Dabla, Puri, Dash, Vasantha, and Tripathi: Predictors of Seizure-Related Injuries in an Epilepsy Cohort from North India

Abstract

Background and Purpose

To identify predictors of seizure-related injury (SRI) and death in people with epilepsy (PWE) in a North Indian cohort.

Methods

This ambispective cohort study included PWE registered in an epilepsy clinic in Delhi between May 2010 and December 2011. Five hundred twenty-six patients were enrolled and followed for 25 months. Patients were categorized into two groups based on SRI/no SRI during the study period. We analyzed various factors to identify predictors of SRI and death.

Results

Of 526 patients, 355 (67.5%) reported having no SRIs and 171 (32.5%) had sustained an SRI. Among patients with SRI, 72.5% were male; 62% of those with no SRI were male. The injury type included soft tissue (60%), head trauma (20%), dental trauma (10%), orthopedic (10%), and burns (5%). On univariate analysis, factors predicting SRI occurrence were male gender, abnormal birth history (p < 0.01), abnormal mental status (p < 0.01), seizure duration (p < 0.04), daytime seizures (p < 0.05), dependence on a caregiver (p < 0.008), and uncontrolled seizures (p < 0.001), history of cluster seizures or status epilepticus (p < 0.001), occurrence of generalized tonic-clonic seizures (GTCS), and use of >3 antiepileptic drugs (p < 0.008). On multiple logistic regression analysis, male gender, uncontrolled seizures, history of cluster seizures or status epilepticus, and GTCS were significant risk factors. Sixteen deaths occurred in our cohort, and 13 fit the definition of probable sudden unexpected death in epilepsy (SUDEP). Most patients with SUDEP had an unwitnessed event (69.2%). The only significant factor in predicting death was uncontrolled seizures.

Conclusions

Male gender, occurrence of GTCS, uncontrolled seizures, and history of cluster seizures or status epilepticus predicted SRI occurrence in PWE. Precautions should be taken by caregivers of patients with these risk factors, to prevent injury.

Introduction

According to the World Health Organization, epilepsy accounted for about 0.5% of the global burden of disease in 2005, or more than 7 million disability-adjusted life-years. Intense clinical research is ongoing to explore various aspects of the risks related to epilepsy. Mortality figures in people with epilepsy (PWE) are about two to three times greater than those in the general population. Most causes of death can be attributed to underlying neurological disease, but some are epilepsy related, including accidents, drowning, status epilepticus, and sudden unexpected death in epilepsy (SUDEP). In a recent publication form Kolkata, a eastern city of India, an annual mortality rate of 7.6 per 100,000 per year and a standardized mortality ratio of 2.58 was reported for epilepsy in a 5-year follow-up of general population.1 Among the neurological causes, epilepsy was the second leading cause of death after stroke. There is a dearth of literature from India regarding deaths in PWE and the potential risk factors.
Another important domain in PWE is the risk of seizure-related injury (SRI). Features such as seizure-like impairment of consciousness and loss of motor control lead to a substantially increased risk of injury during ictus. PWE often have other comorbid conditions such as learning disabilities, and somatic and psychiatric conditions that place them at increased risk for accidental injury. Because of the increased risk of injury, PWE are subject to employment, recreational, and driving restrictions. These limitations have personal and social consequences, leading to inactivity, isolation, and dependency. Risk of injuries due to epilepsy is an important predictor of quality of life as it has a significant impact on an individual’s social life, education, and employment status. Limitations in all these spheres of life may lead to a loss of independence, impaired social development, and increased psychiatric comorbidities.
We examined the rates and types of SRI based on self-reported questionnaires, and we also assessed the risk factors for SRI in a pre-registered cohort of PWE attending an epilepsy clinic of a tertiary teaching hospital in Northern India. We also recorded deaths in the cohort and sought to find potential risk factors.

