Basic Epidemiological Terms

There are some basic terms that are essential to the understanding of the science of epidemiology, a few of which are listed here.

• Association—When two or more attributes are related to each other in such a way that they change predictably together.

• Bias—Anything that causes the conclusions of a study to be systematically different from the truth. Bias may occur in the way data are collected, analyzed, and/or interpreted.

• Case—A person in an epidemiological study who has the disease or condition under investigation. These persons are members of the cases group in a case-control study.

• Case-control study—A type of epidemiological study in which participants are separated into two groups: members of one group have the disease or condition under study (the cases), and those in the other group do not (the controls). The groups are assessed concerning previous exposure to various factors or the presence of certain traits, and then rates of exposure/traits are compared between cases and controls.

• Cause—Refers to a factor that has a direct effect on the occurrence of a disease or condition. The factor could be an intrinsic trait or a behavior of the persons being studied or some event they were exposed to.

• Cohort—A distinct group of people who have something in common, such as being exposed to a common risk factor or being born in the same year.

• Cohort study—A type of epidemiological study that follows one or more cohorts forward in time to determine the incidence of new diseases, conditions, and/or deaths that occur. Typically, one cohort is exposed to a risk factor, while the comparison cohort is not. The rates of the measured outcomes are then compared between the groups to see if members of the exposed cohort are more likely to develop the disease or condition.

• Exposure—An external factor that may have an impact on the health of a person if the person is exposed to that factor.

• Incidence—The number of newly diagnosed cases of a disease within a specified population during a specified time period, which is typically 1 year. The denominator is the population under consideration and the numerator is the number of new cases that develop during the given time period. The incidence rate may be calculated by dividing the number of new cases of a disease in a given time period by the number of persons in the population who are at risk for the disease.

• Odds ratio (OR)—An estimate of the odds of developing a disease given that a person was exposed to a relevant risk factor. It is the odds of being exposed to the risk factor under investigation in the cases divided by the odds of being exposed in the control group, which is calculated from data in case-control studies.

• Prevalence—The number of persons in a population who have a given disease or attribute at a particular point in time (point prevalence) or over a specified period of time (period prevalence). The prevalence rate is calculated by dividing the total number of cases of a disease within a population by the total population.

• Relative risk (RR)—The probability of disease being present in the exposed group, divided by the probability of disease in the unexposed group, which is commonly calculated in cohort studies.

• Risk—The likelihood that a person will experience a given event (e.g., become injured).

• Risk factor—A behavior, environmental exposure, or inherent characteristic of an individual that increases the likelihood of that individual’s developing a disease or condition.

Frequency of Whiplash

Incidence

The incidence of whiplash refers to the number of new cases that are diagnosed each year in a given population. Due to the previously mentioned problems with collecting whiplash-related data, estimates of whiplash incidence vary greatly, ranging from 3.4 per 100,000 ⁶ to 800 per 100,000⁷ population per year. A Swedish study reported the annual incidence of whiplash in the local catchment area to be 4.2 per 1,000 inhabitants for grade 1 WAD and 3.2 per 1,000 for grade 3.⁸ Holm et al⁹ reported that the incidence of reported WAD in the Western world is probably at least 300 per 100,000 inhabitants per year. A commonly quoted statistic that refers to the rate of whiplash in the United States is 1,000,000 total cases per year.¹⁰

The Insurance Institute for Highway Safety (IIHS) reported that approximately 2 million whiplash insurance claims are filed each year in the United States, resulting in more than $8.5 billion in insurance claims.¹¹ In fact, neck sprains and strains are the most frequent type of injury claim reported to insurance companies in the United States, comprising 25% of all injury-related claim dollars paid out by insurers each year. The institute also reported that about 10% of whiplash injuries result in long-term medical problems. In the Canadian province of Saskatchewan, 83% of traffic injury claims were for whiplash in 1994-1995, resulting in an annual incidence of 677 insurance claims per 100,000 adult population.¹²

In addition to the cases that were included in the IIHS data, there are likely other cases of whiplash that occur but do not give rise to an insurance claim. This is because injured persons may not choose to open a claim (perhaps they do not want their insurance rates raised or they think their injuries are minor) or they are not insured. Thus, the true number of cases per year in the United States is almost certainly higher than 2,000,000, especially when non–traffic related whiplash injuries are factored in.

