Is Routine Repeated Head CT Necessary for All Pediatric Traumatic Brain Injury?

Article information

J Korean Neurosurg Soc. 2015;58(2):125-130
Publication date (electronic) : 2015 August 28
doi : https://doi.org/10.3340/jkns.2015.58.2.125
Department of Neurosurgery, Korea University Ansan Hospital, Korea University College of Medicine, Ansan, Korea.
Address for reprints: Sang-Dae Kim, M.D., Ph.D. Department of Neurosurgery, Korea University Ansan Hospital, Korea University College of Medicine, 123 Jeokgeum-ro, Danwon-gu, Ansan 15355, Korea. Tel: +82-31-412-4893, Fax: +82-31-412-5054, neuron19@korea.ac.kr
Received 2015 April 24; Revised 2015 June 22; Accepted 2015 June 23.

Abstract

Objective

Repeated computed tomography (CT) follow up for traumatic brain injury (TBI) patients is often performed. But there is debate the indication for repeated CT scans, especially in pediatric patients. Purpose of our study is to find risk factors of progression on repeated CT and delayed surgical intervention based on the repeated head CT.

Methods

Between March, 2007 and December, 2013, 269 pediatric patients (age 0-18 years) had admitted to our hospital for head trauma. Patients were classified into 8 subgroups according to mechanisms of injury. Types, amount of hemorrhage and amount changes on repeated CT were analyzed as well as initial Glasgow Coma Scale (GCS) scores.

Results

Within our cohort of 269 patients, 174 patients received repeat CT. There were progression in the amount of hemorrhage in 48 (27.6%) patients. Among various hemorrhage types, epidural hemorrhage (EDH) more than 10 cc measured in initial CT was found to be at risk of delayed surgical intervention significantly after routine repeated CT with or without neurological deterioration than other types of hemorrhage. Based on initial GCS, severe head trauma group (GCS 3-8) was at risk of delayed surgical intervention after routine repeated CT without change of clinical neurologic status.

Conclusion

We suggest that the patients with EDH more than 10 cc or GCS below 9 should receive repeated head CT even though absence of significant clinical deterioration.

INTRODUCTION

Computed tomography (CT) scan for initial evaluation of traumatic brain injury (TBI) is well established1171922). Repeated CT scan is also performed for TBI occasionally. But the indication and timing for repeated CT scans in pediatric patients are not well established236). It may expose the patients to unnecessary harmful radiation exposure especially in children8). Besides, it may increase the cost of hospital care and there were some risks during transporting patients and sedation for irritable or incooperative patients. Accordingly, some authors argued that routine repeated CT scan should be avoided without evidence of clinical deteriorations421). On the other hands, some studies had shown that routine repeated CT scan could detect the progression of hemorrhage earlier and prevent or minimize the secondary brain injury with early intervention91418). In our study, patients were classified into several small groups according to the trauma mechanisms, type and amount of hemorrhage and initial Glasgow Coma Scale (GCS) to identify which influenced on the therapeutic plans or outcomes based on the repeated CT scan.

MATERIALS AND METHODS

All patients of age 0 to 18 years that had come and admitted to our hospital for head trauma between March, 2007 and December, 2013 were enrolled and retrospective chart review was done. Almost all patients had taken repeated CT scan at least two times before discharge. Patients were classified into 8 subgroups according to trauma mechanisms. Type and amount of hemorrhage or fracture and changes in the amount of hemorrhage on repeat CT were analyzed as well as initial GCS, Glasgow Outcome Scale (GOS), 6 months after trauma, need for surgical intervention. Severity of trauma based on GCS was classified into mild (GCS 13-15), moderate (9-12), severe (3-8) TBI groups. Lesions found at initial CT scan were classified into several groups including epidural hemorrhage (EDH), subdural hemorrhage (SDH), intracerebral hemorrhage (ICH), subarachnoid hemorrhage (SAH) or intraventricular hemorrhage (IVH), skull fracture without hemorrhage and diffuse axonal injury (DAI). We measured volume of hemorrhage from each CT scans to identify whether there were progressions or not. Patient's age, sex and interval between initial and repeated CT scan, GOS were recorded.

