Introduction
It is of common medical knowledge that the incidence of intracranial hemorrhage of traumatic and spontaneous origins is dependent on multiple variables such as, and among others, access to medication and medical care, lifestyle, genetic predisposition, traffic hazards, work security conditions, and crime issues. Despite the difficulty in calculating the weight that each variable may have in the incidence of intracranial hemorrhage, this indicator can serve to characterize the health status of a community. Computed tomography (CT) scan is the most widely used method for diagnosing intracranial hemorrhage and its efficacy is well defined. At present, available software used for viewing and archiving medical imaging, as well as reports, allows for easy access to all the examinations performed in a certain period of time and to the diagnoses made. The aim of this study was to document the patterns of intracranial hemorrhage encountered by means of brain CT scan in a large urban community in Northern Portugal, and further characterize the chief complaint that led to the diagnosis, providing ciphers in the perspective of descriptive epidemiology that are not readily available. Monitoring the incidence of pathologies that can have devastating neurological outcomes such as head injury and hemorrhagic stroke is of uttermost relevance; if rates encountered compare unfavorably to those of others, study and adoption of efficacious measures aimed at the prevention of these disorders and events should lead to their decrease and to consequent improvements in the health status of the community.
Methods
The population studied had access to one public hospital with a neurological and neurosurgical unit that had recently started to cover emergency cases. On the one hand, this obviated the need to transfer patients from the hospital to referral institutions as well as direct referral to those institutions from the street. On the other hand, the catchment area was well defined since at that initial time, the hospital aimed only at its direct catchment area, and hospitals from the potential indirect catchment area continued to refer patients to previously established referral institutions. A population census had been performed in the year before the study period that provided an accurate figure of 334,081 inhabitants in the direct catchment area of the hospital (two municipalities)1. Private facilities available in the area did not, in general, assume surgical cases or complex inpatients, referring them to the public hospital. It was assumed that patients living in other locations that were diagnosed and treated in the hospital (“passers-by”) would compensate for potential patients of the hospital’s direct catchment area treated at outside institutions.
The software used for archiving and viewing of imaging was used to review all the brain CT scans performed in the hospital in a 1-year period (April 2012-March 2013 – Philips Brilliance CT 64 Channel device), along with the summarized clinical information that motivated the examination, the report performed as well as the age and gender of the patients. All the information was obtained from one computer program (Pacs Sectra). Categories used to classify the chief complaint provided by the referring physician were head injury, speech and cognition complaints, headaches, seizures, stupor, syncope, “follow-up,” sensory complaints, motor complaints, post-operative, and “not provided.” If an event of acute trauma was present, this was assumed as the chief complaint, unless it was subsequent to another event such as syncope. If more than one category was present, for example, speech and motor deficits, the category assumed was the one that the referring clinician mentioned first in the clinical information. Categories used to classify the patterns of intracranial hemorrhage reported by the radiologist were acute subdural and traumatic subarachnoid, epidural, spontaneous cerebral corticosubcortical, spontaneous basal ganglia, spontaneous cerebellar, parenchymal contusion, chronic subdural, ventricular, brainstem, and spontaneous subarachnoid. If more than one category was present, for example, basal ganglia and ventricular, the category assumed was the one that the radiologist described as predominant. If this could not be inferred from the report, the category assumed was the one mentioned first by the radiologist. A volumetric subclassification was not undertaken in this study, meaning that a hemorrhage classified as epidural could range from a minor film to massive. Overlap of categories is well acknowledged as a confounding factor, but these typifications had to be employed given the large size of the sample and the multitude of possible clinical situations and imaging findings. Sorting of data and calculations (including Chi-square analysis/Fisher’s exact test with mid-P method/t-test/95% confidence limits score of Wilson) were performed with widely available spreadsheet and statistical analysis software (Microsoft Excel and OpenEpi).