Methods

A total of 536 consecutive preregistered PWE were identified using a case survey in Delhi and the National Capital Region. PWE attending the epilepsy clinic of the Department of Neurology at the All India Institute of Medical Sciences in New Delhi, during the period from May 2010 to December 2011, were included in this ambispective cohort study. Inclusion criteria for the study were patients with active epilepsy of more than 1-year duration (the International League Against Epilepsy definition of active epilepsy is “at least one epileptic seizure in the previous 5 years, regardless of antiepileptic drug treatment”), and ability to read Hindi and give their informed consent to participate in the study. The purpose of the study was explained and informed consent was obtained from the patients or their caregivers. Structured questionnaires included demographic details such as age, gender, occupation, socioeconomic status, and personal habits along with birth and developmental history and mental status. Questionnaires were administered by a trained neurologist for all patients in either a personal or a telephone interview. Various factors were recorded, such as the age at onset of epilepsy, duration of disease, type and frequency of seizures, any premonition or aura, timing of seizures (nocturnal or daytime), control of epilepsy (controlled epilepsy is defined as either no seizure or less than 10 seizures per year and more than 10 seizures per year is defined as uncontrolled epilepsy), treatment details, and the probable etiology of epilepsy.
Patients were asked whether they had sustained any injury/injuries during a seizure in last 12 months. Injuries were classified as direct injury, such as orolingual trauma or tongue bite (due to the motor phenomenon of seizure) and indirect injuries such as consequence of a fall during a seizure (e.g., fracture or dislocation), burns, lacerations, soft tissue injuries, and dental injuries (needing medical attention). Participants were specifically asked about injuries like tongue bite, dental injuries, soft tissue injuries, head trauma, burns, orthopedic injuries, or seizures in water/drowning. Medical or surgical intervention received for the same were recorded. Documents pertaining to hospitalization and medical advice related to these injuries were also verified. The included participants were divided two groups: group 1 (patients who never sustained any SRIs) and group 2 (patients who had sustained an SRI).
Every 3 months, phone calls were made to inquire about the well-being of the participants. If a participant had died, details regarding the circumstances of their death were collected. The medical records of PWE who had died were also evaluated to collect details regarding the possible cause of death.

Statistical analysis

Data were presented as number (%) or median (range), as appropriate. Continuous demographic and clinical variables of patients with and without SRI were analyzed using a Wilcoxon rank-sum test, and categorical variables were compared using chi-squared or Fischer’s tests. To determine the factors associated with injury and death among PWE, logistic regression analysis was carried out. The results were presented as odds ratio (OR) with 95% confidence intervals (CIs). Adjusted ORs were obtained and considered significant if the CI did not exceed 1. A p-value of < 0.05 was considered significant. Statistical analysis was carried out using STATA 9.0 (StataCorp LLC, College Station, TX, USA).

Results

A total of 526 patients with active epilepsy were enrolled in the study. Overall, 355 patients (67.5%) had no SRIs whereas 171 patients (32.5%) had sustained an SRI during the past 12 months. The demographic and clinical characteristics of both groups are tabulated in Table 1. There were significant differences between the two groups (SRI and no SRI) for the following parameters: gender, birth history, and mental status (p = 0.01); seizures occurring while awake (p = 0.05), independence in daily activities (p = 0.007), uncontrolled seizures (p = 0.001), and use of more than two types of antiepileptic drugs (p = 0.008). No significant difference was found between employed and unemployed participants and among those with differing socioeconomic status (p = 0.626 and 0.703, respectively).
Primary generalized tonic-clonicseizures (GTCS) occurred in 158 (30%) patients, dyscognitive seizures in 100 (19%), secondary generalization in 208 (39.4%), focal non dyscognitive seizures in 21 (3.9%), and myoclonic seizures in 39 (7.4%) patients. In all, 129 patients were taking a single antiepileptic drug, 175 patients took two antiepileptic drugs, and 254 patients took three or more antiepileptic drugs. In addition to antiepileptic drugs, 32 patients (6%) had undergone epilepsy surgery.
The most common etiologies based on radiologic parameters were hippocampal sclerosis (56 patients); central nervous system infection (46 patients), of which 26 were neurocysticercosis; cortical dysplasia (13); developmental brain tumor (11); stroke-related causes (2), and other conditions (54). The latter included arteriovenous malformation, brainatrophy, hematoma, hypoxic brain damage, tuberous sclerosis, neuronal migration syndrome, and posttraumatic events.

