A number of pre-clinical rodent models have been developed in an effort to recapitulate injury mechanisms and identify potential therapeutics for traumatic brain injury (TBI), which is a major cause of death and long-term disability in the United States. The lack of restorative treatments for TBI, however, has led to considerable criticism of current pre-clinical therapeutic development strategies—namely, the translatability of widely used rodent models to human patients. The use of large animal models, such as the pig, with more brain anatomy and physiology comparable to humans may enhance the translational capacity of current pre-clinical animal models. The objective of this study was to develop and characterize a graded piglet TBI model with quantitative pathological features at the cellular, tissue, and functional level that become more prominent with increasing TBI severity. A graded TBI was produced by controlled cortical impact (CCI) in “toddler-aged” Landrace piglets by increasing impact velocity and/or depth of depression to 2 m/sec; 6 mm; 4 m/sec; 6 mm; 4 m/sec; 12 mm; or 4 m/sec; 15 mm, producing a range of neural injury responses that corresponded to injury severity. Quantitative gait analysis was performed pre-TBI and one, three, and seven days post-TBI, and piglets were sacrificed seven days post-TBI. Increasing impact parameters correlated to increases in lesion size with piglets that sustained a 6 mm depth of depression exhibiting significantly smaller lesions than piglets that sustained a depth of depression of 12 mm or 15 mm. Similarly, the extent of neuronal loss, astrogliosis/astrocytosis, and white matter damage became more prominent as CCI parameters were increased. These cellular and tissue-level changes correlated with motor function deficits including swing/stance time, stride velocity, and two- versus three-limb support. The piglet TBI model described here could serve as a translational platform for studying TBI sequelae across injury severities and identifying novel therapeutics.
Get full access to this article
View all access options for this article.
References
1.
LangloisJ.A., Rutland-BrownW., Tand homasK.E. (2006). Traumatic brain injury in the United States: Emergency deparment visits, hospitalizations, and deaths. Centers for Disease Control and Prevention, National Center for Injury Prevention and Control: Atlanta, GA.
2.
SchneierA.J., ShieldsB.J., HostetlerS.G., XiangH., and SmithG.A. (2006). Incidence of pediatric traumatic brain injury and associated hospital resource utilization in the United States. Pediatrics, 118, 483–492.
AndersonV., CatroppaC., MorseS., HaritouF., and RosenfeldJ. (2005). Functional plasticity or vulnerability after early brain injury?. Pediatrics, 116, 1374–1382.
5.
AndersonV., GodfreyC., RosenfeldJ.V., and CatroppaC. (2012). Predictors of cognitive function and recovery 10 years after traumatic brain injury in young children. Pediatrics, 129, e254–e261.
6.
LiL. and LiuJ. (2013). The effect of pediatric traumatic brain injury on behavioral outcomes: a systematic review. Dev. Med. Child Neurol., 55, 37–45.
7.
BerettaE., CimolinV., PiccininiL., Carla TurconiA., GalbiatiS., CrivelliniM., GalliM., and StrazzerS. (2009). Assessment of gait recovery in children after Traumatic Brain Injury. Brain Inj. 23, 751–759.
8.
FakhryS.M., TraskA.L., WallerM.A., WattsD.D., and IRTC Neurotrauma TaskForce (2004). Management of brain-injured patients by an evidence-based medicine protocol improves outcomes and decreases hospital charges. J. Trauma, 56, 492–499.
9.
AllenK.A. (2016). Pathophysiology and treatment of severe traumatic brain injuries in children. J. Neurosci. Nurs., 48, 15–27.
10.
MaasA.I., RoozenbeekB., and ManleyG.T. (2010). Clinical trials in traumatic brain injury: past experience and current developments. Neurotherapeutics, 7, 115–126.
11.
XiongY., MahmoodA., and ChoppM. (2009). Emerging treatments for traumatic brain injury. Expert Opin. Emerg. Drugs, 14, 67–84.
12.
SteinD.G., GeddesR.I., and SribnickE.A. (2015). Recent developments in clinical trials for the treatment of traumatic brain injury. Handb. Clin. Neurol., 127, 433–451.
13.
XiongY., MahmoodA., and ChoppM. (2013). Animal models of traumatic brain injury. Nat. Rev. Neurosci., 14, 128–142.
14.