Results
A total of 8516 patients (3855 males, M/F ratio 0.83; mean age in years 63.31; median 67.72; range 0.15–102.30; standard deviation 20.24) underwent 10,884 brain CT scans, implying a global ratio of 1.28 CT scans per patient. This ratio of CT scans per patient deserved further analysis and was viewed in the context of repeat CT scans to follow hemorrhagic pathology previously encountered, as well as new clinical situations affecting the patients, either of the same, or from a different nature. The number of patients that underwent repeat CT scan was indeed 1379 (16.19%), and they underwent 3733 CT scans, implying a corrected ratio of 2.70 per patient in these patients. Hemorrhage was present in the initial CT scan of 303 of the patients that underwent repeat scans (21.97%). Thirty-two initially “unidentified” patients that possibly underwent repeat scans as identified patients could contribute to this figure as well. A uniform criterion to distinguish between repeat CT scans that represented follow-up of know situations versus those that represented concomitant or new clinical situations was not achieved, and these subsequent CT scans were excluded from the remaining analysis. It is acknowledged that this may underestimate certain ciphers. The frequency of chief complaints that motivated the first CT scan performed by the patients in the study period is displayed in table 1. Hemorrhage was present in 448 (5.26%) of these initial CT scans. The frequency of hemorrhage per chief indication is detailed in table 2, and Chi-square analysis with p < 0.05 supported relevant differences in the proportions found; the frequency of patterns encountered is summarized in table 3. Incidence rates of the diverse situations are shown in table 4. Incidence rates were calculated using as numerator the registered occurrences of clinical situations/imaging findings obtained from the analysis of the CT scans in the 1-year period multiplied by 100,000 and as denominator the 334,081 inhabitants of the direct catchment area of the hospital. Certain age and gender variations according to clinical context and type of hemorrhage are reported in table 5.
Chief complaint | Patients (n) | Percentage/(**) |
---|---|---|
Head injury | 2564 | 30.11 (29.1431.09) |
Cognition and speech | 1273 | 14.95 (14.2115.72) |
Headache | 1260 | 14.80 (14.0615.57) |
Sensory | 909 | 10.67 (10.0411.35) |
Motor | 729 | 8.56 (7.989.17) |
Syncope | 472 | 5.54 (5.076.04) |
Seizures | 369 | 4.33 (3.924.78) |
Not provided | 296 | 3.48 (3.103.88) |
Followup | 286 | 3.36 (2.993.76) |
Stupor | 280 | 3.29 (2.933.68) |
Postoperative | 78 | 0.92 (0.731.14) |
Total | 8516 | 100.00 |
**95% Confidence limits score (Wilson). CT: Computed tomography
Chief complaint | Patients without hemorrhage (n) | Patients with hemorrhage (n) | Percentage hemorrhage by complaint/(**) |
---|---|---|---|
Head injury | 2365 | 199 | 7.76 (6.788.86) |
Cognition and speech | 1237 | 36 | 2.83 (2.053.89) |
Headache | 1236 | 24 | 1.90 (1.282.81) |
Sensory | 899 | 10 | 1.10 (0.592.01) |