Types of injuries

Soft tissue injury was the commonest type of SRI (60%), with involvement of the face, lips, scalp, chin, arms, thigh, back, and buttocks. Suturing was required in only four patients. The second most common type of injury was tongue bite (52%) followed by head trauma (20%), which included concussion and head laceration. Two of our patients were hospitalized and hematoma evacuation was performed; one patient recovered completely and the other had residual weakness. Dental trauma occurred in 10% patients. Eight patients reported burns (5%) that involved the face, foot, and whole body; in all these patients, burns occurred while cooking. One patient with whole-body burns was admitted to the hospital. Seventeen patients reported orthopedic injuries (10%), three of these patients were treated with a plaster cast and patellectomy was performed in one patient.

Activity during which injuries occurred

The activity documented at the time of seizure were doing housework (43%), working (24%), sleeping (12%), playing in school (11%), traveling (5%), and other (5%).

Risk factors for SRI

After univariate analysis of potential risk factors for SRI, male gender (p = 0.01), abnormal birth history (p = 0.01), abnormal mental status (p = 0.01), duration of epilepsy (p = 0.04), seizures occurring during the day (p = 0.05), dependence on a caregiver for carrying out activities (p < 0.008), uncontrolled seizures (p = 0.001), history of cluster seizures or status epilepticus (p = 0.001), and use of more than three types of antiepileptic drugs (p = 0.008) were found to be significant (Table 1). On multiple logistic regression analysis (Table 2), uncontrolled seizures (OR 1.74, 95% CI 1.11–2.72), history of cluster seizures or status epilepticus (OR 1.74, 95% CI 1.11–2.72), and occurrence of GTCS (primary or secondary) were found to be significant risk factors.

Deaths and risk factors for death

A total of 16 deaths were recorded in our cohort. In three patients, death was due to accident: two fell from the roof, presumably due to a seizure, and one drowned. Thirteen of these individuals died during a seizure, but none had status epilepticus. Of these 13 participants, four (30.7%) had seizures while sleeping and died 15–30 minutes after a generalized seizure. The other nine (69.2%) participants had presumed, but unwitnessed seizures; however, these were not in accident settings. There was a male predominance, with 10 out of 16 patients being male. On univariate analysis of potential risk factors for death, the only factor found to have statistical significance was uncontrolled seizures (p = 0.03).