There are quite a few reasons why the various data sources so often generate different numbers. For instance, the National Accident Sampling System (NASS) provides data on all types of MVCs, including those that result in whiplash injuries. NASS data are collected from police-reported traffic crashes,¹³ which is very problematic when trying to obtain an estimate of the actual number of whiplash injuries that occur in the United States. Many MVCs that give rise to whiplash injuries are not reported to police because they do not typically investigate crashes that involve minor vehicle damage, and many whiplash-causing crashes are associated with minor to no vehicle damage. These injured persons “slip through the cracks” and are not included in the NASS database, and this results in an underestimation of the annual number of injuries by possibly hundreds of thousands. Even when police do investigate MVCs that result in whiplash, sometimes symptoms are delayed for hours and days; consequently, these cases are also unreported.

Prevalence

The prevalence of WAD includes the previously mentioned incident cases (i.e., newly injured), but it also includes the total number of people who have persistent symptoms and physical impairments that are not included when only incident cases are counted. It represents the estimated number of persons in a population who manifest WAD symptoms at any given time. Many people experience residual problems for years after a whiplash injury and some never recover. These cases keep mounting in numbers until some of them recover or die. In either case, they are no longer included in calculation of prevalence.

The duration of a disease has an effect on its reported incidence and prevalence. For instance, short-duration diseases like the common cold tend to have a high annual incidence but low prevalence. Because people recover so quickly, not many will have the condition at any one point in time. On the other hand, long-duration diseases like diabetes may have a relatively low annual incidence, yet its prevalence is quite high because the total number of cases keeps accumulating. This principle applies to WAD too, because many affected people experience long-term symptoms. A study from the Netherlands reported that the highest prevalence of MVC-related neck sprain was 28.3 per 100,000 and occurred in those who were in the 25- to 29-year-old age group, with the 40- to 44-year-old group a close second at 27.9 per 100,000.⁶ As mentioned earlier, the incidence of WAD in the United States is probably into the millions, and approximately half of those with WAD continue to report neck pain 1 year after their injuries,¹⁴ so its prevalence is undoubtedly very high. In fact, Freeman et al¹⁵ estimated, from a case-control study comprised of 419 chronic neck pain cases and 246 chronic low back pain controls, that about 6.2% of the U.S. population may have chronic neck pain attributable to a whiplash injury.

Chronicity

There is a great deal of controversy and debate surrounding the determination of which risk factors actually contribute to chronic WAD (aka, late whiplash syndrome) and which ones are merely associated by chance. Furthermore, some even question the legitimacy of chronic WAD, considering it to be a psychosocial phenomenon rather than being physically based.¹⁶ As a result of this dichotomy, there has been much debate about this issue in the whiplash-related literature. As stated so well by Dr. Murray Allen, “There are two great puzzles in this world that foster debate among humans. One is the wonder of the universe, the other is whiplash.”¹⁷

A large proportion of persons with chronic neck pain in the United States were initially injured in an MVC. This estimate was based on a case-control study involving 419 cases and 246 control subjects which reported that 45% of those with chronic neck pain considered its origin to have been a prior MVC.¹⁵ On the other hand, a study that was based on a random sample of 6,000 subjects from two counties in Northern Sweden reported that 42% had chronic neck pain and only about 8% of them attributed their condition to a previous whiplash injury.¹⁸

Most WAD patients recover in time, although many have long-lasting and even permanent pain and impairment. For instance, a cohort of 2,627 persons with whiplash that resulted from an MVC in Canada was followed for up to 7 years.¹⁹ The median time to recovery for the overall group was 32 days, although 12% of the subjects still had symptoms at 6 months. Several risk factors for chronic symptoms were identified in this study, including neck pain on palpation, muscle pain, pain or numbness radiating from the neck to the upper extremities, and headache. Females over 60 years old who had the identified risk factors required a median of 262 days to recover compared with only 17 days for younger males without any risk factors.

