Contusiones Cerebrales. Trucos.
Maintaining cerebral perfusion pressure (CPP), cerebral hemodynamic and metabolism are of paramount importance. End goal directed therapy EGDT is the cornerstone to ensure microcirculatory perfusion and early detection of treatment failure.
The approach to the patient with encephalic trauma should be systemized and follow the ABC emergency protocols giving priority to the airway control, breathing and ventilation and correction of circulatory disturbances. A throughout emergency anamnesis, primary stabilization and finally the complete neurological examination should be performed.
This sequence essentially protects the brain from hypoxia, hypoventilation and hypotension which are determinants of poor prognosis.
Evidence-based strategies for the treatment of the encephalic trauma patient include the following:
Maintain mean arterial pressure MAP >65 mm Hg (systolic pressure >100 mm Hg) to prevent secondary neurologic injury. Fluid therapy is based on EGDT key goals in patients with TEC. Hypotension is a proven factor responsible for the reduction in CPP and increase in mortality in human patients with encephalic trauma.
Mannitol intravenously infuse 0.5–1 g/kg of the 20% solution in 10 to 20 minute infusion (after securing the minimum hemodynamic parameters). It reduces blood viscosity, brain edema, and intracranial pressure ICP thus increasing blood flow and CPP. Do not administer more than three boluses within 24 hours to prevent side effects and osmolarity >320 mOs/L.
Maintain adequate oxygenation and ventilation (SaO >95%; PaO >80 mm Hg; EtCO and PaCO2 30–35 mm Hg). Hyperventilation has been associated with worsening of ischemic lesions and its therapeutic benefit is controversial. Hyperventilation should only be applied in those cases of ICP refractory to mannitol and sedation. It is better to increase respiratory rate and not tidal volume to avoid prejudicing the venous return. The goal is to keep PaCO2 at 30 mm Hg, reserving levels of 25 mm Hg for severe and refractory cases.
Raise the patient body as whole 45 degree in the prone position; this facilitates venous drainage and reduces the ICP. Avoid compressing the jugulars and exaggerated inclination that could increase intra-abdominal pressure IAP. Monitor IAP with the aim to early detect any interference on blood pressure and cerebrospinal fluid (CSF) drain.
Use sedation protocols, only when agitation compromise the maintenance of compartment pressures. However, heavy sedation increases mortality.
Early endotracheal intubation, if needed to keep oxygenation and ventilation.
Controlled hypothermia (1.5–2.5°C below normal) it has neuroprotective effects by reducing excitatory amino acids, lipid peroxidation and endogenous consumption of antioxidants.
Do not administer furosemide. Furosemide does not reduce brain edema and it does increase hypovolemia.
Administer hypertonic saline NaCl 7.5%, it improves systemic arterial pressure, has anti-inflammatory and anti-free radicals properties, increases osmolarity maintaining intravascular volume, generates an osmotic gradient through the intact blood-brain barrier, reduces edema, promotes diuresis and significantly rapidly decreases the ICP.
Do not administer high-dose corticosteroids. Despite its excellent anti-inflammatory action on the CNS, several prospective studies in humans showed no significant advantages of their use in encephalic trauma. The final results from the randomized CRASH Trial presented by the end of 2006, concluded that the percentage of death and long term neurological dysfunction in adults with severe encephalic trauma and altered consciousness at presentation in which corticosteroids at high doses were used, was higher than the control group.
Glycemic control. Hyperglycemia is directly associated with increased mortality in people with severe encephalic trauma. Excessive glucose offer to the ischemic brain results in severe cerebral lactic acidosis and increased brain damage.
Surgical approach. Early decompressive craniotomy and craniectomy for immediate reduction of the ICP. Craniectomy involves removing an area of the skull to allow adequate expansion brain; this area should be big enough to allow brain expansion without damaging the brain tissue.
Monitor and control IAP. There are some reports of nonsurgical and surgical abdominal decompression treatment for refractory increased ICP in encephalic trauma patients.
