Injuries Affecting Intercollegiate Water Polo Athletes: A Descriptive Epidemiologic Study

Data Collection

The study population was made up of Pac-12 athletes from 4 men’s and 5 women’s water polo teams during the observation period. The observation period was July 2016 through June 2021 for 3 men’s and 4 women’s teams and July 2018 through June 2021 for 1 men’s and 1 women’s team. All athletes who consented to having their deidentified injury and illness data used for research were included in the study population regardless of how long they remained in the sport; none were excluded. This study was considered exempt from institutional review board approval.

The following data are collected into the Pac-12 Sports Injury Research Archive for each health event (injury or illness) sustained by an athlete: deidentified athlete ID, sex, event year, body part affected, injury/illness type, mechanism of injury, season timing (in season vs off season), event setting, requirement for physician encounter, requirement for surgery, and return-to-play data. Information for each event is maintained in the database by athletic trainers and/or physicians over the course of the injury or illness; for example, the event year is recorded at the time when an athlete is first evaluated, whereas return-to-play outcome information is determined at the time of injury or illness resolution or when the outcome can be prospectively determined with confidence. Data from the Pac-12 Sports Injury Research Archive were extracted and transferred for analysis.

Definitions

A health event was defined as a player’s first presenting to his or her athletic trainer or physician with a health complaint. Health events were classified as either illnesses or injuries. Illness was defined as a health event that was nonmusculoskeletal, nontraumatic, and labeled as “illness,” “infection,” “condition,” or “disease” in the event type; and injury was defined as any health event that was not an illness, including all musculoskeletal conditions (such as fractures, arthritis, and bursitis) and nonmusculoskeletal conditions that resulted from a distinct traumatic event (such as concussions, lacerations, and hematomas). Athletes affected was defined as the number of athletes suffering from at least 1 of the specified health events during the observation period.

Statistical Analysis

Statistical analysis was performed using Microsoft Excel Version 16.49 in consultation with the biostatistics core facility at our institution. The percentage of health events was calculated as the number of the specific injury/illness divided by the total number of injuries/illnesses. The percentage of athletes affected was calculated as the number of athletes affected at least once by the specific injury/illness divided by the total number of athletes observed. Relative risk (RR) was used to compare the percentage of athletes affected between sexes, with statistical significance defined by a 95% CI, that does not include 1.0 (P < .05).

Shoulder Injuries

Previous studies on water polo injuries have mostly focused on shoulder pathology, proposing increased shoulder mobility, rotator cuff imbalances, and repeated throwing as major causes of pain. ^18,30 The present study found the shoulder to be the most common injury site for water polo players; however, for common shoulder injuries including synovitis, muscle strain, and muscle spasm/cramps/soreness, more than 50% of athletes returned with no missed time or restrictions. In addition, only a total of 3 shoulder injuries required surgery, 1 for an acute dislocation and 2 for chronic instability. Operative shoulder injuries in water polo are not well studied; however, data from other NCAA sports suggest labral tears and shoulder dislocations to be the most common injuries requiring surgery. ¹⁰ Findings from this study suggest that although shoulder injuries are the most common injuries among water polo players, their clinical significance appears relatively minor compared with other injuries such as concussions and FAI.

Concussions

Despite being widely studied in a variety of collegiate sports, concussion data on water polo players from an NCAA injury surveillance study have been absent to date. ³¹ Concussions were found to make up 1.9% of injuries in 8904 matches from the Olympic Games and World Championships, ¹⁹ similar to the 2.1% rate of concussions sustained in competition in the present study. However, the importance of out-of-competition injury surveillance data is underscored by the 81.9% of concussions that occurred outside of competition in the present study, resulting in concussions being 11.4% of all injuries and by far the most common single injury diagnosis overall. In addition, concussions had the worst return-to-play outcomes compared with other common diagnoses, with 91.6% of concussions resulting in the athlete missing playing time, 2.4% resulting in the athlete having to return the following season, and 2.4% resulting in the athlete being unable to return because of the injury. These findings highlight the critical need for concussion-reduction strategies, which may benefit from different approaches for men and women; whereas the highest percentage of male concussions occurred via contact with another player, the highest percentage of female concussions occurred via contact with a playing device (ie, the ball). As several studies have shown position-specific differences in head impacts/concussions during play, ^{2 –4} concussion-prevention strategies would be enhanced by more detailed injury surveillance data that include player-position information and a more thorough description of the injury mechanism.

