Korean J Neurotrauma. 2021 Apr;17(1):34-40. English.
Published online Apr 20, 2021.
Copyright © 2021 Korean Neurotraumatology Society
Original Article

Comparisons of Radiological and Clinical Characteristics between Traumatic and Non-traumatic Subdural Hematoma Patients

Jun Gue Seo, Joochul Yang, Ji Hye Lee, Inho Oh, Tae Wan Kim, and Kwan Ho Park
    • Department of Neurosurgery, VHS Medical Center, Seoul, Korea.
Received July 17, 2020; Revised March 26, 2021; Accepted March 29, 2021.

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (https://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Objective

Subdural hematoma (SDH) primarily occurs in elderly patients. While most patients have good prognosis, some do not. Hematoma recurrence is one of the factors influencing prognosis. Moreover, some characteristic radiological factors may increase the recurrence rate. The aim of this study was to investigate whether the presence of trauma influenced radiological characteristics and hematoma recurrence in SDH patients treated with burr hole trephination.

Methods

From January 2012 to December 2014, we selected 83 patients diagnosed with unilateral SDH using computed tomography and/or magnetic resonance imaging. We divided the patients into 2 groups based on the presence of trauma. We compared the 2 groups with multiple parameters, such as patient factors, radiological characteristics, and recurrence rate.

Results

Patients who had a prolonged international normalized ratio (INR) were significantly more common in the non-traumatic SDH group (22.2%:55.2%, p=0.002). There was no statistical difference in radiological parameters between the 2 groups. The recurrence rate was marginally higher in the non-traumatic SDH group (14.8%:17.2%, p=0.502), but this difference was not statistically significant.

Conclusion

There were no statistically significant differences in the radiological findings, including brain atrophy, hematoma density, thickness of hematoma, and degree of midline shifting between the 2 groups. The associated trauma history may not influence recurrence. Anticoagulants medication influence INR prolongation, and commonly shown in non-traumatic group, but not statistically. INR prolongation was statistically more common in non-traumatic SDH patients than in traumatic SDH patients. INR prolongation is only a different characteristic between 2 groups.

Keywords
Subdural hematoma; Trauma; International normalized ratio; Recurrence

INTRODUCTION

Subdural hematoma (SDH) occurs mainly in elderly patients. Most elderly patients who exhibit midline shifting have shown poor outcomes without surgery.5) Most symptomatic patients are treated surgically using burr hole trephination and closed-system drainage. The majority of patients have a good prognosis, but hematoma recurrence is observed in some patients, which may influence outcomes. Definitive operative methods remain controversial. Computed tomography (CT) remains the most important diagnostic tool.

While some patients had experienced head trauma, others did not. We retrospectively analyzed patient factors and radiological differences by CT and/or magnetic resonance (MR) imaging, and subsequently investigated whether the presence of trauma influenced the radiological characteristics and recurrence of SDH.

MATERIALS AND METHODS

Patient selection

From January 2012 to December 2014, we selected 83 patients diagnosed with unilateral SDH using CT and/or MR imaging. Sometimes, the presence or absence of trauma history was ambiguous. We therefore questioned patients regarding their trauma history, including minor trauma, or questioned family members if the patients were not alert and no external wound was observed at admission. We defined non-traumatic hematomas as the absence of memory of trauma and external wounds. Among them, 24 patients underwent CT only before surgery, and 52 underwent both CT and MR imaging. Only MR imaging was performed in 7 patients. All patients underwent surgical treatment using burr hole trephination and closed-system drainage. The patients comprised 75 men and 8 women, with a mean age of 75.72 years (range; 50–88 years). We divided the patients into 2 groups based on the presence or absence of trauma history (group A, traumatic SDH; group B, non-traumatic SDH). Fifty-four patients were assigned to group A and 29 patients to group B.

Analytic parameters

We compared the 2 groups using multiple parameters: hypertension history, use of antiplatelet and/or anticoagulant medication, prolongation of international normalized ratio (INR), side of hematoma, presence of brain atrophy, hematoma density (mixed or single density), hematoma thickness, and degree of midline shifting. INR is the ratio of a patient's prothrombin time to a normal sample. The normal range of INR was 0.93 to 1.14 in our hospital. Therefore, prolongation of INR was defined more than 1.15. Brain atrophy was classified using the Pasquier cortical atrophy scale.16) Presence of brain atrophy was defined scale 2 and 3 in this study. Mixed hematoma density was classified as either separated, laminar, or trabecular type. Hematoma thickness was measured as the maximal thickness of the hematoma. All radiological data were measured using CT scan, except for 7 patients who did not undergo CT scans, in which case, we used MR imaging. Two authors double-checked all radiological data and used the average value of degree of midline shifting and hematoma thickness to calculate the maximal thickness.

