Preferential Location for Arterial Dissection Presenting as Golf-Related Stroke

Discussion

Our study illustrates that arterial dissection from golf-related stroke was more likely to be on the right side and predominantly in the extracranial vertebrobasilar system. This preference may be explained by the anatomic vulnerability of the vertebrobasilar system and the biomechanics of the golf swing.

Recent studies on ethnic differences in spontaneous vertebral artery dissection have shown that intracranial dissection is more common than extracranial dissection in East Asian populations.⁷ Our study of golf-related vertebral artery dissection shows that extracranial involvement is more frequent than intracranial involvement. As compared with either their intracranial segments or extracranial arteries of similar caliber, greater mobility of the extracranial segments of the carotid and vertebral arteries leads to increased susceptibility for injury by surrounding hard structures including bones, ligaments, and contracted muscles.^6,8 Even with an external elastic lamina and a thickened media in the extracranial arteries, various studies have found that the atlantic (V3) portion of the vertebral artery is susceptible to VA dissection during trauma.⁸ This V3 portion is exposed without the support of bony structures and rotates freely during inadvertent head movement. Extracranial vertebral artery dissection has also been reported in patients who have undergone chiropractic manipulation, fixed neck posture caused by long-lasting surgery, or chest compressions during cardiopulmonary resuscitation.^9,10 In addition, dynamic imaging studies show that the VA is compressed and even occluded at the extracranial portion during contralateral head rotation.^12,13 These reasons support direct mechanical injury of the extracranial vessels as the etiology for golf-related stroke.

VA injuries during sports activities with repetitive neck movement have been reported in yoga, tennis, volleyball, judo, bowling, and wrestling.^3,14,15 Most sports-related vessel damage is caused by dissection or thromboembolism.³ A similar case of right VA dissection associated with unidirectional stereotypical movement was reported in a right-handed archer and is known as “bow hunter's stroke.”¹⁵ As compared with other sports, the golf swing is a high-speed, unidirectional, stereotypical rotational movement. Force is proportional to mass and acceleration of an object, as stated by Newton's second law. Torque (τ: torque) is a moment of force in rotating movement, and its magnitude depends on the length of the lever arm (r: length) and the force (F: force). Therefore, the driving torque of the golf swing is calculated as the cross-product of the distance and force, which tends to generate rotation, as expressed in the following equation: τ = r × F.¹⁶ Our patients were all right-handed. In a right-handed swing, the central axis (hub) of the right leg during the back swing is changed to the left leg because of the body-weight shift from right to left to obtain forceful impact of the ball. As compared with the left VA, the right VA is more distant from the central axis during the body-weight shift and receives a greater torque during the golf swing. This swing trajectory also causes repetitive mechanical stress to the adjacent tissues including muscles, ligaments, and vessels.⁶ The increased stress of neck muscles adjacent to the right VA can lead to vessel injury by acting as a hammer when a golfer has greater torso-pelvic separation, misses the shot, or has insufficient warm-up.¹⁷ In the present study, symptoms occurred during the golf swing in many of the cases (On-line Table).¹⁸ Our 2 professionals and 1 player with low handicap self-reported attempts to maximize torso-pelvic separation to get more distance. From this perspective, a right-sided preference for this specific type of stroke can be explained by a momentary high torque status in relation to the forceful hitting phases (downswing, impact, and follow-through) and an anatomic vulnerability at the hypermobile portion of the right VA (Fig 2).

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Fig 2.

Mechanical explanation for the predominance of the right vertebral artery (VA) dissection during a golf swing. A, Late follow-through phase. B, Anatomy of neck muscles adjacent to the hypermobile segment (V3) of the VA. C, Vulnerability of the right VA during the golf swing. In a right-handed swing, there is a combination of right-to-left body-weight shift and counter-clockwise body rotation. This gives the right shoulder (R to R′) a longer arch compared with the left shoulder (L to L′). In the same setting of force (F), the right VA receives a greater torque (τ) than does the left VA because it has a longer distance (r) from the central axis (dotted line). The anatomic preference for this specific stroke syndrome can be explained by a momentary high torque (τ = r × F) during body-weight shift and forceful rotation of the body and neck.

Our study has several limitations. Given the small number of patients with golf-related stroke in this study, investigations with more cases are needed for a balanced interpretation. Moreover, the handedness of half of the patients was unknown despite the significant association with the laterality of the golfer's stroke. Finally, video analyses of swing phases were not investigated in a biomechanical laboratory. Five cases (36%) had no relationship with the direct golf swing even though the mechanical injury was suspicious for the development of arterial dissection during the swing.