Discussion

We conducted an ambispective cohort study of 526 preregistered PWE from a tertiary teaching hospital in North India. Overall, 33% of respondents reported having sustained some form of SRI in their lifetime. Of these, only 5% required hospitalization for their injuries.
In a large prospective study by Beghi and Cornaggia2 of 951 patentsassessing the risk of accidents in PWE, 24% had SRIs. In a questionnaire-based study by Sapna et al.3 from Southern India, 44.8% of respondents reported at least one injury in the previous 12 months. This proportion is much higher than the proportion in our series, which may be because those authors studied the frequency of both seizure-related and unrelated injuries in PWE.
The proportion of PWE who sustain SRI varies depending upon the study design and method of obtaining the figures. In a recent self-reported survey of 343 PWE from Australia, 55% of respondents reported to have SRI. In a retrospective population-based study of 247 PWE, followed up for 2,714 person-years conducted by Lawn et al.,4 16% of patients experienced at least one SRI. The most common type of injury in our study was soft tissue injuries (60%). Many previous studies have also shown soft tissue injuries to be the most common type of injury among PWE. The risk of soft tissue injury has been reported to be as high as 74% in previous studies of adults and children.5
PWEs have a high risk for fractures. Fractures result from the interplay between accidental trauma, loss of protective reflexes during seizure and seizure-related falls, and associated osteoporosis due to long-term use of antiepileptic drugs. In a meta-analysis of the literature on fracture risk in epilepsy, it was found that PWE are twice as likely to sustain fracture as the general population.6 In our study, 10% of patients had dislocations and fractures of different bones.
In a population-based study of PWE by Téllez-Zenteno et al.,7 a higher frequency of burns than that in the general population was reported. About 5% of participants in our study reported burns, all occurring while doing household work. This is lower than the rates reported in surveys conducted by Spitz et al.8 and Buck et al.9 The possible reason for the lower percentages of burns in our study could be due to differences in sociocultural practices in India. Joint families are the norm in Indian culture and PWE usually do not actively participate in cooking or other household chores that could expose them to a risk of burns.
Many factors have been implicated in increasing the risk of SRI. Of all the factors, type of seizure has the highest correlation with risk of SRI. In a retrospective population-based study by Lawn et al.,4 univariate analyses identified five potential risk factors for SRI: greater number of antiepileptic drugs used, less independent living situation, higher Rankin score, history of generalized convulsive seizures or drop attacks, and higher seizure frequency score. Seizure frequency, however, was the only significant risk factor identified by multivariate analysis (p < 0.001; relative risk, 1.3). In agreement with their study, male gender, uncontrolled seizures, a history of cluster seizures or status epilepticus, and presence of GTCS were found to be significant risk factors in our series. In a questionnaire-based study of 300 patients from Thailand, the potential risk factors identified were occurrence of GTCS, seizures at least 12 times per year, and daytime seizures.10 In contrast to this, we found no significant correlation with the time of seizure and risk of SRI.
In a retrospective case-controlled cohort study using data from Danish registries, Holst et al.11 reported that having epilepsy increased the crude risk of death, with a hazard ratio of 11.9 (95% CI 11.0–12.9). The findings of a community-based study from India among 37,844 inhabitants, including 173 PWE, suggested a higher risk of death in PWE than in the general population.
In our cohort of 526 PWE, 16 were reported to have died during seizures. Thirteen patients died unexpectedly and suddenly, without any evidence of status epilepticus or trauma; however, autopsy was not performed in any of these patients, which was mostly due to religious beliefs of the family members. These PWE fulfilled the criteria for probable SUDEP. One of the limitations of our study was that there was no control arm for comparison. Hesdorffer et al.12 analyzed pooled data from four case-control studies of risk factors for SUDEP, including 289 cases and 958 controls. Their findings indicated that people who have early-onset refractory symptomatic epilepsy with frequent GTCS and antiepileptic drug polytherapy are at higher risk of SUDEP. Our study found uncontrolled seizures to be the only factor associated with an increased risk of death.
Lamberts et al.13 reported that most of the SUDEP events were unwitnessed (86%), and many were during sleep (58%). In those with SUDEP, the seizure patterns were nocturnal in 36% and diurnal in 32% of individuals in that study. Showing a similar trend, 69.2% of our cases were unwitnessed and 30.7% were sleep related. Because of the sociocultural milieu in a country like India, discussing death is a taboo. Prospective case-controlled studies examining the potential risk factors for SUDEP would shed more light on this important aspect of epilepsy.
The limitations of our study include the lack of a control arm. There is a possibility of significant recall bias as the data were collected by administering a questionnaire to participant and not using medical records, thus decreasing the reliability of the information and with possible underreporting of mild SRIs. In addition, the study population was a hospital-based cohort of PWE; therefore, our results cannot be generalized to the general population.
In the present study, we found that male gender, occurrence of GTCS, uncontrolled seizures, and a history of cluster seizures or status epilepticus predicted the occurrence of injury in PWE. We found that uncontrolled seizures was the risk factor that could predict SUDEP. Precautions should be taken by caregivers of patients with these risk factors, to prevent injury.