Monitoring
The evaluation of the ICP is still not routinely used in veterinary medicine, but if possible it should be performed whenever the patient has an adapted Glasgow coma score GCS of less than 8 points and abnormalities on the CT scan or MRI and in cases were systolic pressure is less than 100 mm Hg in association with signs of decerebration.
References
1. Joseph DK, Dutton RP, Aorabi B, Scalea T. Decompressive laparotomy to treat intractable intracranial hypertension after traumatic brain injury. J Trauma. 2004;57:687–695.
2. Adeodato AG, Pedro Neto O, Rabelo RC. Traumatismo crânio encefálico. In: Rabelo RC, Crowe Jr DT. Fundamentos de Terapia Intensiva Veterinária em Pequenos Animais - Condutas no Paciente Crítico. 1a. ed. Rio de Janeiro, Brazil: LF Livros; 2005:326–346.
3. Mayer SA, Chong JY. Critical care management of increased intracranial pressure. Journal of Intensive Care Medicine. 2002; V. 17.
4. Platt SR, Radaelli ST, McDonnell JJ. The prognostic value of the Modified Glasgow Coma Scale in head trauma in dogs. Journal of Veterinary Internal Medicine. 2001;15:581–584.
5. Nagpal S, Halpern CH, Calland JF, et al. Decompressive laparotomy to treat intractable cerebral hypoxia. J Trauma. 2009;67(5):E152–155.
6. Faleiro RM, Faleiro LCM, Oliveira MM, et al. Craniectomia descompressiva para tratamento da hipertensão intracraniana traumática em crianças e adolescentes. Arq Neuropsiquiatr. 2006;64(3–B):839–844.
7. Rivers E, Nguyen B, Havstad S, Ressler J, Muzzin A, Knoblich B, Early Goal-Directed Therapy Collaborative Group. Early goal-directed therapy in the treatment of severe sepsis and septic shock. New England Journal of Medicine. 2001;77–345:368.
8. Rhodes A, Bennett ED. Early goal-directed therapy: an evidence-based review. Critical Care Medicine. 2004;32(11 Suppl):S448–50.
9. Berger S, Schwarz M, Huth R. Hypertonic saline solution and decompressive craniectomy for treatment of intracranial hypertension in pediatric severe traumatic brain injury. Journal of Trauma. 2002;53:558–563.
10. Syring RS, Otto CM, Drobatz KJ. Hyperglycemia in dogs and cats with head trauma: 122 cases (1997–1999). Journal of American Veterinary Medical Association. 2001;218(7):1124–1129.
11. Edwards P, Arango M, Balica L, et al. Final results of MRC CRASH, a randomised placebo-controlled trial of intravenous corticosteroid in adults with head injury-outcomes at 6 months. Lancet. 2005;365(9475):1957–1959.
12. Huang MS, Shih HC, Wu JK, et al. Urgent laparotomy versus emergency craniotomy for multiple trauma with head injury patients. The Journal of Trauma. 1995;38(1):154–157.
13. Howard JL, Cipolle MD, Anderson M, et al. Outcome after decompressive craniectomy for the treatment of severe traumatic brain injury. Journal of Trauma. 2008;65:380–385.
14. CRASH-2 Trial Collaborators. Improving the evidence base for trauma care: progress in the international CRASH-2 trial. Plos Clin Trials. 2006;1(6):e30.
15. Dvilevicius AE, Prandini MN. Selective hypotermia: an experimental study on traumatic brain injury in rats. Arq Neuropsiquiatr. 2008;66(2-B):391–396.
16. Bloomfield GL, Blocher CR, Sugerman HJ. The relationship between elevated intra-abdominal, intrathoracic and raised intracranial pressure. Critical Care Medicine. 1997;25:496–503.
17. Saggi BH, Bloomfield GL, Blocher CR, Marmarou A, Bullock MR, Sugerman HJ. Treatment of intracranial hypertension using nonsurgical abdominal decompression. Journal of Trauma. 1999;651–46:646.
18. Dewey CW. Emergency management of the head trauma patient. Veterinary Clinics of North America: Small Animal Practice. 2000;30(1):207–225.