Statistical analysis

Fisher's exact test, t-test and multivariate analysis of variance were used for statistical analysis using SPSS (version 18.0; SPSS Inc, Chicago, IL, USA). A p-value of less than 0.05 was considered statistically significant.

RESULTS

Patient factor

Fifty-two patients were found to have taken antihypertensive medication, out of which 35 were classified into group A, and 17 were classified into group B (64.8%:58.6%, p=0.373).

Thirty-eight patients had taken antiplatelet and/or anticoagulant medications, of which 22 were in group A, and 16 patients in group B. The number of patients who had taken antiplatelet and/or anticoagulant medication was higher in group B, but this difference was not statistically significant (40.7%:55.2%, p=0.152). Among them, 28 patients were taken antiplatelet medication, and the rest 10 patients were taken anticoagulant. Patients who taken antiplatelet medication were common in group B, but not statistically (9.3%:17.2%, p=0.287). Patients who taken anticoagulants were also common in group B, but also not statistically (29.6%:41.4%, p=0.280).

All patients who taken anticoagulants except one (9/10) were INR prolonged state. The mean INR was 1.343±0.36. Fifteen patients were shown INR prolongation among 28 antiplatelet medication patients and mean INR was 1.105±1.16. Four non-medication patients were also shown INR prolongation and mean INR was 1.056±0.08. INR prolongation was commonly noted in anticoagulants medication patients compare to other patients, statistically (p<0.001).

INR prolongation was noted in 28 patients. Twelve were in group A, and 16 in group B. Patients with a prolonged INR were statistically more common in group B (22.2%:55.2%, p=0.002) (TABLE 1).

TABLE 1
Comparison of demographic data between the 2 groups

Radiological finding

A hematoma on the left side was observed in 44 patients, including 29 in group A and 15 in group B (53.7%:51.7%, p=0.523).

Mixed-density within the hematoma was observed in 38 patients. In group A, 23/54 patients had a mixed-density hematoma, while 15/29 patients in group B exhibited the same. Mixed density hematomas were more common in group B (42.6%:51.7%); however, this difference was not statistically significant (p=0.286).

Separated-type hematomas were observed in 9 patients and laminar-type hematomas in 7 patients. The separated type was more common in group A (30.4%:13.3%), whereas the laminar type was more common in group B (13.0%:26.7%), but this observation was not statistically significant (p=0.208 and 0.261, respectively).

In group A, 23 patients were scale 0, 12 were scale 1, 17 were scale 2, and 2 were scale 3. In group B, 12 patients were scale 0, 6 were scale 1, 9 were scale 2, and 2 were scale 3. Associated brain atrophy was observed in 30 patients, with 19 in group A, and 11 in group B. Associated brain atrophy was more common in group B than in group A (35.2%:37.9%), but the difference was not statistically significant (p=0.494).

The mean thickness of hematoma in group A was slightly thicker than that in group B (21.22 mm:20.59 mm), although the difference was not statistically significant (p=0.921).

The mean degree of midline shift in group A was greater than that in group B (10.11 mm:9.84 mm), which was not statistically significant (p=0.818).

Mixed density hematoma and associated brain atrophy were more common in group B, while the mean thickness of hematoma and the degree of midline shift were marginally greater in group A. However, none of these results were statistically significant (TABLE 2).

TABLE 2
Comparison of radiological data between the 2 groups

INR prolongation was also the only significant difference between 2 groups on multivariate analysis of variance (TABLE 3).

TABLE 3
Multivariable analysis of traumatic subdural hematoma group

Recurrence

Thirteen patients underwent reoperation due to hematoma recurrence. All patients underwent surgery using a previous burr hole. Eight patients in group A and 5 in group B had recurrence. There was no statistically significant difference in the occurrence rate between the 2 groups (14.8%:17.2%, p=0.502). The results indicate that the etiology of SDH may not influence the recurrence rate, either traumatically or non-traumatically.

DISCUSSION

The mechanism underlying SDH formation remains unclear. Increased osmotic pressure between the hematoma and blood vessels, genesis of the neomembrane, and subsequent growth of new vessels are known to be important factors in enlarging the hematoma.