KobeissyF.H. (2015). Brain Neurotrauma: Molecular, Neuropsychological, and Rehabilitation Aspects. CRC Press, Taylor & Francis Group: Boca Raton.
15.
RomineJ., GaoX.,and ChenJ. (2014). Controlled cortical impact model for traumatic brain injury. J. Vis. Exp.e51781.
16.
BiglerE.D., AbildskovT.J., PetrieJ., FarrerT.J., DennisM., SimicN., TaylorH.G., RubinK.H., VannattaK., GerhardtC.A., StancinT., and Owen YeatesK. (2013). Heterogeneity of brain lesions in pediatric traumatic brain injury. Neuropsychology, 27, 438–451.
17.
AndersonV.A., CatroppaC., RosenfeldJ., HaritouF., and MorseS.A. (2000). Recovery of memory function following traumatic brain injury in pre-school children. Brain Inj. 14, 679–692.
18.
Kuhtz-BuschbeckJ.P., StolzeH., GolgeM., and RitzA. (2003). Analyses of gait, reaching, and grasping in children after traumatic brain injury. Arch. Phys. Med. Rehabil., 84, 424–430.
19.
FoxG.B., FanL., LevasseurR.A., and FadenA.I. (1998). Sustained sensory/motor and cognitive deficits with neuronal apoptosis following controlled cortical impact brain injury in the mouse. J. Neurotrauma, 15, 599–614.
20.
SaatmanK.E., FeekoK.J., PapeR.L. and RaghupathiR. (2006). Differential behavioral and histopathological responses to graded cortical impact injury in mice. J. Neurotrauma, 23, 1241–1253.
21.
YuS., KanekoY., BaeE., StahlC.E., WangY., van LoverenH., SanbergP.R., and BorlonganC.V. (2009). Severity of controlled cortical impact traumatic brain injury in rats and mice dictates degree of behavioral deficits. Brain Res. 1287, 157–163.
22.
WashingtonP.M., ForcelliP.A., WilkinsT., ZappleD.N., ParsadanianM., and BurnsM.P. (2012). The effect of injury severity on behavior: a phenotypic study of cognitive and emotional deficits after mild, moderate, and severe controlled cortical impact injury in mice. J. Neurotrauma, 29, 2283–2296.
23.
ZhaoZ., LoaneD.J., MurrayM.G.2nd, StoicaB.A., and FadenA.I. (2012). Comparing the predictive value of multiple cognitive, affective, and motor tasks after rodent traumatic brain injury. J. Neurotrauma, 29, 2475–2489.
24.
XiongY., MahmoodA., and ChoppM. (2010). Neurorestorative treatments for traumatic brain injury. Discov. Med., 10, 434–442.
25.
BukiA., OkonkwoD.O., and PovlishockJ.T. (1999). Postinjury cyclosporin A administration limits axonal damage and disconnection in traumatic brain injury. J. Neurotrauma, 16, 511–521.
26.
RiessP., ZhangC., SaatmanK.E., LaurerH.L., LonghiL.G., RaghupathiR., LenzlingerP.M., LifshitzJ., BoockvarJ., NeugebauerE., SnyderE.Y., and McIntoshT.K. (2002). Transplanted neural stem cells survive, differentiate, and improve neurological motor function after experimental traumatic brain injury. Neurosurgery, 51, 1043–1052.
27.
KolbB., GibbR., and GornyG. (2000). Cortical plasticity and the development of behavior after early frontal cortical injury. Dev. Neuropsychol., 18, 423–444.
28.
JohnsonV.E., MeaneyD.F., CullenD.K., and SmithD.H. (2015). Animal models of traumatic brain injury. Handb. Clin. Neurol., 127, 115–128.
29.
KandelE.R. (2013). Principles of Neural Science, 5th ed. McGraw-Hill: New York.
30.
AhmadA.S., SatriotomoI., FazalJ., NadeauS.E., and DoreS. (2015). Considerations for the optimization of induced white matter injury preclinical models. Front. Neurol., 6, 172.
31.
ThomasJ.M. and BeamerJ.L. (1971). Age-weight relationships of selected organs and body weight for miniature swine. Growth, 35, 259–272.
32.
CoppolettaJ.M. and WolbachS.B. (1933). Body length and organ weights of infants and children: a study of the body length and normal weights of the more important vital organs of the body between birth and twelve years of age. Am. J. Pathol., 9, 55–70.
33.