Several studies have reported that approximately 50% of WAD patients continue to complain of symptoms 1 year following injury.²⁰^–²² Other studies, however, have found the rate of long-term WAD symptoms to be lower,^8,²³^–²⁵ and some have reported it as being much lower.²⁶^–²⁸ To complicate the issue further, one study found the prevalence of long-term pain following whiplash injuries to be very close to the same level as the prevalence of chronic neck pain in the general population.²⁹

Neck and shoulder pain are commonly reported symptoms of chronic WAD. Symptoms involving other bodily regions and overall health have been reported as well, including headache, back pain, jaw pain, fatigue, dizziness, paraesthesiae, nausea, sleep disturbances, and ill health.^30,³¹ Depression has also been reported following whiplash injuries. In one study, 42.3% of 5,211 subjects who did not have pre-injury mental health problems reported depressive symptoms within 6 weeks of the injury.³² Furthermore, the symptoms were recurrent or persistent in almost 40% of the cases. Berglund et al³⁰ concluded that whiplash injuries due to rear-impact MVCs have a substantial impact on health complaints, even a long time after the injury.

A systematic review and meta-analysis involving 38 cohort studies that followed subjects with acute whiplash reported that recovery rates were extremely variable across studies.³³ Most subjects recovered within 3 months after the injury, and recovery rates leveled off after 3 months had elapsed. The review’s authors suggested that data concerning prognostic factors thought to be associated with a poor recovery were difficult to interpret because of the dissimilar ways studies assessed associations, differences in their methods of reporting data, as well as differences in the outcome measures that were used.

Whiplash Risk Factors

Risk Factors for Developing WAD

Numerous studies have assessed the influence of a variety of risk factors on the probability of developing WAD subsequent to an MVC. Example risk factors include position of the occupant within the vehicle, head position (e.g., rotated), female gender, head-to-neck ratio, prior neck injury, use of safety belts, and crash severity. The results of these studies have been conflicting for the most part, but a few WAD risk factors have emerged as being important.

The underlying mechanism of whiplash is best explained by distortion of the neck that results from sudden movement of the head in relation to the torso. Thus, automobile head restraints and reactive seat backs are designed to minimize the difference between the rates of acceleration of the head compared with the torso. If there is very little or no movement of the head relative to the torso, the neck will probably not be injured, even in severe crashes that result in a lot of vehicle damage. In fact, studies have reported that the incidence of whiplash is surprisingly low in high-energy crashes, as well as in crashes where occupants sustain multiple traumas.^34,³⁵

A recent systematic review ⁹ that included studies pertaining to the determinants of developing WAD following MVC found several relevant factors, including the occupant’s seat position (i.e., being a front-seat versus a rear-seat passenger) and the direction of collision impact. The authors found preliminary evidence suggesting that head restraints and/or car seats that limit head extension have a preventive effect on reporting WAD, although this relationship was mainly evident in females. Being a younger person and/or female seemed to be associated with filing claims or seeking care for WAD, although the evidence was not consistent. Preliminary evidence presented in one of the studies included in the review reported that the elimination of insurance payments for pain and suffering were associated with a lower incidence of WAD injury claims.