Femoroacetabular Impingement

The irregular “eggbeater” or treading-water motion used during water polo play is recognized to contribute to lower extremity injuries, with knee pathology often emphasized. ^8,26 Although less traditionally discussed, groin/hip pathology is becoming increasingly recognized as important in water polo. ^5,11 Strikingly, this study found pathology of the groin/hip/pelvis/buttock to make up 50% of injuries requiring surgery, which was considerably more than the second most common site, the hand/wrist/forearm (15.4%). A total of 9 of the 13 groin/hip/pelvis/buttock injuries had the specific diagnosis of FAI, and the other 4 were described more generally as chronic joint trauma and may or may not have been FAI. Some 8 of the 13 surgical procedures resulted in athletes returning to play, 4 resulted in an indeterminate outcome with either athletes leaving campus or the outcome not specified, and 1 resulted in the athlete unable to return from the injury. Overall, FAI was diagnosed in 16 athletes for a total of 21 events (2.9% of injuries), although this is likely to be an underestimate because radiographic evidence of FAI has been found in around 2 of 3 water polo players and synchronized swimmers, ¹⁷ and many athletes remain asymptomatic.

FAI is thought to arise from repetitive hip loading at extreme ranges of motion, especially hip flexion and internal rotation, which is seen during water treading, in skeletally immature individuals, causing bony remodeling. ²⁸ Despite previous reports showing great surgical outcomes for both water polo and swimming athletes, ^9,23 the high burden of surgery and missed playing time associated with FAI makes this injury a critical subject of future research. For example, such research could focus on how early sport specialization and high training volume, which have been shown to increase injury rates and missed time among NCAA athletes, ¹ may influence rates of FAI.

Injury Comparisons With Other Sports

Across NCAA sports, upper extremity injuries account for approximately 20% of all injuries, ¹⁰ which is notably lower than the 41.2% value for water polo seen in the present study. This is somewhat unsurprising for a sport that relies heavily on the upper extremities for throwing, wrestling, and swimming and has comparable rates of upper extremity injuries with NCAA swimming, which is also above 40%. ¹⁵ Elbow sprains, the fourth most common injury diagnosis overall for water polo players, are also particularly prevalent in football, baseball, and wrestling, ¹³ which share some of the same throwing and contact requirements. The relatively low percentage of lower extremity injuries (26.1%) in water polo was mostly anticipated, compared with NCAA land sports such as basketball in which lower extremity injuries make up about 60% of injuries, with ankle sprains being the most common diagnosis. ⁷

Sex-Based Differences

Several significant differences were seen between various male and female injury rates, although the overall risk of injury was not different between the sexes. Men were found to be at significantly higher risk of being injured in the weight room; injuring the spine/neck; having muscle spasm/cramp/soreness, fracture, and visceral damage/trauma/surgery injury types; being diagnosed with shoulder tendinopathy and lumbar spine muscle spasm/cramps/soreness; suffering a concussion in off-season practice or via contact with another player; and having symptomatic COVID-19. Although these differences could be due to chance, several of these corroborate previously published sex differences that warrant mentioning. For example, in a study of comparable NCAA sports, men were found to be more likely than women to sustain a neck or cervical spine injury. ⁶ Another study of 25 NCAA sports found male athletes to have higher rates of lumbar injuries compared with female athletes. ¹⁴ In addition, although men having a significantly higher risk of symptomatic COVID-19 is likely to be multifactorial, it is notably in line with evidence that different immune responses to SARS-CoV-2 between men and women result in greater COVID-19 symptoms among men. ²⁷ Finally, an earlier study comparing sex-based differences in water polo injuries at one NCAA institution found women to suffer from significantly more shoulder injuries compared with men; however, this was hypothesized to be because of team-specific training differences ²⁴ and was not seen in the present study.

Limitations

This study is not without limitations. One limitation of this study was the use of a relatively new injury surveillance database that began collecting data on water polo in 2016; the relatively lower number of events in the earlier years of the database is probably owing to lower reporting during the injury surveillance program rollout. However, the addition of 1 men’s and 1 women’s team in July 2018 does account for some of the increased number of injuries seen in 2018 and 2019. The drop in injury rates in 2020 is likely to be the result of play suspension secondary to the COVID-19 pandemic, and therefore is unlikely to be reflective of injury rates during a normal season. Thus, these both probably contribute to an underestimation of true injury rates. In addition, the database has no athlete exposure or observation period data for individual athletes, making us unable to report injury rates per athlete exposure. However, if desired, one could estimate the number of water polo “athletic exposures,” defined as an athlete participating in an NCAA-sanctioned practice or competition, based on data from other sports; for example, an NCAA swimmer has an average of 155 to 160 athletic exposures per year. ¹⁵ One would also need to estimate the average number of years observed per athlete, which would likely be between 2 and 3 years in the present study depending on chosen assumptions. An unavoidable limitation of this study is that it includes data only on athletes who consented to having their injury and illness data used for research. In addition, there were likely to be injuries and illnesses that were never brought to the attention of athletic trainers and physicians and thus were not included in the database. Finally, this study assumed complete diagnostic accuracy by athletic trainers and physicians during documentation, because diagnostic criteria for injuries were not specified.