Pulmonary Embolism in an Adolescent Soccer Player

Venous thromboembolism among physically active young adult females

Background

Young adult females are at risk of venous thromboembolism (VTE) due to various acquired and transient factors. In recent years, a growing number of females have engaged in strenuous physical activity, but its role as a risk factor for VTE is uncertain.

Objectives

To determine the incidence of VTE in young adult females engaged in strenuous physical activity.

Methods

A large national cohort of female individuals enlisted in the Israeli Defense Forces between 2012 and 2019 was analyzed. The study group consisted of participants undergoing strenuous physical training during their military service, while the control group maintained regular activity levels. We compared the incidence of VTE between the groups and adjusted for potential risk factors using a multivariate Cox analysis.

Results

The cohort included 160,718 female individuals aged 18 to 21years, of whom 11,745 engaged in strenuous physical activity and 148,973 served as controls. During a mean follow-up of 1.7 years, VTE occurred in 5 individuals (0.04%) in the strenuous activity group and 47 individuals (0.03%) in the control group. The incidence per 10,000 person-years was 2.41 (95% CI, 0.78-5.62) for the strenuous activity group and 1.82 (95% CI, 1.34-2.42) for the controls. Strenuous activity did not increase the risk for VTE in univariate or multivariate regression, with a hazard ratio (HR) of 1.27 (95% CI, 0.49-4.22). Use of oral contraceptives was the only significant risk factor, demonstrating dose effect; HR 1.95 (95% CI, 1.06-3.57) for low dose and HR 3.62 (95% CI, 1.40-9.37) for medium estrogen dose contraceptives.

Conclusion

Strenuous physical activity did not increase the risk for VTE among a large cohort of young adult female individuals.

Non-Cardiac Conditions that Mimic Cardiac Symptoms in Athletes

When considering the variety of complaints an athlete can present with, chest pain is arguably the most concerning given the potential for catastrophic outcomes. Luckily, these do not comprise the majority of cases, and indeed, are quite rare. The bulk of presentations of athletes with chest pain are due to musculoskeletal, gastrointestinal, and pulmonary causes. Each and every healthcare provider who works closely with athletes must have a thorough understanding of contributing conditions that present as chest pain. Here, we explore some of the more prevalent causes of non-cardiac chest pain, classic presentations, and management considerations.

Sport and Venous Thromboembolism

BACKGROUND

The occurrence of venous thromboembolisms (VTE) in association with sporting activity has been described but not yet systematically explored. The aim of this study was to determine the sites at which VTE occur in athletes, the accompanying features, and the special features of the symptoms and diagnosis, so that physicians can take the findings into consideration.

METHODS

A search of the literature in the databases PubMed, Web of Science, and Cochrane in accordance with the PRISMA criteria, together with a search of Google Scholar up to 29 February 2020.

RESULTS

No observational studies were identified. A total of 154 case descriptions were evaluated: 89 on upper-extremity deep vein thrombosis (DVT), 53 on lower-extremity DVT, and 12 on pulmonary embolisms with no evidence of thrombosis. Ninety-five percent of the upper-extremity DVT involved the region of the subclavian/axillary vein. Thoracic outlet syndrome (38%), hereditary thrombophilia/a family history of VTE (16%), intensive training (12%), and the use of oral contraceptives (7%) were identified as accompanying features. The upper-extremity DVT occurred mainly in male strength athletes and ball sports players. The lower-extremity DVT were located in the lower leg/knee (30%), the thigh (19 %), or occurred in combination in the lower leg-to-pelvis region (30 %). The features accompanying lower-extremity DVT were hereditary thrombophilia/a family history of VTE (30%), trauma (25%), immobilization (21%), and the use of oral contraceptives (11%). The lower-extremity DVT were found in endurance sports and ball sports. The symptoms may be obscured by sport-specific symptoms/trauma, and diagnosis is often delayed. Early D-dimer determination is useful and is complemented by diagnostic imaging.

CONCLUSION

VTE are found in association with sports. The background factors, the sites of VTE, the types of sports involved, and the accompanying features are all important to know. The symptoms may be obscured, and it may be difficult to reach the correct diagnosis. The possible presence of DVT must be borne in mind.

Performance of wells score to predict deep vein thrombosis and pulmonary embolism in endurance athletes

INTRODUCTION

There are an increasing number of reports describing deep vein thrombosis (DVT) and/or pulmonary embolism (PE) in otherwise healthy endurance athletes. The Wells score is the most commonly used clinical prediction rule to diagnose DVT/PE in clinical populations. However, the Wells score may have limited utility for recognition of DVT/PE in athletes, contributing to missed or delayed diagnosis.

OBJECTIVE

We performed an analysis of the ability of the Wells score to identify DVT/PE events in athletes through a review of published case reports.

METHODS

A systematic search of the literature yielded 11 case reports.

