key: cord-0062273-tlexv8ow
authors: Savioli, Gabriele; Ceresa, Iride Francesca; Luzzi, Sabino; Giotta Lucifero, Alice; Pioli Di Marco, Maria Serena; Manzoni, Federica; Preda, Lorenzo; Ricevuti, Giovanni; Bressan, Maria Antonietta
title: Mild Head Trauma: Is Antiplatelet Therapy a Risk Factor for Hemorrhagic Complications?
date: 2021-04-07
journal: Medicina (Kaunas)
DOI: 10.3390/medicina57040357
sha: c83d43c49cb3244a4031797b00160167b3381f8a
doc_id: 62273
cord_uid: tlexv8ow

Background and objectives: In patients who receive antiplatelet therapy (APT), the bleeding risk profile after mild head trauma (MHT) still needs clarification. Some studies have demonstrated an association with bleeding risk, whereas others have not. We studied the population of our level II emergency department (ED) trauma center to determine the risk of bleeding in patients receiving APT and whether bleeding results not from antiplatelet agents but rather from age. We assessed the bleeding risk, the incidence of intracranial hemorrhage (ICH) that necessitated hospitalization for observation, the need for cranial neurosurgery, the severity of the patient’s condition at discharge, and the frequency of ED revisits for head trauma in patients receiving APT. Materials and Methods: This retrospective single-center study included 483 patients receiving APT who were in the ED for MHT in 2019. The control group consisted of 1443 patients in the ED with MHT over the same period who were not receiving APT or anticoagulant therapy. Our ED diagnostic therapeutic protocol mandates both triage and the medical examination to identify patients with MHT who are taking any anticoagulant or APT. Results: APT was not significantly associated with bleeding risk (p > 0.05); as a risk factor, age was significantly associated with the risk of bleeding, even after adjustment for therapy. Patients receiving APT had a greater need of surgery (1.2% vs. 0.4%; p < 0.0001) and a higher rate of hospitalization (52.9% vs. 37.4%; p < 0.0001), and their clinical condition was more severe (evaluated according to the exit code value on a one-dimensional quantitative five-point numerical scale) at the time of discharge (p = 0.013). The frequency of ED revisits due to head trauma did not differ between the two groups. Conclusions: The risk of bleeding in patients receiving APT who had MHT was no higher than that in the control group. However, the clinical condition of patients receiving APT, including hospital admission for ICH monitoring and cranial neurosurgical interventions, was more severe.

Minor head injury (MHI), in which affected patients have a Glasgow Coma Scale score of 14 or 15, is among the most common reasons why people go to the emergency department (ED). MHI accounts for approximately 88% of cases of head trauma. Despite the low risk for severe complications, MHI carries a potential risk of a poor outcome [1] . For approximately 95% of patients with MHI, computed tomographic (CT) scans indicate no abnormality, and fewer than 1% are candidates for surgery. An increasing number of investigations are being conducted to identify the risk factors for intracranial hemorrhages [2] [3] [4] [5] [6] [7] [8] [9] [10] .

Although anticoagulant therapy is recognized as a risk factor for bleeding, ongoing use of antiplatelet drugs is still controversial. Reports suggest that people receiving antiplatelet therapy tend to bleed, and whether this represents an independent risk factor for hemorrhagic complications is unclear. The tendency to bleed is more pronounced with age [11] [12] [13] [14] [15] [16] [17] [18] [19] . Since 2015, antiplatelets have increasingly been used as the primary method of preventing cardiovascular diseases [20] [21] [22] [23] .

The goal of our study was to assess the risk of bleeding in patients receiving antiplatelet therapy who visited our ED because of MHI. The secondary endpoints were hospitalization necessary for observation and monitoring intracranial hemorrhage (ICH), the need for cranial neurosurgical interventions for ICH, the severity of patients' condition at discharge, and the rate of ED revisits for late bleeding.

We conducted a retrospective single-center observational study involving all patients admitted to our ED in 2019 because of MHI. The primary endpoint was the diagnosis of post-traumatic ICH during observation and within 30 days. Secondary endpoints were the rate of hospitalization for observation and monitoring of ICH, the rate of ED revisits, the severity of patients' condition at discharge, and the need for cranial neurosurgery during the hospital stay.