Evaluating factors (intracranial lesions classification and volume measurement and mechanism of injury)

Positive findings revealed from CT was classified into several types. These types included EDH, SDH, ICH, DAI, skull fracture without hematoma, SAH or IVH. Focal petechial deep white matter hematoma was regarded as DAI. Multiple lesions in a patient were recorded separately for the proper analysis. The volume of hematoma was measured by simple summation formula (0.5×height×depth×length)15). and classified into 3 groups (0-9 cc small, 10-19 cc medium, 20-29 cc large) according to their amount. All patients were classified into 8 subgroups according to the mechanism of injury with chart review. These included motor vehicle collision, pedestrian struck, bicycle collision, motorcycle collision, falls, beating, sports and suicidal accident.

Indications of surgery

Epidural hematoma greater than 30 cc was evacuated regardless of the patient's neurological status such as GCS score5). Another types of lesions such as SDH, ICH, depressed skull fracture, surgery was considered by CT findings including amount, depth and midline shifting correlated with patient's clinical status.

Statistical analysis

Risk factors of progression on repeated CT and of need for delayed surgery were analyzed with t-test for continuous variables such as age group with presenting as mean±standard deviation (SD) and Pearson's chi-square test for categorical variables such as sex, GCS, mechanism of injury, type of lesions. Independent associations were also analyzed by binary logistic regression with calculating odds ratios (ORs) and confidence intervals (CIs). At a later time, multivariate logistic regression was used to compare differences between the amount of hematoma for each types of lesions that caused delayed surgical intervention. The SPSS version 20.0 (IBM Corporation, Armonk, NY, USA) was used and p-values less than 0.05 were considered statistically significant.

RESULTS

Total 269 patients were admitted to our hospital for traumatic brain injury between March, 2007 and December, 2013. 9 patients underwent immediate emergency operation. Total 174 patients received repeat head CT within 24 hr after initial head CT scan. 125 (71.8%) patients were male and 49 (28.2%) patients were female. Mean age was 5.7 years with range from 1 month to 19 years. There were 154 (88.5%) mild TBI, 12 (6.9%) moderate TBI and 8 (4.6%) severe TBI based on GCS score. Falls (n=72, 41.4%) were leading cause among mechanism of injury groups, followed by motorcycle collisions (n=31, 17.8%). Total 196 lesions were found among 174 patients and EDH (n=66, 34.6%) was the leading type of lesions followed by skull fracture (n=40, 20.9%), ICH (n=30, 15.7%), SDH (n=32, 14.1%) in order. Number of total patients and lesions categorized by progression on repeated CT and delayed surgical intervention were recorded on Table 1.

Table 1

Characteristics of patients and type of lesions on CT with progression on repeated CT and delayed surgical intervention

Progression of intracranial lesions on repeated CT scan

Of the 174 patients who underwent repeat head CT, progression of intracranial lesions on repeat CT scan were found at 48 (27.6%) patients. Using t-test, age differences were found between progression on repeated CT and non progression. Progression on repeated CT group (mean±SD, 11.66±5.52) were significant older than non progression group (mean±SD, 7.74±6.35). Logistic regression analysis was performed and progression of volume of hematoma were determined for age, sex, initial GCS score, mechanisms of trauma, lesion types. Results of analysis was demonstrated on Table 2. Among those groups, age (OR 1.09, p=0.013), moderate TBI (OR 5.06, p=0.022), severe TBI (OR 34.62, p=0.002), EDH (OR 10.31, p<0.001) had significant relationship with progression of volume of hematoma. ICH (OR 3.00, p=0.067) was relatively found to be at risk of progression. Using Pearson's chi-square test, there was significant differences among mechanism of injury groups (p=0.003) between progression on repeated CT and non progression on repeated CT groups with leading percentage of progression in motorcycle collision groups (n=16 of 31, 51.6%). But logistic regression revealed no such significant findings as an independent risk factor of progression on repeated CT. Another types of intracranial lesions, sex, mechanism of trauma were not significantly associated with progression.

Table 2

Univariate and multivariate logistic regression for risk factors of progression on repeated CT

Delayed surgical intervention

Multivariate logistic regression analysis for the risk factors of delayed surgery was performed same as hematoma expansion. Results of analysis was demonstrated on Table 3. Severe TBI group (OR=136.17, p<0.001), EDH group (OR=14.95, p=0.012) were significantly associated with delayed surgical intervention. Age was not significantly associated (p=0.263) in contrast to being significantly associated with progression on repeated CT. Among 174 patients who received repeat CT, 14 (8.0%) patients underwent delayed surgical intervention with or without clinical deterioration after repeat CT. 10 patients for EDH, 2 patients for SDH, 1 patient for ICH, 1 patient for brain swelling with midline shifting underwent surgery for hematoma evacuation or decompression. Table 4 demonstrate characteristics of patients underwent delayed surgery. Among these patients, only two patients had neurological deterioration (pupillary dilatation) and performed immediate follow up head CT scan before surgery. Their characteristics were described on Table 4. All patients who underwent surgery was found to have volume of hematoma more than 30 cc on their repeat CT scan except one patient that had progression of swelling.