RESULTS

The Wells score had a 100% failure rate in identifying athletes with DVT (0/6) and PE (0/5), resulting in a delayed diagnosis for DVT of 20 ± 14 days. Retrospectively removing 'differential diagnosis' from the clinical prediction rule for DVT changed the Wells score median from 0 (range: -1 to 0) to 2 (range: 1 to 2); the threshold for predicting DVT as 'likely'. There were limited clinical characteristics captured in the Wells score for PE that were applicable to athletes, highlighting the need for reappraisal. Although the Wells score failed to accurately triage athletes with known DVT and/or PE, the addition of a D-dimer value (mean: 1566 ± 758ng/dL) to the Wells score correctly identified 9/9 athletes.

CONCLUSIONS

The Wells score had a 100% failure rate for triaging athletes with known DVT/PE. When performed, D-dimer adequately facilitated the additional diagnostic testing required for a timely diagnosis of DVT/PE in athletes. Improving awareness of an atypical presentation of thrombotic events in athletes may reduce the widespread underestimation of DVT/PE among athletes and facilitate the additional testing required for a timely diagnosis.

Fatalities in high school and college football players

BACKGROUND

Fatalities in football are rare but tragic events.

PURPOSE

The purpose was to describe the causes of fatalities in high school and college football players and potentially provide preventive strategies.

STUDY DESIGN

Descriptive epidemiology study.

METHODS

We reviewed the 243 football fatalities reported to the National Center for Catastrophic Sports Injury Research from July 1990 through June 2010.

RESULTS

Football fatalities averaged 12.2 per year, or 1 per 100,000 participants. There were 164 indirect (systemic) fatalities (average, 8.2 annually [or 0.7 per 100,000 participants]) and 79 direct (traumatic) fatalities (average, 4.0 annually [or 0.3 per 100,000 participants]). Indirect fatalities were 2.1 times more common than direct fatalities. The risk of a fatality in college compared with high school football players was 2.8 (95% CI, 0.7-8.2) times higher for all fatalities, 3.6 (95% CI, 2.5-5.3) times higher for indirect events, 1.4 (95% CI, 0.6-3.0) times higher for direct injuries, 3.8 (95% CI, 1.8-8.3) times higher for heat illness, and 66 (95% CI, 14.4-308) times higher for sickle cell trait (SCT) fatalities. Most indirect events occurred in practice sessions; preseason practices and intense conditioning sessions were vulnerable periods for athletes to develop heat illness or SCT fatalities, respectively. In contrast, most brain fatalities occurred during games. The odds of a fatality during the second decade, compared with the first decade of the study, were 9.7 (95% CI, 1.2-75.9) for SCT, 1.5 (95% CI, 0.8-2.9) for heat illness, 1.1 (95% CI, 0.8-1.7) for cardiac fatalities, and 0.7 (95% CI, 0.4-1.2) for brain fatalities. The most common causes of fatalities were cardiac failure (n = 100, 41.2%), brain injury (n = 62, 25.5%), heat illness (n = 38, 15.6%), SCT (n = 11, 4.5%), asthma and commotio cordis (n = 7 each, 2.9% each), embolism/blood clot (n = 5, 2.1%), cervical fracture (n = 4, 1.7%), and intra-abdominal injury, infection, and lightning (n = 3, 1.2% each).

CONCLUSION

High school and college football have approximately 12 fatalities annually with indirect systemic causes being twice as common as direct blunt trauma. The most common causes are cardiac failure, brain injury, and heat illness. The incidence of fatalities is much higher at the college level for most injuries other than brain injuries, which were only slightly more common at the college level. The risk of SCT, heat-related, and cardiac deaths increased during the second decade of the study, indicating these conditions require a greater emphasis on diagnosis, treatment, and prevention.

Factor V leiden thrombophilia in a female collegiate soccer athlete: a case report

OBJECTIVE

To raise awareness among health care providers caring for an active population to an uncommon genetic mutation that increases the risk for a potentially fatal venous thromboembolism.

BACKGROUND

A 19-year-old previously healthy female collegiate soccer athlete complained of coughing and progressively decreased exercise tolerance, which were attributed to a recent illness and lack of sleep. Later that evening, she complained of dyspnea and pleuritic pain and was referred to the emergency department. Bilateral pulmonary emboli were identified with computed tomography, and a hypercoagulable panel revealed that the patient was heterozygous for the factor V Leiden mutation.

DIFFERENTIAL DIAGNOSIS

Pneumonia, pneumothorax, pericarditis, pleuritis, gastroesophageal reflux disease, pulmonary embolism.

TREATMENT

Intravenous heparin therapy was initiated immediately in the emergency department. This was followed by inpatient anticoagulant therapy for 5 days and outpatient anticoagulant therapy for an additional 12 months. During this time, the patient was unable to participate in soccer drills or return to competition and was limited to conditioning activities due to the risk of increased bleeding time.