PondW.G., BolemanS.L., FiorottoM.L., HoH., KnabeD.A., MersmannH.J., SavellJ.W., and SuD.R. (2000). Perinatal ontogeny of brain growth in the domestic pig. Proc. Soc. Exp. Biol. Med., 223, 102–108.
34.
FlynnT.J. (1984). Developmental changes of myelin-related lipids in brain of miniature swine. Neurochem. Res., 9, 935–945.
35.
LindN.M., MoustgaardA., JelsingJ., VajtaG., CummingP., and HansenA.K. (2007). The use of pigs in neuroscience: modeling brain disorders. Neurosci. Biobehav. Rev., 31, 728–751.
36.
ZhangK. and SejnowskiT.J. (2000). A universal scaling law between gray matter and white matter of cerebral cortex. Proc. Natl. Acad. Sci. U. S. A., 97, 5621–5626.
37.
FairbairnL., KapetanovicR., SesterD.P., and HumeD.A. (2011). The mononuclear phagocyte system of the pig as a model for understanding human innate immunity and disease. J. Leukoc. Biol., 89, 855–871.
38.
GaleS.D., JohnsonS.C., BiglerE.D., and BlatterD.D. (1995). Nonspecific white matter degeneration following traumatic brain injury. J. Int. Neuropsychol. Soc., 1, 17–28.
39.
LighthallJ.W. (1988). Controlled cortical impact: a new experimental brain injury model. J. Neurotrauma, 5, 1–15.
40.
HutchinsonE.B., SchwerinS.C., RadomskiK.L., IrfanogluM.O., JulianoS.L., and PierpaoliC.M. (2016). Quantitative MRI and DTI abnormalities during the acute period following CCI in the ferret. Shock, 46, Suppl 1, 167–176.
41.
SchwerinS.C., HutchinsonE.B., RadomskiK.L., NgalulaK.P., PierpaoliC.M., and JulianoS.L. (2017). Establishing the ferret as a gyrencephalic animal model of traumatic brain injury: optimization of controlled cortical impact procedures. J. Neuroscience Methods, 285, 82–96.
42.
KingC., RobinsonT., DixonC.E., RaoG.R., LarnardD., and NemotoC.E. (2010). Brain temperature profiles during epidural cooling with the ChillerPad in a monkey model of traumatic brain injury. J. Neurotrauma, 27, 1895–1903.
43.
DuhaimeA.C., MarguliesS.S., DurhamS.R., O'RourkeM.M., GoldenJ.A., MarwahaS., and RaghupathiR. (2000). Maturation-dependent response of the piglet brain to scaled cortical impact. J. Neurosurg., 93, 455–462.
44.
AlessandriB., HeimannA., FilippiR., KopaczL.. and KempskiO. (2003). Moderate controlled cortical contusion in pigs: effects on multi-parametric neuromonitoring and clinical relevance. J. Neurotrauma, 20, 1293–1305.
45.
ManleyG.T., RosenthalG., LamM., MorabitoD., YanD., DeruginN., BollenA., KnudsonM.M., and PanterS.S. (2006). Controlled cortical impact in swine: pathophysiology and biomechanics. J. Neurotrauma, 23, 128–139.
46.
MytarJ., KiblerK.K., EasleyR.B., SmielewskiP., CzosnykaM., AndropoulosD.B., and BradyK.M. (2012). Static autoregulation is intact early after severe unilateral brain injury in a neonatal Swine model. Neurosurgery, 71, 138–145.
47.
DubersteinK.J., PlattS.R., HolmesS.P., DoveC.R., HowerthE.W., KentM., SticeS.L., HillW.D., HessD.C., and WestF.D. (2014). Gait analysis in a pre- and post-ischemic stroke biomedical pig model. Physiol. Behav., 125, 8–16.
48.
SchneiderC.A., RasbandW.S., and EliceiriK.W. (2012). NIH Image to ImageJ: 25 years of image analysis. Nat. Methods, 9, 671–675.
49.
PlattS.R., HolmesS.P., HowerthE.W., DubersteinK.J., DoveC.R., KinderH.A., WyattE.L., LinvilleA.V., LauV.W., SticeS.L., HillW.D., HessD.C., and WestF.D. (2014). Development and characterization of a Yucatan miniature biomedical pig permanent middle cerebral artery occlusion stroke model. Exp. Transl. Stroke Med., 6, 5.
50.