Risk factors for the genesis of spontaneous SDH include hypertension, use of anticoagulants and antiplatelet agents, alcohol addiction, and intracranial hypotension. Cerebral atrophy is a significant factor in the development of hematomas at all ages, especially those less than 65 years.22) A high co-morbidity rate was noted in the non-trauma group, although this was not statistically significant.3) Anticoagulant therapy is the most significant risk factor, and hypertension may be a statistically significant risk factor for patients older than 70 years. Simultaneous anticoagulant and antiplatelet therapy resulted in significantly high rate of occurrence of chronic SDH.7) Anticoagulant and/or antiplatelet medications influence hematoma progression and expansion.23) Anticoagulant and/or antiplatelet agent use are more prevalent in non-traumatic chronic SDH patients, while mean INR levels were significantly higher in the non-traumatic SDH group, but may not have influence the recurrence rate.3) In this study, anticoagulant and/or antiplatelet agent use was also more common in the non-traumatic SDH patient group, and patients with prolonged INR were significantly more common in the non-traumatic SDH group, however this had no influence on the recurrence rate.

The most important factor in the development of chronic SDH is sufficient subdural space, namely brain atrophy.8) Other important precipitating factors are trauma and coagulopathy.9) Severe brain atrophy and larger subdural space volumes are prone to SDH development when head trauma has occurred.6) In this study, brain atrophy was not common in the traumatic SDH group.

Midline shifting, mixed-density hematomas, and larger hematoma thickness may accelerate hematoma progression, but the existence of trauma and the underlying mechanism did not influence hematoma progression.18) Any correlations between the progression of hematoma and anticoagulants and/or antiplatelet medication are unclear.20)

Various factors influencing hematoma recurrence have been mentioned in several studies, but these factors have not been shown to influence recurrence in other studies. The presence of seizure history and absence of diabetes mellitus are closely related to hematoma recurrence.21) Loculation and unilaterality of hematoma, old age, large hematoma thickness, and midline shift may be correlated with the occurrence of hemiparesis.11) Hematoma thickness and density, bilaterality of hematoma, presence of brain atrophy, degree of midline shifting, postoperative residual air, and postoperative residual space of hematoma are known predictors of recurrence.19) Large postoperative residual hematoma volume and anticoagulant therapy are also predisposing factors for recurrence.10, 12) Anticoagulant medication was associated with increased rebleeding risk, but antiplatelet medication was not,14) and vice versa.17) Old age, male sex,13) presence of hematoma loculation on preoperative CT,12) and high or mixed hematoma density15) are all independent predictive factors of recurrence. On initial CT, laminar and separated type mixed-density hematomas had a higher recurrence rate, whereas trabecular type hematomas had a lower recurrence rate.19) In this study, mixed-density hematomas were more commonly noted in the non-traumatic group, while the separated type was more common in the traumatic group, although the latter was not statistically significant. Meanwhile, the laminar type was more common in the non-traumatic group. Mixed density hematoma type did not influence the recurrence rate.

Mixed-density hematomas were significantly thicker than other types of hematomas.4) Patients with preoperative hematoma volumes <115 mL had a low recurrence rate,19) while those with preoperative hematomas thicker than 20 mm had a higher recurrence rate.1) In this study, there was no difference in hematoma thickness between the 2 groups.

The presence of trauma history was not influenced by the recurrence rate.2, 3) In this study, there was no statistically significant difference in the recurrence rate between the 2 groups.

The limitation of this study was its retrospective nature and relatively small subjective groups. In addition, some patients underwent MR imaging for analysis. In addition, the 2 subjective groups were treated using the same operative method. If the study included all SDH patients, including those who underwent conservative treatment and craniotomy, different results may have been observed.

CONCLUSION

There were no statistically significant differences in the radiological findings, including brain atrophy, hematoma density, thickness of hematoma, and degree of midline shifting between the 2 groups. The associated trauma history may not influence recurrence. Anticoagulants medication influence INR prolongation, and commonly shown in non-traumatic group, but not statistically. INR prolongation was statistically more common in non-traumatic SDH patients than in traumatic SDH patients. INR prolongation is only a different characteristic between 2 groups.

Notes

Conflict of Interest:The authors have no financial conflicts of interest.