The study group involved patients with MHI, with Glasgow Coma Scale scores ≥14, aged >18 years, and receiving antiplatelet therapy (APT). The control group included patients with the same demographic data but who were not receiving APT or anticoagulant therapy and did not report any history of clotting disorders. The exclusion criteria were suspected or diagnosed skull fracture and spontaneous ICH. Of the patients whose records we reviewed, 129 were not eligible.

The terms for our database search were "cranial trauma," "intracranial hemorrhage," and "head trauma." Each patient's data, including clinical reports, medical diary, and laboratory and radiological information, were examined with the use of the PIESSE digital platform.

We collected demographic data and information about the etiology and dynamic of injury, waiting time, process time, length of stay, blood pressure, means of arrival, triage code, exit code, and hematochemical examination results for all enrolled patients. In the triage guidelines of the American College of Surgeons, Sasser et al. described the dynamic criteria for major trauma [24] : ejection from a vehicle, motorcyclist thrown from a vehicle, death in a vehicle, intrusion of an interior compartment of >30 cm, and falling from a height of >2 m (Supplementary Table S1 ). When none of these criteria was present, the dynamics of trauma were considered to be minor.

Hospitalization for observation and monitoring of ICH, cranial surgery, death, and ED revisit within 30 days were documented. We viewed and evaluated all the performance data, and a neuroradiologist reviewed all CT scans. In patients receiving antiplatelet therapy, we reviewed each CT scan that was positive for ICH with regard to topography (intraparenchymal, subdural, epidural, and subarachnoid) and size. We also calculated the score on the Marshall classification of traumatic brain injury. Of the patients whose records we reviewed, 1926 consecutive patients with a diagnosis of MHI were enrolled; 483 were receiving APT and were assigned to the APT group, and the other 1443 were assigned to the control group ( Figure 1 ).

A triage code was assigned according to predefined grids by the triage nurse to the patient. The exit code is a five-point quantitative one-dimensional numerical scale for assessing the severity of the patient according to medical judgment, scale in force in Italy. It was assigned by the emergency doctor to the patient at the time of admission based on clinical judgment. Exit code 1 represents the greatest severity, with 5 being the least.

In accordance with the International Emergency Severity Index and Canadian Triage and Acuity Scale, we used a modified system of triage coding involving five codes; code 1 represented the most severe condition of a patient upon entry into the ED, and code 5 represented the least severe condition (Table 1) [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] [35] [36] [37] . At discharge, according to the clinical judgment of the ED physician, severity codes, called exit codes, that were based on the same scale as the triage codes (Table 1) were assigned to the patients. These were used to measure the severity of the patient's condition at discharge. 

Continuous variables were calculated either as means ± standard deviations or as medians and interquartile ranges, depending on the normality of the distribution; categorical variables were calculated as counts and percentages.

Stata statistical software (Stata Corporation, College Station, TX, USA) was used. We used the t test to compare normally distributed data from the two groups; for other comparisons, we used the nonparametric Wilcoxon test. Associations between categorical variables were checked using Pearson's χ 2 test or Fisher's exact test.

To study the association with the outcome variable (bleeding), we examined the potential covariates in the association between treatment and bleeding with univariable logistic models. After selecting the covariates (predictors for which a significant statistical association with the outcome variable bleeding had been reported), we tested logistic multivariable models with the treatment condition (APT vs. no APT) and each covariate as predictors.

To estimate the average treatment effect of APT versus no APT, we performed propensity score matching using a logistic model. The missing potential outcome for each patient receiving APT was determined from an average of the outcomes of similar patients who received APT, and that for each patient not receiving APT was determined according to similar patients not receiving APT. Similarity between patients was based on estimated treatment probabilities (propensity scores). To compute the treatment effect, we calculated the average of the differences between the observed and potential outcomes for each subject. Statistical significance was determined as p < 0.05, and all the tests were two-sided.