OsierN. and DixonC.E. (2016). The controlled cortical impact model of experimental brain trauma: overview, research applications, and protocol. Methods Mol. Biol., 1462, 177–192.
51.
SindelarB., BailesJ.E., ShermanS.A., FinanJ.D., StoneJ., LeeJ.M., AhmadianS., ZhouY., PatelV., and SmithD. (2016). Effect of Internal jugular vein compression on intracranial hemorrhage in a porcine controlled cortical impact model. J. Neurotrauma, 34, 1703–1709.
52.
JinG., DeMoyaM.A., DugganM., KnightlyT., MejaddamA.Y., HwabejireJ., LuJ., SmithW.M., KasotakisG., VelmahosG.C., SocrateS., and AlamH.B. (2012). Traumatic brain injury and hemorrhagic shock: evaluation of different resuscitation strategies in a large animal model of combined insults. Shock, 38, 49–56.
53.
MeissnerA., Timaru-KastR., HeimannA., HoelperB., KempskiO., and AlessandriB. (2011). Effects of a small acute subdural hematoma following traumatic brain injury on neuromonitoring, brain swelling and histology in pigs. Eur. Surg. Res., 47, 141–153.
54.
ChastainC.A., OyoyoU.E., ZippermanM., JooE., AshwalS., ShutterL.A., and TongK.A. (2009). Predicting outcomes of traumatic brain injury by imaging modality and injury distribution. J. Neurotrauma, 26, 1183–1196.
55.
PieralliniA., PantanoP., FantozziL.M., BonaminiM., VichiR., ZylbermanR., PisarriF., ColonneseC., and BozzaoL. (2000). Correlation between MRI findings and long-term outcome in patients with severe brain trauma. Neuroradiology, 42, 860–867.
56.
McGinnM.J. and PovlishockJ.T. (2015). Cellular and molecular mechanisms of injury and spontaneous recovery. Handb. Clin. Neurol., 127, 67–87.
57.
DuhaimeA.C., HunterJ.V., GrateL.L., KimA., GoldenJ., DemidenkoE., and HarrisC. (2003). Magnetic resonance imaging studies of age-dependent responses to scaled focal brain injury in the piglet. J. Neurosurg., 99, 542–548.
58.
MissiosS., HarrisB.T., DodgeC.P., SimoniM.K., CostineB.A., LeeY.L., QuebadaP.B., HillierS.C., AdamsL.B., and DuhaimeA.C. (2009). Scaled cortical impact in immature swine: effect of age and gender on lesion volume. J. Neurotrauma, 26, 1943–1951.
59.
WolfH.K., BusleiR., Schmidt-KastnerR., Schmidt-KastnerP.K., PietschT., WiestlerO.D., and BlumckeI. (1996). NeuN: a useful neuronal marker for diagnostic histopathology. J. Histochem. Cytochem., 44, 1167–1171.
60.
BuriticaE., VillamilL., GuzmanF., EscobarM.I., Garcia-CairascoN., and PimientaH.J. (2009). Changes in calcium-binding protein expression in human cortical contusion tissue. J, Neurotrauma, 26, 2145–2155.
61.
GobbelG.T., BonfieldC., Carson-WalterE.B., and AdelsonP.D. (2007). Diffuse alterations in synaptic protein expression following focal traumatic brain injury in the immature rat. Childs Nerv. Syst., 23, 1171–1179.
62.
AjaoD.O., PopV., KamperJ.E., AdamiA., RudobeckE., HuangL., VlkolinskyR., HartmanR.E., AshwalS., ObenausA., and BadautJ. (2012). Traumatic brain injury in young rats leads to progressive behavioral deficits coincident with altered tissue properties in adulthood. J. Neurotrauma, 29, 2060–2074.
63.
MiddeldorpJ. and HolE.M. (2011). GFAP in health and disease. Prog, Neurobiol, 93, 421–443.
64.
BurdaJ.E., BernsteinA.M., and SofroniewM.V. (2016). Astrocyte roles in traumatic brain injury. Exp. Neurol. 275 Pt, 3, 305–315.
65.
ZiebellJ.M. and Morganti-KossmannM.C. (2010). Involvement of pro- and anti-inflammatory cytokines and chemokines in the pathophysiology of traumatic brain injury. Neurotherapeutics, 7, 22–30.
66.
SajjaV.S., HlavacN., and VandeVordP.J. (2016). Role of glia in memory deficits following traumatic brain injury: biomarkers of glia dysfunction. Front. Integr. Neurosci., 10, 7.