UNIQUENESS

Documented cases of pulmonary embolism in a young athletic population are rare and are usually associated with genetic risk factors. Factor V Leiden is a relatively uncommon genetic mutation that dramatically increases the risk for venous thromboembolism. Although the fatality rate in this population is low, fatality is preventable if the condition is recognized early and managed properly.

CONCLUSIONS

Athletes should be encouraged to communicate with their athletic trainers regarding any changes in health status or medication usage. When an athlete presents with nonspecific symptoms such as dyspnea and chest pain, athletic trainers should consider the possibility of pulmonary embolism. A high degree of suspicion results in early diagnosis and treatment and may prevent a fatal event.

Sixteen-year-old athlete with chest pain and shortness of breath due to pulmonary emboli

BACKGROUND

Pulmonary embolism (PE) is a life-threatening condition that is extremely uncommon in the healthy pediatric population.

OBJECTIVE

Because pediatric PE is rarely on the Emergency Physician's differential diagnosis, with this case we hope to increase the clinical suspicion for PE in children who present to the Emergency Department (ED).

CASE REPORT

This is a case of bilateral pulmonary embolism in a 16-year-old basketball player whose only risk factor is oral contraceptive medication. Initial vital signs demonstrated a temperature of 37.1°C (98.8°F), blood pressure 124/74 mm Hg, heart rate 74 beats/min, respiratory rate 16 breaths/min, and oxygen saturation 100% on room air. Subsequent vital signs, physical examination, chest radiograph, electrocardiogram, and laboratory assessments were all within normal limits. Using clinician gestalt in combination with the patient's Wells score of 0, a D-dimer was obtained and returned at 1916 ng/mL. The computed tomography scan with PE protocol detected a total of seven pulmonary emboli bilaterally. The patient was anticoagulated with Lovenox (Sanofi US, Bridgewater, NJ) in the ED and admitted to the pediatric intensive care unit. Complete thrombophilia work-up was negative. The patient was discharged with Lovenox and was transitioned to warfarin.

CONCLUSIONS

Emergency Physicians may be inclined to discharge a pediatric patient at low pre-test probability for PE with outpatient follow-up if the work-up is non-contributory. But the current adult PE clinical criteria are not as sensitive or specific in the pediatric population. This case demonstrates that the clinician's gestalt should play a major role in combination with the Wells score and PERC (pulmonary embolism rule-out criteria) rule to exclude PE until clinical decision rules specific for the pediatric population are established.

Bilateral pulmonary emboli in a collegiate gymnast: a case report

OBJECTIVE

To characterize the diagnosis of pulmonary embolism in collegiate student-athletes and to raise awareness among sports medicine providers of the possibility of this potentially fatal disease in the student-athlete population.

BACKGROUND

An 18-year-old, previously healthy National Collegiate Athletic Association Division I female gymnast complained of intense pain, bilaterally, deep in her chest. The athlete was referred to her team physician, who identified normal vital signs but referred her to the emergency room because of significant pain. The student-athlete was diagnosed with bilateral pulmonary emboli in the emergency room.

DIFFERENTIAL DIAGNOSIS

Pneumonia, renal calculi, upper urinary tract infection, intercostal muscle strain or rib fracture, pancreatitis, gall bladder disease, gastritis, ulceration, esophagitis, infection, tumor, pulmonary embolism.

TREATMENT

The student-athlete was immediately placed on anticoagulants for 6 months. During that time, she was unable to participate in gymnastics and was limited to light conditioning.

UNIQUENESS

Documented cases of female student-athletes developing a pulmonary embolism are lacking in the literature. Two cases of pulmonary embolism in male high school student-athletes have been documented, in addition to many cases in elderly and sedentary populations.

CONCLUSIONS

All health care providers, including sports medicine professionals, should be aware that this condition may be present among student-athletes. During the initial evaluation, prescreening should include questions about any previous or family history of pulmonary embolism or other blood clots. Athletes who answer positively to these questions may have a higher likelihood of pulmonary embolism and should be referred for testing.

Atypical chest pain in athletes

Initial management of chest pain in athletes always should involve assessment for serious, life-threatening causes, such as myocardial infarction. However, atypical chest pain, or chest pain not due to myocardial ischaemia, is a common presentation in the athletic population. This review looks at the possible causes of atypical chest pain in athletes, focusing upon conditions that are more common in athletes than the general population or that have a link to exercise. Causes can be grouped due to the system involved (musculoskeletal, gastrointestinal, respiratory, cardiac) with more common causes including rib stress fractures, costochondritis, muscle strain, gastroesophageal reflux, and exercise-induced asthma. Psychogenic causes can be common in children/adolescents. Return to play is discussed, with some conditions such as myocarditis warranting a long (at least 6 months) absence from training, whereas others such as precordial catch require nothing more than reassurance.