Motor | 695 | 34 | 4.66 (3.356.44) |
Syncope | 461 | 11 | 2.33 (1.304.12) |
Seizures | 360 | 9 | 2.44 (1.284.57) |
Not provided | 284 | 12 | 4.05 (2.336.95) |
Followup | 239 | 47 | 16.43 (12.5921.17) |
Stupor | 249 | 31 | 11.07 (7.9115.29) |
Postoperative | 43 | 35 | 44.87 (34.3355.89) |
8068 | 448 |
**95% Confidence limits score (Wilson)
Type of hemorrhage | Patients (n) | Percentage/(**) |
---|---|---|
Acute subdural | 166 | 37.05 (32.7141.62) |
Cerebellar | 10 | 2.23 (1.214.05) |
Contusion | 72 | 16.07 (12.9619.76) |
Corticosubcortical | 58 | 12.95 (10.1516.37) |
Chronic subdural | 30 | 6.70 (4.739.39) |
Epidural | 17 | 3.79 (2.385.99) |
Basal ganglia | 61 | 13.62 (10.7517.1) |
Spontaneous subarachnoid | 18 | 4.02 (2.556.26) |
Brainstem | 4 | 0.89 (0.342.27) |
Ventricular | 12 | 2.68 (1.534.62) |
Total | 448 | 100.00 |
**95% Confidence limits score (Wilson)
Chief complaint | No hemorrhage | Acute subdural | Cerebellar | Contusion | Corticosubcortical | Chronic subdural | Epidural | Basal ganglia | Spontaneous subarachnoid | Brainstem | Ventricular | Total |
---|---|---|---|---|---|---|---|---|---|---|---|---|
Head injury | 707.91 (679.8736.9) | 36.52 (30.4643.45) | 0.30 (0.011.47) | 14.67 (10.9719.23) | 0.30 (0.011.47) | 1.80 (0.723.73) | 4.19 (2.386.86) | 0.90 (0.222.44) | 0.00 | 0.00 | 0.90 (0.222.44) | 767.48 (738.2797.6) |
Cognition and speech | 370.27 (350.1391.3) | 0.30 (0.011.47) | 0.00 | 0.00 | 3.89 (2.166.48) | 1.50 (0.543.31) | 0.00 | 4.79 (2.837.61) | 0.30 (0.011.47) | 0.00 | 0.00 | 381.05 (360.5402.4) |
Headache | 369.97 (349.8391) | 0.30 (0.011.47) | 0.00 | 0.00 | 2.39 (1.114.54) | 0.90 (0.222.44) | 0.00 | 0.30 (0.011.47) | 2.39 (1.114.54) | 0.00 | 0.90 (0.222.44) | 377.15 (356.8398.4) |
Sensory | 269.10 (251.9287.1) | 0.30 (0.011.47) | 0.60 (0.11.97) | 0.30 (0.011.47) | 0.30 (0.011.47) | 0.60 (0.101.97) | 0.00 | 0.60 (0.11.97) | 0.00 | 0.30 (0.011.47) | 0.00 | 272.09 (254.8290.2) |
Motor | 208.03 (193223.9) | 0.30 (0.011.47) | 0.00 | 0.60 (0.101.97) | 1.80 (0.723.73) | 0.30 (0.011.47) | 0.00 | 6.59 (4.239.80) | 0.30 (0.011.47) | 0.00 | 0.30 (0.011.47) | 218.21 (202.8234.5) |
Syncope | 137.99 (125.8151) | 1.50 (0.543.31) | 0.00 | 0.30 (0.011.47) | 0.00 | 0.30 (0.011.47) | 0.00 | 0.60 (0.101.97) | 0.30 (0.011.47) | 0.30 (0.011.47) | 0.00 | 141.28 (129154.5) |
Seizures | 107.76 (97.05119.3) | 0.60 (0.101.97) | 0.00 | 0.00 | 1.50 (0.543.31) | 0.60 (0.101.97) | 0.00 | 0.00 | 0.00 | 0.00 | 0.00 | 110.45 (99.6122.2) |
Not provided | 85.01 (75.5595.34) | 0.90 (0.222.44) | 0.30 (0.011.47) | 0.30 (0.011.47) | 0.60 (0.101.97) | 0.00 | 0.00 | 0.60 (0.101.97) | 0.00 | 0.30 (0.011.47) | 0.60 (0.101.97) | 88.60 (78.9399.14) |
Followup | 71.54 (62.8981.05) | 5.39 (3.298.35) | 0.60 (0.101.97) | 3.29 (1.735.72) | 1.20 (0.382.88) | 1.80 (0.723.73) | 0.30 (0.011.47) | 0.90 (0.222.44) | 0.00 | 0.00 | 0.60 (0.101.97) | 85.61 (76.1195.97) |
Stupor | 74.53 (65.784.23) | 2.10 (0.914.14) | 0.90 (0.222.44) | 0.60 (0.101.97) | 0.60 (0.101.97) | 0.30 (0.011.47) | 0.30 (0.011.47) | 2.99 (1.525.33) | 0.90 (0.222.44) | 0.30 (0.011.47) | 0.30 (0.011.47) | 83.81 (74.4294.07) |