Of the 1926 patients enrolled, 483 patients were receiving APT, and 1443 were not. Table 1 lists demographic and clinical data. Patients receiving APT had slightly lower heart rates, slightly lower oxygen saturation, and higher blood pressure. Scores on the Glasgow Coma Scale were similar in the two groups (p = 0.43). The APT group was, on average, older (approximately 81 vs. 54; p < 0.0001), and the cause of head injury in the group was more often minor (98.53 vs. 93.79%; p < 0.0001). The APT group had a greater number of high priority triage codes before the medical examination (p < 0.0001), shorter waiting times (approximately 46 vs. 72 min; p < 0.0001), and a longer length of stay in the ED (approximately 358 vs. 260 min; p < 0.0001; Table 1 ). Dynamic criteria for major trauma were present in only a small percentage of cases, for both the group on APT (1% (n = 5)) and the control group (4% (n = 58)). The causes of trauma are listed in Supplementary  Table S2 .

Among the APT group, 85% were taking acetylsalicylic acid; 9%, clopidogrel; 5%, ticlopidine; and 1%, indobuphen. APT did not appear to be statistically significant as a risk factor for bleeding, both when tested as the only predictor and after adjustment for age in the multivariable analysis. Age did appear to be a risk factor for bleeding, which was also true in the multivariable analysis, after adjustment for therapy (Tables 2 and 3 ). All the potential covariables in the association between treatment (APT vs. no APT) and the outcome (bleeding) were selected according to logistic regression models, as reported for statistical methodology. Diastolic blood pressure, trauma dynamics, oxygen saturation, and age ≥75 years were associated with bleeding, and these associations remained significant even after adjustment for treatment (APT vs. no APT; Table 4 ). A logistic model with propensity score matching, based on the aforementioned covariables, was used to estimate the average treatment effect of APT versus no APT. As presented in Table 5 , we found no statistically significant difference between the two groups after propensity score matching. Table 6 lists results of the univariable logistic model for the association between treatment (APT vs. no APT) and the outcome variable (bleeding) and the results for treatment after adjustment for each covariable with multivariable models. With regard to secondary outcomes, the APT group had higher severity codes at discharge (p < 0.001), a higher rate of hospitalization (14.9% vs. 10.1%; p = 0.002; Table 1 ), more need of surgery (1.2% vs. 0.4%; p < 0.0001; Table 1 ), and a higher rate of ED revisits within 30 days of the injury for reasons related to head trauma, although this finding was not statistically significant (5.6% vs. 3.5%; p = 0.0608; Table 1 ). The various types of hemorrhage and the Marshall classifications of the patients are listed in Supplementary  Table S3 . Rates of hospital mortality did not differ between the groups.

Our study did not demonstrate that APT was a risk factor for ICH. The findings indicate a higher rate of hospitalization to monitor ICH, a greater need for cranial surgery, and a worse condition at discharge among patients receiving APT.

The two groups analyzed differed mainly in age. It is possible that age also affected the other characteristics in which the two groups differed. Systolic blood pressure was higher in patients receiving APT, presumably because they are at greater cardiovascular risk and are older [38] [39] [40] [41] [42] [43] . In fact, arterial hypertension is very common in patients harboring other cardiovascular risk factors [44, 45] . Moreover, in patients receiving APT, falling was the most frequent mechanism of head trauma. In view of their having been older, falling could probably be related to age, as described in the literature [46] [47] [48] .

The two groups were similarly hemodynamically stable. Glasgow Coma Scale scores were also similar. Inasmuch as MHI is defined on the basis of the Glasgow Coma Scale score, the similarity in scores highlights the comparability of the two groups.

The literature contains much debate as to whether APT predisposes to bleeding in the event of mild head trauma [1, 12, [49] [50] [51] [52] [53] [54] [55] [56] [57] [58] [59] [60] [61] [62] [63] [64] . Our study indicates that APT is not related to a higher risk of bleeding, but it is related to a more severe clinical condition when bleeding does occur. In patients receiving APT, unfavorable conditions related to MHI, particularly the need for neurosurgery and hospitalization, are predictable. Patients receiving APT also need a longer stay in the ED, and longer lengths of stay are correlated with worse outcomes [57, 65, 66] . These patients, therefore, have complex problems, and during triage, it seems appropriate that they are classified as patients at greater risk.