Table 1
Distribution of cases, according to demographic data
Group 1 (no injury) (n = 355, 67.5%) Group 2 (injury group) (n = 171, 32.5%) p-value
Gender
 Male 220 (62) 124 (72.5) 0.01
 Female 135 (38) 47 (27.5)
Birth history
 Normal 346 (97.4) 159 (93) 0.01
 Abnormal 9 (2.6) 12 (7)
Mental status
 Normal 319 (90) 140 (82) 0.01
 Abnormal 36 (10) 31 (20)
Occupation
 None/household work 102 (28.7) 56 (32.7)
 Laborer/high risk 110 (31) 63 (36.8) 0.324
 Desk job 133 (37.5) 50 (29.2)
Socioeconomic status (modified Kuppuswamy scale)
 Upper 51 (14.4) 5 (2.9)
 Upper middle 35 (9.9) 26 (15.2) 0.12
 Lower middle 52 (14.6) 32 (18.7)
 Upper lower 104 (29.3) 34 (19.9)
 Lower 113 (31.9) 74 (43.3)
Care
 Self-care 328 (92) 145 (85) 0.007
 Caregiver 27 (8) 26 (15)
Seizure control
 Controlled 179 (50) 58 (34) 0.001
 Uncontrolled 176 (50) 113 (64)
Timing of seizure
 Day 323 (90) 146 (85.4) 0.05
 Night 32 (10) 25 (14.6)
Sensorium
 Normal 162 (45.6) 71 (42) 0.374
 Altered 193 (54.4) 100 (58)
Treatment compliance
 Good 341 (96) 159 (93) 0.128
 Poor 14 (4) 12 (7)
No. of antiepileptic drugs
 1 90 (25.34) 39 (22.8) 0.008
 2 131 (36.9) 44 (25.8)
 3 or more 134 (37.75) 88 (51.4)

Values are presented as number (%).

Table 2
Risk factors for injury by multiple logistic regression analysis
OR (95% CI) OR (95% CI)


Unadjusted p-value Adjusted p-value
Gender
 Male 1
 Female 0.62 (0.41, 0.93) 0.018 0.60 (0.40, 0.92) 0.01
Birth history
 Normal 1
 Abnormal 2.9 (1.12, 7.03) 0.018 1.80 (0.56, 5.40) 0.298
Mental status
 Normal 1
 Abnormal 1.97 (1.17, 3.21) 0.01 0.89 (0.36, 2.24) 0.799
Occupation
 Nil/household work 1
 Laborer/high risk 0.79 (0.45, 1.40) 0.80
 Desk job 1.15 (0.63, 2.08) 0.42
Care
 Self 1
 Caregiver 2.18 (1.23, 3.86) 0.008 1.5 (0.56, 4.08) 0.425
No. of seizures (years)
 Nil 1
 <10 1.56 (0.65, 3.77) 0.323
 10–20 1.86 (0.74, 4.39) 0.199
 >20 4.14 (1.72, 9.11) 0.002
Cluster/status epilepticus
 Nil 1
 Cluster/SE 2.79 (1.64, 4.76) 0.001 2.0 (1.12, 3.68) 0.01
 Duration of seizures 1.01 (0.99, 1.0) 0.154
Control of seizure
 Controlled 1
 Uncontrolled 2.0 (1.4, 2.9) 0.001 1.74 (1.11, 2.72) 0.01
Timing of seizures
 Day 1
 Nocturnal 1.7 (1.0, 3.0) 0.06
Sensorium during seizures
 Day 1
 Nocturnal 1.19 (0.82, 1.7) 0.374
No. of antiepileptic drugs
 1 1
 2 0.8 (0.5, 1.3) 0.375 0.7 (0.4, 1.2) 0.09
 3 or more 1.5 (0.96, 2.45) 0.08 0.94 (0.60, 1.62) 0.81
Compliance to treatment
 Compliant 1
 Noncompliant 1.84 (0.83, 4.07) 0.133
Type of seizures
 Generalized (primary & secondary) 1
 Focal seizures 0.19 (0.05–0.63) 0.01 0.16 (0.05, 0.61) 0.02
Type of seizures
 Primary GTCS 1 0.02
 Dyscognitive seizures 0.45 (0.26, 0.79) 0.005 0.49 (0.27, 0.87) 0.991
 Myoclonic seizures 0.80 (0.39, 1.16) 0.550 0.91 (0.46, 12.16)
 Focal seizures with secondary generalization 0.65 (0.43, 1.0) 0.05 0.60 (0.39, 0.97) 0.04
 Simple focal seizures –Non-dyscognitive 0.24 (0.068, 0.85) 0.02 0.23 (0.06, 0.84) 0.03

p-value < 0.05 is significant.

OR, odds ratio; CI, confidence interval; SE, status epilepticus; GTCS, generalized tonic-clonic seizures.

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