Postoperative | 12.87 (9.4317.18) | 1.50 (0.543.31) | 0.30 (0.011.47) | 1.50 (0.543.31) | 4.79 (2.837.61) | 0.90 (0.222.44) | 0.30 (0.011.47) | 0.00 | 1.20 (0.382.88) | 0.00 | 0.00 | 23.35 (18.5828.98) |
Total | 2414.98 (23632468) | 49.69 (42.5557.69) | 2.99 (1.525.33) | 21.55 (16.9926.98) | 17.36 (13.322.28) | 8.98 (6.1712.66) | 5.09 (3.067.98) | 18.26 (14.0923.3) | 5.39 (3.298.35) | 1.20 (0.382.88) | 3.59 (1.946.10) | 2549.08 (24952604) |
Scenario | Total patients | Males | Females | M/F ratio | Mean age (yy) | Median | Min. | Max. | SD |
---|---|---|---|---|---|---|---|---|---|
Global | 8516 | 3855 | 4661 | 0.83 | 63.31 | 67.72 | 0.15 | 102.30 | 20.24 |
Head injury | 2564 | 1207 | 1357 | 0.89 | 63.72 | 70.25 | 0.15 | 102.30 | 22.46 |
Hemorrhage | 448 | 244 | 204 | 1.20 | 66.88 | 71.74 | 0.52 | 97.79 | 19.22 |
Head injury with hemorrhage | 199 | 122 | 77 | 1.58 | 65.87 | 72.92 | 0.52 | 97.79 | 22.22 |
Basal ganglia | 61 | 39 | 22 | 1.77 | 73.31 | 74.54 | 40.61 | 91.77 | 11.33 |
Corticosubcortical spontaneous | 58 | 26 | 32 | 0.81 | 65.97 | 69.62 | 7.62 | 95.50 | 18.35 |
Chronic subdural | 30 | 15 | 15 | 1.00 | 76.81 | 78.36 | 37.39 | 91.70 | 11.80 |
Spontaneous subarachnoid | 18 | 4 | 14 | 0.29 | 61.62 | 60.90 | 25.08 | 88.31 | 15.01 |
Discussion
The methodology employed in the present study for obtaining the cases of intracranial hemorrhage by means of CT scan review allowed for a comprehensive analysis of the phenomenon, in both the traumatic and spontaneous forms. With the exception of the early infancy period in which transfontanelar ultrasonography is many times employed, current practice indicates CT scan as the appropriate examination for diagnosis and follow-up. This approach obviated certain selection bias such as department origin, surgical intervention, or etiologic (either traumatic or spontaneous cases). Studies employing a selection of cases using codes from the International Classification of Diseases (ICD) or Diagnosis Related Groups (DRGs) may tend to analyze only patients that were categorized as inpatients, i.e. remaining more than 24 h in the hospital. They may not be able to measure the phenomenon of patients that suffer minor head injury and have indeed suffered head injury, but do not have lesions in the CT, and are, therefore, discharged from the emergency room. These patients are users of the health system and resources but may not be accounted for in the head injury statistics. In this study, this can be easily found by looking up head injury indication for CT scan and no intracranial hemorrhage in CT scan result. Another potential pitfall of studies using ICD or DRG codes might have to do with transferred patients. A patient admitted for surveillance in a local hospital who later deteriorates and undergoes surgery in a referral institution, and even later gets transferred again to the local institution, might be counted 3 times for epidemiological purposes with the coding methodology.