Holm et al ³⁶ conducted a study in Sweden wherein questionnaires were mailed to 1,187 persons who reported WAD after an MVC and filed an insurance claim for injuries. The questionnaire asked about prior health, details about the collision, and symptoms after the collision. The following factors were reported to be significantly associated with severe initial neck pain intensity: low educational level (OR 2.8), being sole adult in the family (OR 1.6), prior neck pain (OR 2.9), prior headache (2.2), prior poor general health (OR 2.6), and exposure to rollover MVC (OR 1.9). The authors concluded that sociodemographic and economic status, pre-injury health status, and collision-related factors were associated with the degree of participants’ initial neck pain intensity.

Several factors, including job style, severity of injury, and social class, were also found to have an impact on the time taken off work following whiplash injuries.³⁷ The data for this study were extracted from the files of 800 medicolegal cases in a private orthopedics practice. The mean time off work corresponded to the severity of injury: 10.6 days for minor injuries, 12.1 days for moderate, 13.8 days severe, and 24.9 days very severe. Heavy manual workers were off work an average of 20.5 days, 15.7 days light manual, 13.9 days for drivers, 9.2 days secretarial, and 12.8 days sedentary. Analysis for each social class showed that professionals were off 7.0 days, 16.1 days for skilled nonmanual workers, and 34.2 days skilled manual, and 11.5 days unskilled manual. Approximately 31% of the 800 cases took no time off work, about 52% returned to work after only 4 days off, and 90% returned to work after 30 days off. Only 4.9% were still off work after 12 weeks.

Sturzenegger et al interviewed a sample of 137 consecutive WAD patients soon after their MVC and found three attributes of crash mechanisms that were associated with more severe symptoms. These included occupant unpreparedness, a rear-end collision vector, and rotated or inclined head position at the time of impact.³⁸

Some studies have suggested that the introduction of automobile safety belts has increased the incidence and/or severity of whiplash injuries,³⁹^–⁴¹ although others have not found an association.^6,³⁸ A recent best evidence synthesis did not find a relationship between the use or type of safety belt and the prognosis for recovery from WAD.¹⁴ A report from the early 1990s indicated that there was a progressive increase in the number of whiplash patients seen in emergency departments in the United Kingdom since 1982 when safety belt laws were established,⁴² but the authors suggested that the increase was not necessarily due to the introduction of seatbelts. Thus, the evidence seems to point away from safety belts having an impact on the incidence of whiplash injuries. Their use should always be encouraged, however, because they have been shown to significantly reduce the risk of serious injury and death in MVCs.^43,⁴⁴

Risk Factors for Developing Chronic WAD

Risk factors for developing chronic symptoms following whiplash include some of the same that increase the risk of being injured in the first place. A number of risk factors have been investigated that were initially thought to increase the chance of developing chronic WAD symptoms (e.g., advancing age, female gender, neck pain on palpation, pain or numbness radiating from the neck to the upper extremities, headache, pretraumatic neck pain, low educational level, and position of the occupant at impact). However, the findings of most studies pointing to a positive association are not robust, are sometimes conflicting, and many are of poor methodological quality.⁴⁵ Ultimately, only a few risk factors have emerged as being significant. Table 9-1 provides a list of commonly reported risk factors for developing chronic whiplash.

TABLE 9-1 Some of the Reported Risk Factors for Developing Chronic Whiplash

Category	Risk Factor
Patient demographics	• Advancing age • Female gender • Low educational level Only gold members can continue reading. Log In or Register to continue Share this: Click to share on Twitter (Opens in new window) Click to share on Facebook (Opens in new window) Related Related posts: Introduction The Safety and Effectiveness of Common Treatments for Whiplash Prognosis of Whiplash-Associated Disorders Imaging Management of Muscle Injury and Myofascial Pain Syndromes Functional Anatomy of the Cervical Spine Stay updated, free articles. Join our Telegram channel Tags: Whiplash A Patient Centered Approach to Management Mar 13, 2017 \| Posted by admin in PHYSICAL MEDICINE & REHABILITATION \| Comments Off on Epidemiology of Whiplash Injuries Full access? Get Clinical Tree Get Clinical Tree app for offline access Get Clinical Tree app for offline access