Various results of studies have led to different protocols for adult and pediatric patients with MHI in the emergency room [11] [12] [13] [14] [15] [16] [17] [18] [19] 67] . In some hospitals, all these patients undergo CT examination; in others, CT scanning is performed only if patients meet an age criterion (typically over 65 years) [2] [3] [4] [5] [6] [7] [8] [20] [21] [22] . To our knowledge, however, different durations of observation have not been proposed. Thus, for patients who report MHI and are taking antiaggregation therapy, an observation period of 4-8 h is recommended [68] . Patients who are receiving APT, do not have focal deficits, and have stable lesions can be sent home after proper observation; patients receiving APT should be closely monitored, possibly for 24 h if they have bleeding.

Age remains instead an independent bleeding factor. Previous study results may have been skewed by the age variable. This possibility is supported by other studies [59] [60] [61] [62] [63] [64] 66, 68, 69] . Further studies are necessary to better delineate the risk profile of dual APT in patients with MHI.

This study had all the limitations of a retrospective and single-center study. The bleeding predictors analyzed were those that we deemed reliable in a retrospective study: dynamics of trauma, therapy in progress, Glasgow Coma Scale score, vital signs, sex, and age. We did not consider amnesia because it is not always clearly reported.

The rates of mortality in the two groups were not significantly different; however, we decided not to study it because the low incidence of death in cases of MHI would have necessitated a greater number of patients to be enrolled.

APT is not significantly associated with the rate of ICH in patients with MHI. However, such patients have a greater need for cranial neurosurgical intervention, longer hospitalization, and more frequent ED revisits. 

The authors declare no conflict of interest. 

Indications for Computed Tomography in Patients with Minor Head Injury

Prediction Value of the Canadian CT Head Rule and the New Orleans Criteria for Positive Head CT Scan and Acute Neurosurgical Procedures in Minor Head Trauma: A Multicenter External Validation Study

Clinical Policy: Neuroimaging and Decisionmaking in Adult Mild Traumatic Brain Injury in the Acute Setting

Clinical Performance of NICE Recommendations versus NCWFNS Proposal in Patients with Mild Head Injury

NICE guideline for the management of head injury: An audit demonstrating its impact on a district general hospital, with a cost analysis for England and Wales

Application of the Canadian CT head rules in managing minor head injuries in a UK emergency department: Implications for the implementation of the NICE guidelines

A Critical Comparison of Clinical Decision Instruments for Computed Tomographic Scanning in Mild Closed Traumatic Brain Injury in Adolescents and Adults

The NICE guidelines in the real world: A practical perspective

Indication, Timing, and Surgical Treatment of Spontaneous Intracerebral Hemorrhage: Systematic Review and Proposal of a Management Algorithm

Preinjury warfarin, but not antiplatelet medications, increases mortality in elderly traumatic brain injury patients

Incidence and Predictors of Intracranial Hemorrhage After Minor Head Trauma in Patients Taking Anticoagulant and Antiplatelet Medication

Systematic Review and Meta-Analysis: Is Pre-Injury Antiplatelet Therapy Associated with Traumatic Intracranial Hemorrhage?

Low-dose aspirin prophylaxis and risk of intracranial hemorrhage in patients older than 60 years of age with mild or moderate head injury: A prospective study

A retrospective review of patients with head injury with coexistent anticoagulant and antiplatelet use admitted from a UK emergency department

A meta-analysis to determine the effect of preinjury antiplatelet agents on mortality in patients with blunt head trauma

Clinical outcomes in traumatic brain injury patients on preinjury clopidogrel

The effects of preinjury clopidogrel use on older trauma patients with head injuries

Predictors of Mortality in Trauma Patients With Intracranial Hemorrhage on Preinjury Aspirin or Clopidogrel

Expert consensus document on the use of antiplatelet agents. The task force on the use of antiplatelet agents in patients with atherosclerotic cardiovascular disease of the European society of cardiology

AHA/ACC Guidelines for Preventing Heart Attack and Death in Patients with Atherosclerotic Cardiovascular Disease

Rates of Intracranial Hemorrhage in Mild Head Trauma Patients Presenting to Emergency Department and Their Management: A Comparison of Direct Oral Anticoagulant Drugs with Vitamin K Antagonists

Guidelines for field triage of injured patients: Recommendations of the National Expert Panel on Field Triage

Triage in Medicine, Part I: Concept, History, and Types

Impacts of the introduction of a triage system in Japan: A time series study

Optimizing triage consistency in Australian emergency departments: The Emergency Triage Education Kit

