., UrdzikovaL., SaganovaK., CizkovaD., and GalikJ. (2001). A simple and reproducible model of spinal cord injury induced by epidural balloon inflation in the rat. J. Neurotrauma, 18, 1399–1407.
HelpsS.C., ThorntonE., KleinigT.J., ManavisJ., and VinkR. (2012). Automatic nonsubjective estimation of antigen content visualized by immunohistochemistry using color deconvolution. Appl. Immunohistochem. Mol. Morphol., 20, 82–90.
19.
MarmarouA. (2007). A review of progress in understanding the pathophysiology and treatment of brain edema. Neurosurg. Focus, 22, E1.
20.
PadayachyL.C., FigajiA.A., and BullockM.R. (2010). Intracranial pressure monitoring for traumatic brain injury in the modern era. Childs Nerv. Syst., 26, 441–452.
HornE.M., TheodoreN., AssinaR., SpetzlerR.F., SonntagV.K., and PreulM.C. (2008). The effects of intrathecal hypotension on tissue perfusion and pathophysiological outcome after acute spinal cord injury. Neurosurg. Focus, 25, E12.
23.
TatorC.H., and FehlingsM.G. (1991). Review of the secondary injury theory of acute spinal cord trauma with emphasis on vascular mechanisms. J. Neurosurg., 75, 15–26.
24.
YoungW., DeCrescitoV., and TomasulaJ.J. (1982). Effect of sympathectomy on spinal blood flow autoregulation and posttraumatic ischemia. J. Neurosurg., 56, 706–710.
25.
SharmaH.S., OlssonY., NybergF., and DeyP.K. (1993). Prostaglandins modulate alterations of microvascular permeability, blood flow, edema and serotonin levels following spinal cord injury: an experimental study in the rat. Neuroscience, 57, 443–449.
26.
WangR., EharaK., and TamakiN. (1993). Spinal cord edema following freezing injury in the rat: relationship between tissue water content and spinal cord blood flow. Surg. Neurol., 39, 348–354.
27.
TaokaY., and OkajimaK. (1998). Spinal cord injury in the rat. Prog. Neurobiol., 56, 341–358.
28.
TatorC.H., and KoyanagiI. (1997). Vascular mechanisms in the pathophysiology of human spinal cord injury. J. Neurosurg., 86, 483–492.
29.
SenterH.J., and VenesJ.L. (1979). Loss of autoregulation and posttraumatic ischemia following experimental spinal cord trauma. J. Neurosurg., 50, 198–206.
30.
SimardJ.M., TsymbalyukO., IvanovA., IvanovaS., BhattaS., GengZ., WooS.K., and GerzanichV. (2007). Endothelial sulfonylurea receptor 1-regulated NC Ca-ATP channels mediate progressive hemorrhagic necrosis following spinal cord injury. J. Clin. Invest., 117, 2105–2113.
31.
PopovichP.G., LemeshowS., GenselJ.C., and TovarC.A. (2012). Independent evaluation of the effects of glibenclamide on reducing progressive hemorrhagic necrosis after cervical spinal cord injury. Exp. Neurol., 233, 615–622.
32.
BilgenM., DoganB., and NarayanaP.A. (2002). In vivo assessment of blood-spinal cord barrier permeability: serial dynamic contrast enhanced MRI of spinal cord injury. Magn. Reson. Imaging, 20, 337–341.
33.
JacobsT.P., KempskiO., McKinleyD., DutkaA.J., HallenbeckJ.M., and FeuersteinG. (1992). Blood flow and vascular permeability during motor dysfunction in a rabbit model of spinal cord ischemia. Stroke, 23, 367–373.
34.
GoodmanJ.H., BinghamW.G.Jr., and HuntW.E. (1976). Ultrastructural blood-brain barrier alterations and edema formation in acute spinal cord trauma. J. Neurosurg., 44, 418–424.
WhetstoneW.D., HsuJ.Y., EisenbergM., WerbZ., and Noble-HaeussleinL.J. (2003). Blood-spinal cord barrier after spinal cord injury: relation to revascularization and wound healing. J. Neurosci. Res., 74, 227–239.
37.
JaegerC.B., and BlightA.R. (1997). Spinal cord compression injury in guinea pigs: structural changes of endothelium and its perivascular cell associations after blood-brain barrier breakdown and repair. Exp. Neurol., 144, 381–399.
38.
HaggT., and OudegaM. (2006). Degenerative and spontaneous regenerative processes after spinal cord injury. J. Neurotrauma, 23, 264–280.