Table 3

Univariate and multivariate logistic regression for risk factors of delayed surgical intervention

Table 4

Characteristics of patients who underwent delayed surgical intervention

Type of hematoma and volume associated with surgical intervention

Further multivariate logistic regression analysis was performed for each type of hematoma and its volume. Results of analysis was demonstrated on Table 5. EDH, SDH, ICH were included for analysis and each were divided into 3 groups according to the initial amount (0-9 cc small, 10-19 cc medium, 20-29 cc large). Of these lesions, EDH more than 10 cc groups were significantly at an increased risk of progression more than 30 cc and underwent surgery. Medium EDH (OR=28.00, p=0.002), large EDH (OR=58.33, p<0.001) were associated to progression comparison to small EDH (OR=0.73, p=0.787). Another hematoma groups were not significantly associated.

Table 5

Multivariate logistic regression for risk factors of delayed surgical intervention among types of hematoma and their size

DISCUSSION

It is much harder to perform exact neurologic examination for the pediatric patients than adult patients. Occasionally it may lead to miss the early deterioration of their neurologic status and delay the golden time for intervention. Besides, all acute traumatic brain lesions have a chance to be progressive479111314161823). For these reasons, routine repeat head CT scan was performed in many pediatric patients. In our study, there were 48 (27.6%) progression on repeat CT among 174 patients and 14 (8.0%) patients underwent delayed surgical intervention. It is similar result to previous studies that progression on routine repeat CT reported 21-50% and need for delayed surgical intervention after repeat CT reported 1-24%2610131418).

Our study focused on the risk factors of progressive intracranial lesions and need for delayed surgical intervention including mechanisms of injury, type of intracranial lesions, GCS scores. But mechanisms of injury had no relations with progression of lesions or delayed surgical intervention on logistic regression in our study. But our study had limited records about severity of trauma mechanism, such as height of falling down, velocity of vehicle accident and so to perform more precise study, such things should be considered.

Several previous studies demonstrated that lower GCS score is a risk factor of injury progression as present study231320). Thorson et al.20) revealed that GCS score of less than 15 is associated with injury progression, and Lee et al.13) argued that severe head trauma (GCS 3-8) patients had more chance to have progression of repeat CT than in moderate head injury (GCS 9-12) patients. Aziz et al.2) showed that repeat head CT should be taken routinely in patients with intracranial hemorrhage with GCS score of 8 or less. Bata and Yung3), also concluded that of children with moderate to severe TBI, repeat head CT is more likely to alter management. As similar to those previous studies, our study demonstrated that moderate to severe TBI (GCS<13) had significant relationship with progression of volume of hematoma and severe TBI (GCS<9) was significantly associated with delayed surgical intervention after repeat head CT. On the other hand, some previous studies712) revealed that routine repeated CT is not recommended for the pediatric TBI patients. Kochanek et al.12) reviewed previous studies about pediatric TBI. Their level III recommendation based on previous study7), routine repeated CT may not be indicated in the absence of neurologic deterioration or increasing intracranial pressure (ICP). But ICP monitoring including extra-ventricular drainage, ICP probe insertion is an invasive procedure, especially more difficult to perform on pediatric patients. So there is limitation on the detection of neurologic decline and ICP monitoring in pediatric patients.

Among various types of intracranial lesions, EDH seemed to be at a risk of progression on repeat CT and EDH more than 10 cc was significantly associated with progression more than 30 cc and undergoing surgery in our study. These findings were similar to several previous studies. Howe et al.10) argued that routine repeat CT without clinical deterioration shoud be avoided but children with EDH had a higher potential for progression and routine repeat CT seems to be indicated in those cases. Durham et al.6) revealed EDH, SDH, cerebral edema, and intraparenchymal hemorrhage as a high risk lesions of progression and recommended repeated CT imaging without signs of clinical detereioration in pediatric TBI. In our study, as well as EDH revealed to be a risk factor of progression, ICH (OR 3.00, p=0.067) relatively found to be at risk of progression. In our study, differs from those previous studies, volume of hematoma was measured and demonstrated EDH more than 10 cc was at a risk of progression more than 30 cc and undergoing surgery among various hematoma lesion types. Washington and Grubb24) measured hematoma volume on serial head CT and revealed only an ICH>10 cc was independently associated with the risk of progression. This finding differed from our study but their study population was adult patients. In our study, 14 patients underwent surgery after repeated head CT. 2 patients had clinical deterioration (pupil dilatation) and underwent surgery after immediate repeated CT. Their outcomes were worse (GOS 2 and 3) than other patients underwent surgery after routine repeated CT without clinical deteriorations as seen on Table 3. These findings may suggest that early detection of the progression of hemorrhage prevent or minimize the secondary brain injury with early intervention as some authors emphasized.91418) Even a patient with initial GCS score 4 with EDH 18 cc on initial head CT and underwent surgery after routine repeat CT revealed expansion of hematoma to 110 cc had excellent outcome (GOS 5). In that case, no significant neurologic decline was found before routine repeated head CT.