Emergency department triage revisited

Revisions to the Canadian Emergency Department Triage and Acuity Scale (CTAS) Guidelines

Reliability and Validity of a New Five-level Triage Instrument

Modern Triage in the Emergency Department

Impact of Coronavirus Disease 2019 Pandemic on Crowding:A Call to Action for Effective Solutions to Access Block

Reliability of Canadian Emergency Department Triage and Acuity Scale (CTAS) in Saudi Arabia

Analysis of three advanced practice roles in emergency nursing

A review of the quality assurance processes for the Australasian Triage Scale (ATS) and implications for future practice

The urgency distribution of an accident and emergency department's workload

Regioni e le Province Autonome sul Documento di Linee-Guida sul Sistema di Emergenza Sanitaria Concernente: Triage Intraospedaliero (Valutazione Gravità All'Ingresso) e Chirurgia Della Mano e Microchirurgia nel Sistema Dell'Emergenza-Urgenza Sanitaria

Arterial hypertension in the elderly

Hypertension in the elderly

Change in left ventricular geometry over 10 years in the elderly and risk of incident cardiovascular disease

Progression of conventional cardiovascular risk factors and vascular disease risk in individuals: Insights from the PROG-IMT consortium

Differences in Cardiovascular Aging in Men and Women

Obesity, diabetes, and risk of cardiovascular disease in the elderly

International Prevalence, Recognition, and Treatment of Cardiovascular Risk Factors in Outpatients with Atherothrombosis

ESC/ESH Guidelines for the management of arterial hypertension

Fall Risk Assessment Predicts Fall-Related Injury, Hip Fracture, and Head Injury in Older Adults

Head Trauma in Elderly Patients: Mechanisms of Injuries and CT Findings

Geriatric trauma

Predictive factors of intracranial bleeding in head trauma patients receiving antiplatelet therapy admitted to an emergency department

Risk of Intracranial Hemorrhage in Ground-level Fall with Antiplatelet or Anticoagulant Agents

Do EMS Providers Accurately Ascertain Anticoagulant and Antiplatelet Use in Older Adults with Head Trauma? Prehospital Emerg

Risk of traumatic intracranial hemorrhage in patients with head injury and preinjury warfarin or clopidogrel use

Clinical Factors and Perioperative Strategies Associated with Outcome in Preinjury Antiplatelet and Anticoagulation Therapy for Patients with Traumatic Brain Injuries

Effect of preoperative antiplatelet or anticoagulation therapy on hemorrhagic complications in patients with traumatic brain injury undergoing craniotomy or craniectomy

Traumatic Minor Intracranial Hemorrhage: Management by Non-neurosurgeon Consultants in a

Management of Prehospital Antiplatelet and Anticoagulant Therapy in Traumatic Head Injury: A Review

Impact of ED Organization with a Holding Area and a Dedicated Team on the Adherence to International Guidelines for Patients with Acute Pulmonary Embolism: Experience of an Emergency Department Organized in Areas of Intensity of Care

Intraventricular Hemorrhage After Head Injury: A Multicenter, Retrospective, Cohort Study

Chronic Subdural Hematoma in the Elderly

Surgical Trial in Traumatic intraCerebral Haemorrhage (STITCH): A randomised controlled trial of Early Surgery compared with Initial Conservative Treatment

Outcomes of Subdural Hematoma in the Elderly with a History of Minor or No Previous Trauma

Current diagnosis and treatment of chronic subdural haematomas

Traumatic Brain Injury Profile of an Elderly Population in Puerto Rico. Puerto Rico Health Sci

Chronic subdural haematoma in the elderly

Role of a Brief Intensive Observation Area with a Dedicated Team of Doctors in the Management of Acute Heart Failure Patients: A Retrospective Observational Study

Preparing for the Maximum Emergency with a Simulation: A Table-Top Test to Evaluate Bed Surge Capacity and Staff Compliance with Training

Early Decompressive Craniectomy as Management for Severe TBI in the Pediatric Population: A Comprehensive Literature Review. World Neurosurg

Head injury: Triage, assessment, investigation and early management of head injury in children, young people and adults (NICE guideline CG 176)

Major trauma in elderly patients: Worse mortality and outcomes in an Italian Trauma Center