References

    1. Altaf I, Shams S, Vohra AH. Radiolological predictors of recurrence of chronic subdural hematoma. Pak J Med Sci 2018;34:194–197.
    1. Amirjamshidi A, Abouzari M, Eftekhar B, Rashidi A, Rezaii J, Esfandiari K, et al. Outcomes and recurrence rates in chronic subdural haematoma. Br J Neurosurg 2007;21:272–275.
    1. Aspegren OP, Åstrand R, Lundgren MI, Romner B. Anticoagulation therapy a risk factor for the development of chronic subdural hematoma. Clin Neurol Neurosurg 2013;115:981–984.
    1. Fujisawa H, Nomura S, Kajiwara K, Kato S, Fujii M, Suzuki M. Various magnetic resonance imaging patterns of chronic subdural hematomas: indicators of the pathogenesis? Neurol Med Chir (Tokyo) 2006;46:333–338.
    1. Jones S, Kafetz K. A prospective study of chronic subdural haematomas in elderly patients. Age Ageing 1999;28:519–521.
    1. Ju MW, Kim SH, Kwon HJ, Choi SW, Koh HS, Youm JY, et al. Comparison between brain atrophy and subdural volume to predict chronic subdural hematoma: volumetric CT imaging analysis. Korean J Neurotrauma 2015;11:87–92.
    1. Kostić A, Kehayov I, Stojanović N, Nikolov V, Kitov B, Milošević P, et al. Spontaneous chronic subdural hematoma in elderly people - Arterial hypertension and other risk factors. J Chin Med Assoc 2018;81:781–786.
    1. Lee KS. Chronic subdural hematoma in the aged, trauma or degeneration? J Korean Neurosurg Soc 2016;59:1–5.
    1. Lee KS, Yoon SM, Oh JS, Oh HJ, Shim JJ, Doh JW. Causes and trauma apportionment score of chronic subdural hematoma. Korean J Neurotrauma 2018;14:61–67.
    1. Miki K, Abe H, Morishita T, Hayashi S, Yagi K, Arima H, et al. Double-crescent sign as a predictor of chronic subdural hematoma recurrence following burr-hole surgery. J Neurosurg 2019;131:1905–1911.
    1. Motiei-Langroudi R, Alterman RL, Stippler M, Phan K, Alturki AY, Papavassiliou E, et al. Factors influencing the presence of hemiparesis in chronic subdural hematoma. J Neurosurg 2019;131:1926–1930.
    1. Motiei-Langroudi R, Stippler M, Shi S, Adeeb N, Gupta R, Griessenauer CJ, et al. Factors predicting reoperation of chronic subdural hematoma following primary surgical evacuation. J Neurosurg 2018;129:1143–1150.
    1. Motoie R, Karashima S, Otsuji R, Ren N, Nagaoka S, Maeda K, et al. Recurrence in 787 patients with chronic subdural hematoma: retrospective cohort investigation of associated factors including direct oral anticoagulant use. World Neurosurg 2018;118:e87–e91.
    1. Nathan S, Goodarzi Z, Jette N, Gallagher C, Holroyd-Leduc J. Antcoagulant and antiplatelet use in seniors with chronic subdural hematoma. Neurology 2017;88:1889–1893.
    1. Park WB, Kim YI, Cho CB, Yang SH, Kim IS, Hong JT, et al. Chronic subdural hematoma in elderly patients: consideration of preoperative risk factors for recurrence. J Korean Soc Geriatr Neurosurg 2016;12:135–139.
    1. Pasquier F, Leys D, Weerts JG, Mounier-Vehier F, Barkhof F, Scheltens P. Inter- and intraobserver reproducibility of cerebral atrophy assessment on MRI scans with hemispheric infarcts. Eur Neurol 1996;36:268–272.
    1. Poon MT, Al-Shahi Salman R. Association between antithrombotic drug use before chronic subdural haematoma and outcome after drainage: a systematic review and meta-analysis. Neurosurg Rev 2018;41:439–445.
    1. Son S, Yoo CJ, Lee SG, Kim EY, Park CW, Kim WK. Natural course of initially non-operated cases of acute subdural hematoma: the risk factors of hematoma progression. J Korean Neurosurg Soc 2013;54:211–219.
    1. Stanišić M, Hald J, Rasmussen IA, Pripp AH, Ivanović J, Kolstad F, et al. Volume and densities of chronic subdural haematoma obtained from CT imaging as predictors of postoperative recurrence: a prospective study of 107 operated patients. Acta Neurochir (Wien) 2013;155:323–333.
    1. Vega RA, Valadka AB. Natural history of acute subdural hematoma. Neurosurg Clin N Am 2017;28:247–255.
    1. Yamamoto H, Hirashima Y, Hamada H, Hayashi N, Origasa H, Endo S. Independent predictors of recurrence of chronic subdural hematoma: results of multivariate analysis performed using a logistic regression model. J Neurosurg 2003;98:1217–1221.
    1. Yang AI, Balser DS, Mikheev A, Offen S, Huang JH, Babb J, et al. Cerebral atrophy is associated with development of chronic subdural haematoma. Brain Inj 2012;26:1731–1736.
    1. Yang W, Huang J. Chronic subdural hematoma epidemiology and natural history. Neurosurg Clin N Am 2017;28:205–210.

Metrics
Share
Tables

1 / 3

PERMALINK