67.
HarishG., MahadevanA., PruthiN., SreenivasamurthyS.K., PuttamalleshV.N., Keshava PrasadT.S., ShankarS.K., and Srinivas BharathM.M. (2015). Characterization of traumatic brain injury in human brains reveals distinct cellular and molecular changes in contusion and pericontusion. J. Neurochem., 134, 156–172.
68.
GaberZ.B. and NovitchB.G. (2011). All the embryo's a stage, and Olig2 in its time plays many parts. Neuron, 69, 833–835.
69.
FlygtJ., GumucioA., IngelssonM., SkoglundK., HolmJ., AlafuzoffI., and MarklundN. (2016). Human traumatic brain injury results in oligodendrocyte death and increases the number of oligodendrocyte progenitor cells. J. Neuropathol. Exp. Neurol., 75, 503–515.
70.
DentK.A., ChristieK.J., ByeN., BasraiH.S., TurbicA., HabgoodM., CateH.S., and TurnleyA.M. (2015). Oligodendrocyte birth and death following traumatic brain injury in adult mice. PloS One, 10, e0121541.
71.
LotockiG., de Rivero VaccariJ.P., AlonsoO., MolanoJ.S., NixonR., SafaviP., DietrichW.D., and BramlettH.M. (2011). Oligodendrocyte vulnerability following traumatic brain injury in rats. Neurosci. Lett., 499, 143–148.
72.
Kuhtz-BuschbeckJ.P., HoppeB., GolgeM., DreesmannM., Damm-StunitzU., and RitzA. (2003). Sensorimotor recovery in children after traumatic brain injury: analyses of gait, gross motor, and fine motor skills. Dev. Med. Child Neurol., 45, 821–828.
73.
DubersteinK.J., PlattS.R., HolmesS.P., DoveC.R., HowerthE.W., KentM., SticeS.L., HillW.D., HessD.C., and WestF.D. (2014). Gait analysis in a pre- and post-ischemic stroke biomedical pig model. Physiol. Behav., 125, 8–16.
74.
OchiF., EsquenaziA., HiraiB., and TalatyM. (1999). Temporal-spatial feature of gait after traumatic brain injury. J. Head Trauma Rehabil., 14, 105–115.
75.
Katz-LeurerM., RotemH., KerenO., and MeyerS. (2011). The effect of variable gait modes on walking parameters among children post severe traumatic brain injury and typically developed controls. NeuroRehabilitation, 29, 45–51.
76.
Katz-LeurerM., RotemH., LewitusH., KerenO., and MeyerS. (2008). Relationship between balance abilities and gait characteristics in children with post-traumatic brain injury. Brain Inj. 22, 153–159.
77.
Katz-LeurerM., RotemH., KerenO., and MeyerS. (2009). Balance abilities and gait characteristics in post-traumatic brain injury, cerebral palsy and typically developed children. Dev. Neurorehabil., 12, 100–105.
78.
InnessE.L., HoweJ.A., Niechwiej-SzwedoE., JaglalS.B., McIlroyW.E., and VerrierM.C. (2011). Measuring balance and mobility after traumatic brain injury: validation of the community balance and mobility scale (CB&M). Physiother. Can., 63, 199–208.
79.
SambasivanK., GrilliL., and GagnonI. (2015). Balance and mobility in clinically recovered children and adolescents after a mild traumatic brain injury. J. Pediatr. Rehabil. Med., 8, 335–344.
80.
WilliamsG., MorrisM.E., SchacheA., and McCroryP.R. (2009). Incidence of gait abnormalities after traumatic brain injury. Arch. Phys. Med. Rehabil., 90, 587–593.
81.
SashindranathM., DaglasM., and MedcalfR.L. (2015). Evaluation of gait impairment in mice subjected to craniotomy and traumatic brain injury. Behav. Brain Res., 286, 33–38.
82.
NeumannM., WangY., KimS., HongS.M., JengL., BilgenM., and LiuJ. (2009). Assessing gait impairment following experimental traumatic brain injury in mice. J. Neurosci. Methods, 176, 34–44.
83.
GagnonI., SwaineB., FriedmanD., and ForgetR. (2004). Children show decreased dynamic balance after mild traumatic brain injury. Arch. Phys. Med. Rehabil., 85, 444–452.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