CONCLUSION

Our study demonstrated that severe TBI (GCS below 9) or EDH more than 10 cc were significantly at an increased risk of hematoma expansion and altered management plans such as performing delayed surgical intervention. So in those cases, clinicians may consider repeated CT scan regardless of patient's neurological deterioration to minimize the complications. Routine repeated head CT is not necessary for EDH less than 10 cc, other types of intracranial lesions, mild to moderate TBI (GCS 9-15) patients regardless of their mechanism of injury.

References

1. Adelson PD, Bratton SL, Carney NA, Chesnut RM, du Coudray HE, Goldstein B, et al. Guidelines for the acute medical management of severe traumatic brain injury in infants, children, and adolescents. Chapter 5. Indications for intracranial pressure monitoring in pediatric patients with severe traumatic brain injury. Pediatr Crit Care Med 2003;4(3 Suppl):S19–S24. 12847341.
2. Aziz H, Rhee P, Pandit V, Ibrahim-Zada I, Kulvatunyou N, Wynne J, et al. Mild and moderate pediatric traumatic brain injury : replace routine repeat head computed tomography with neurologic examination. J Trauma Acute Care Surg 2013;75:550–554. 24064865.
3. Bata SC, Yung M. Role of routine repeat head imaging in paediatric traumatic brain injury. ANZ J Surg 2014;84:438–441. 24697988.
4. Brown CV, Weng J, Oh D, Salim A, Kasotakis G, Demetriades D, et al. Does routine serial computed tomography of the head influence management of traumatic brain injury? A prospective evaluation. J Trauma 2004;57:939–943. 15580014.
5. Bullock MR, Chesnut R, Ghajar J, Gordon D, Hartl R, Newell DW, et al. Surgical management of acute epidural hematomas. Neurosurgery 2006;58(3 Suppl):S7–S15. :discussion Si-Siv. 16710967.
6. Durham SR, Liu KC, Selden NR. Utility of serial computed tomography imaging in pediatric patients with head trauma. J Neurosurg 2006;105(5 Suppl):365–369. 17328259.
7. Figg RE, Stouffer CW, Vander Kolk WE, Connors RH. Clinical efficacy of serial computed tomographic scanning in pediatric severe traumatic brain injury. Pediatr Surg Int 2006;22:215–218. 16328336.
8. Frush DP, Donnelly LF, Rosen NS. Computed tomography and radiation risks : what pediatric health care providers should know. Pediatrics 2003;112:951–957. 14523191.
9. Givner A, Gurney J, O'Connor D, Kassarjian A, Lamorte WW, Moulton S. Reimaging in pediatric neurotrauma : factors associated with progression of intracranial injury. J Pediatr Surg 2002;37:381–385. 11877652.
10. Howe J, Fitzpatrick CM, Lakam DR, Gleisner A, Vane DW. Routine repeat brain computed tomography in all children with mild traumatic brain injury may result in unnecessary radiation exposure. J Trauma Acute Care Surg 2014;76:292–295. :discussion 295-296. 24458036.
11. Kaups KL, Davis JW, Parks SN. Routinely repeated computed tomography after blunt head trauma : does it benefit patients? J Trauma 2004;56:475–480. :discussion 480-481. 15128116.
12. Kochanek PM, Carney N, Adelson PD, Ashwal S, Bell MJ, Bratton S, et al. Guidelines for the acute medical management of severe traumatic brain injury in infants, children, and adolescents--second edition. Pediatr Crit Care Med 2012;13(Suppl 1):S1–S82. 22217782.
13. Lee TT, Aldana PR, Kirton OC, Green BA. Follow-up computerized tomography (CT) scans in moderate and severe head injuries : correlation with Glasgow Coma Scores (GCS), and complication rate. Acta Neurochir (Wien) 1997;139:1042–1047. :discussion 1047-1048. 9442218.
14. Oertel M, Kelly DF, McArthur D, Boscardin WJ, Glenn TC, Lee JH, et al. Progressive hemorrhage after head trauma : predictors and consequences of the evolving injury. J Neurosurg 2002;96:109–116. 11794591.
15. Petersen OF, Espersen JO. Extradural hematomas : measurement of size by volume summation on CT scanning. Neuroradiology 1984;26:363–367. 6544377.
16. Servadei F, Nanni A, Nasi MT, Zappi D, Vergoni G, Giuliani G, et al. Evolving brain lesions in the first 12 hours after head injury : analysis of 37 comatose patients. Neurosurgery 1995;37:899–906. :discussion 906-907. 8559338.
17. Shackford SR, Wald SL, Ross SE, Cogbill TH, Hoyt DB, Morris JA, et al. The clinical utility of computed tomographic scanning and neurologic examination in the management of patients with minor head injuries. J Trauma 1992;33:385–394. 1404507.
18. Smith JS, Chang EF, Rosenthal G, Meeker M, von Koch C, Manley GT, et al. The role of early follow-up computed tomography imaging in the management of traumatic brain injury patients with intracranial hemorrhage. J Trauma 2007;63:75–82. 17622872.
19. Stein SC, Fabbri A, Servadei F. Routine serial computed tomographic scans in mild traumatic brain injury : when are they cost-effective? J Trauma 2008;65:66–72. 18580532.
20. Thorson CM, Van Haren RM, Otero CA, Guarch GA, Curia E, Barrera JM, et al. Repeat head computed tomography after minimal brain injury identifies the need for craniotomy in the absence of neurologic change. J Trauma Acute Care Surg 2013;74:967–973. :discussion 973-975. 23511133.
21. Velmahos GC, Gervasini A, Petrovick L, Dorer DJ, Doran ME, Spaniolas K, et al. Routine repeat head CT for minimal head injury is unnecessary. J Trauma 2006;60:494–499. :discussion 499-501. 16531845.
22. Vos PE, Battistin L, Birbamer G, Gerstenbrand F, Potapov A, Prevec T, et al. EFNS guideline on mild traumatic brain injury : report of an EFNS task force. Eur J Neurol 2002;9:207–219. 11985628.
23. Wang MC, Linnau KF, Tirschwell DL, Hollingworth W. Utility of repeat head computed tomography after blunt head trauma : a systematic review. J Trauma 2006;61:226–233. 16832279.
24. Washington CW, Grubb RL Jr. Are routine repeat imaging and intensive care unit admission necessary in mild traumatic brain injury? J Neurosurg 2012;116:549–557. 22196096.