In the general characterization of the sociological scenario of the population in study, it would be worth mentioning: relatively easy and affordable access to medical care, as well as antihypertensive, antidyslipidemic, and anticoagulant medication; promotion of physical activity and Mediterranean diet, although sedentarism and obesity issues regarded as a growing epidemic; absence of documented peaks of vascular hereditary hemorrhagic pathologies; controlled crime situation and unpermissive use of guns by citizens; mandatory use of helmet by motorcyclists; restrictive speed limit, although concerns regarding its adequate supervision are common; reasonable road quality; and reasonable implementation of measures to prevent work accidents. This should be taken into account in the contextualization of the salient figures of this study that include an incidence rate of intracranial hemorrhage of 134.10/100,000/year; a global incidence rate of head injury of 767.48/100,000/year; incidence rates of hemorrhagic patterns more likely to be associated with a traumatic origin include acute subdural (49.69), contusion (21.55), and epidural (5.09), adding up to a global incidence rate of 76.33/100,000/year; and incidence rates of hemorrhagic patterns more likely to be associated with a spontaneous origin include basal ganglia (18.26), cerebral corticosubcortical spontaneous (17.36), spontaneous subarachnoid (5.39), cerebellar (2.99), and brainstem (1.20), adding up to a global incidence rate of 45.2/100,000/year, inferior to the one of trauma. When viewing the difference between these two figures, it is acknowledged that the categorization between traumatic and spontaneous origins may not be straightforward in selected situations. Head injury is the most frequent complaint motivating brain CT scan (30.11%), and in this context, hemorrhage is present in up to 7.76%. The presence of hemorrhage in 44.87% of post-operative CT scans does not imply a large volume; it includes operated hemorrhages and elective cases and is not synonym with post-operative hematoma requiring surgical evacuation. The “follow-up” category is an unspecific clinical jargon that may harbor diverse situations; given that, this analysis employed the first CT scan of the sequence that patients performed, this category probably includes patients that suffered the original hemorrhagic event before the study period and that may justify the finding of 16.43% of hemorrhage; the number may also represent those patients that were diagnosed in private settings and then transferred to the public facility during the study period. Hemorrhage is present in 11.07% of cases of stupor, and this attests the severe clinical condition that hemorrhage may cause. Acute subdural, contusion, and epidural, classically of traumatic origin, add up to 56.91% of the patterns of hemorrhage found. Although more females undergo brain CT scan (M/F ratio 0.83), and even so in the context of head injury (M/F ratio 0.89), hemorrhage, in general, is more frequently encountered in males (M/F ratio 1.20), including the context of head injury (M/F ratio 1.58), but excluding spontaneous subarachnoid hemorrhage (M/F ratio 0.29) (p < 0.05 Fisher’s exact with mid-P method). It can be hypothesized that males engage in more accident-prone behavior and adhere less to the control of neurovascular risk factors. Basal ganglia hemorrhage and chronic subdural hemorrhage seem to affect older people (mean age superior to 70) (p < 0.05 t-test). In the context of head injury and traumatic brain injury, focused published reviews emphasize the considerable variability that exists on the reported incidence rates due to very different inclusion criteria and effective regional variations, ranging from 7.3 to 811/100,000/year2, with a mean of 262 in Europe3. Male predominance and mean age of occurrence ranging from 27 to 59.67 years have been reported as well2. The concept of traumatic brain injury as “an alteration in brain function or other evidence of brain pathology caused by an external force”4 might encompass the cases here reported as head injury with intracranial hemorrhage (76.33/100,000/year obtained by summing acute subdurals, contusions, and epidurals); on the other hand, the complaint head injury alone would measure a much larger phenomenon that includes the very frequent minor trauma with no consequence (reported in the present study as 767.48/100,000/year). The population of the present study would rank low in the former situation (major trauma) and high in the latter (minor trauma). For intracerebral hemorrhage reported incidence rates per 100,000 person-years ranged from 19.6 to 51.85, and the population of the present study would rank high (39.81/100,000/year obtained by summing basal ganglia, cerebral corticosubcortical spontaneous, cerebellar, and brainstem). Spontaneous subarachnoid hemorrhage ranges from 4.2 to 22.7/100,000 person-years6; the population of the present study would rank low (5.39/100,000 person-years). Screening of vascular lesions with modern non-invasive imaging methods in selected high-risk groups is well established7, and if feasible, treatment before rupture is advocated in this setting, thereby minimizing the risk of hemorrhage. To what extent should these programs be implemented in settings of high incidence of intracranial hemorrhage could deserve further cost-effect analysis. Surveillance of intracranial hemorrhage incidence in large sampling geographical areas, such as performed in the present study, may disclose potential areas of intervention for the improvement of these rates and of the health status of the community.
Conclusion
In the population and in the period in study, traumatic patterns of hemorrhage seem to be slightly more frequent than those of spontaneous nature and head injury the most frequent indication for brain CT scan study. Although within the ranges reported in literature, the incidence rates of hemorrhage that were found rank low for trauma and spontaneous subarachnoid and high for intracerebral. Reinforcement of measures aimed at the prevention of head trauma, control of neurovascular risk factors, and screening for vascular pathology may be in order. This indicator serves to characterize the health status of the community.