Article information Continued

Table 1

Characteristics of patients and type of lesions on CT with progression on repeated CT and delayed surgical intervention

Table 1

t-test for age, Pearson's chi-square test for sex, GCS, mechanism of injury, type of lesions were used. CT : computed tomography, GCS : Glasgow Coma Scale, TBI : traumatic brain injury, EDH : epidural hemorrhage, SDH : subdural hemorrhage, ICH : intracerebral hemorrhage, DAI : diffuse axonal injury, SAH : subarachnoid hemorrhage, IVH : intraventricular hemorrhage

Table 2

Univariate and multivariate logistic regression for risk factors of progression on repeated CT

Table 2

OR : odds ratio, CI : confidence interval, TBI : traumatic brain injury

Table 3

Univariate and multivariate logistic regression for risk factors of delayed surgical intervention

Table 3

OR : odds ratio, CI : confidence interval, TBI : traumatic brain injury

Table 4

Characteristics of patients who underwent delayed surgical intervention

Table 4

*Progression of swelling with midline shifting was mainly attributed, 6 months after trauma. GCS : Glasgow Coma Scale, GOS : Glasgow Outcome Scale, CT : computed tomography, I : intubated, EDH : epidural hemorrhage, SDH : subdural hemorrhage, ICH : intracerebral hemorrhage, Rt : right, Lt : left, Cbll : Cerebellar, F : frontal, T : temporal, P : parietal

Table 5

Multivariate logistic regression for risk factors of delayed surgical intervention among types of hematoma and their size

Table 5

Small : 0-9 cc, Medium : 10-19 cc, Large : 20-29 cc. EDH : epidural hemorrhage, SDH : subdural hemorrhage, ICH : intracerebral hemorrhage, OR : odds ratio, CI : confidence interval