INTRODUCTION
Arterial tortuosity involves varying degrees of abnormal twists and bends [7]. There are a few arteries known for their tortuous course, including the classic descriptions of the splenic and facial arteries [40]; however, there have been numerous reports of incidental findings of anatomical variation in arteries throughout all regions of the body including the head and neck [6, 14], thorax [42], abdomen and pelvis [27], upper limb and lower limb [45, 46]. These incidental cases report findings generally with involvement of a single vessel are distinct from arterial tortuosity syndrome, which is characterized by “severe and widespread arterial tortuosity of the aorta and middle-sized arteries” plus craniofacial involvement and skin or connective tissue disorder [5]. While the exact causal mechanisms of arterial tortuosity are unknown, it has been associated with senescence, high blood pressure as well as other cardiovascular risks, and is more common in females [7].
Clinically, both arterial and venous abnormal tortuosity has been associated with compression of nerves [11, 15, 26, 49]. A tortuous ulnar artery may also present difficulties to neuroradiologists, radiologists and surgeons during relevant procedures [36, 44]. Regarding the lower limb, previous reports had no comment on clinical implications of posterior tibial arterial tortuosity; though tortuosity of the accompanying posterior tibial veins has been linked to entrapment of the tibial nerve within the tarsal tunnel [31].
Here we report and discuss a unique case of distal limb arterial tortuosity discovered during a routine cadaveric dissection. While there have been reports in distal limb vessels, to our knowledge, these have not been reported in the same individual outside of arterial tortuosity syndrome.
CASE REPORT
The presence of an enlarged and tortuous ulnar artery was observed during a routine dissection of a left upper limb in a 78-year-old Hispanic male cadaver. The left ulnar artery had a typical appearance at its origin from the brachial artery; however, ~66 mm proximal to the flexor retinaculum, a significant winding pattern was observed with sinusoidal bends and a widened appearance (Fig. 1). Further dissection revealed a mildly enlarged but not tortuous artery on the right side (Fig. 2). Dissection of the lower extremities revealed a similar pattern in the tibial artery with enlargement and tortuosity noted on the right side (Fig. 3), while the left appeared relatively normal. Further inspection and dissection of the arteries in all other regions were unremarkable.
In a questionnaire filled out prior to the donor’s death, they self-reported a brief smoking history over 50 years prior during young adulthood as well as a cancer history but did not specify which type. No enlarged lymph nodes or abnormal masses were seen. The University of Massachusetts Medical School (UMMS) Institutional Review Board determined this case report (#H00020805) is not human subject research.
METHODS
Terminology for describing vessel appearance and classification of the anatomical variation is based on Ciurica et al. [7]. While there is currently no standardised measure for determining the amount of arterial tortuosity in two-dimensions, three main methods are used consistently in the literature. The first method is based on a sum-of-angles metric, typically defined as the deviation from the anatomical normal straight path of the vessel. This metric is usually provided as a total number of degrees or as a ratio of straight-line length [12, 35, 48]. The second method calculates the degree of angulation from a centre line of flow, often as a mathematical measure of curvature, or amplitude [4]. This measure can be thought of as representing ‘wave-height’. Lastly is the ‘distance metric’ which provides a ratio of the vessel path to the straight-line measure and can be used to describe the actual length of the vessel versus the anatomical normal length. In cadaveric studies this usually involves excision and straightening of the vessel before measuring [10, 41]. Distance metric was chosen as the optimal assessment of vessel tortuosity for this study as it would more accurately represent the normally straight arteries involved. To achieve this, measures were collected for straight-line length and path. The two vessels with greatest variation (left ulnar artery and right tibial artery) were subsequently removed for further analysis. For these, vessel external and internal (lumen) diameter was measured at both the origin and at the site of greatest dilation, wall thickness was also determined at the same sites. Additionally, the number of inflection points (bends) was noted for all vessels. All of the measures were taken by two observers with calibrated digital callipers.
RESULTS
The diameter of the tortuous segment of the ulnar artery measured 8.11 mm at its widest, whereas it was only 4.66 mm at its origin (Table 1). The arterial walls of the tortuous segment appeared thickened, and the lumen of the artery measured 4.2 mm (Fig. 2). Six bends were noted in the left ulnar artery prior to diving under the palmar carpal ligament and continuing into the ulnar tunnel (Guyon’s canal). Upon continued dissection of the hand, the ulnar artery terminated into the superficial palmar arch and common palmar digital arteries. The tortuosity seen in the ulnar artery continued into the distal palmar arteries. In the area of tortuosity, the wall thickness was greater (0.88 mm) than at the origin (0.47), resulting in a reduced internal diameter of the lumen (4.07 mm vs. 4.58 mm). The left ulnar artery was then traced proximally and was noted to be typical in size and shape proximal to the bends, with no aneurysms apparent. No abnormalities were seen at the origin of the vessel from the brachial artery. The brachial artery was also traced proximally and had a typical appearance. Dissection of the right arm revealed a slightly enlarged ulnar artery which had a diameter of 5.70 mm at the origin (Fig. 2). The right ulnar artery also exhibited a slight bend, 30 mm proximal of Guyon’s canal, but a torturous pattern did not exist.
Measure |
Left ulnar artery |
Right ulnar artery |
Right tibial artery |
SLM |
132.06 ± 2.14 |
75.45 ± 3.14 |
115.73 ± 1.27 |
Path |
151.86 ± 3.94 |
93.98 ± 0.91 |
130.22 ± 1.97 |
Number of inflections |
6 ± 0 |
3 ± 0 |
4 ± 0 |
External MD origin |
4.66 ± 0.11 |
5.70 ± 0.26 |
3.47 ± 0.04 |
External MD — widest point |
8.11 ± 0.49 |
8.16 ± 0.42 |
4.86 ± 0.11 |
Internal MD — origin |
4.58 ± 0.06 |
– |
3.66 ± 0.11 |
Internal MD — widest point |
4.07 ± 0.11 |
– |
2.77 ± 0.07 |
Wall thickness — origin |
0.57 ± 0.05 |
– |
0.81 ± 0.01 |
Wall thickness — widest point |
0.88 ± 0.01 |
– |
1.32 ± 0.03 |
Dissection of the lower extremities revealed a tortuous tibial artery on the right side (Fig. 3) with the left appearing normal. The diameter of the tortuous segment of the right tibial artery measured 4.86 mm at its widest and 3.47 mm at its origin. Again, in the area of tortuosity, the wall thickness was much larger (1.32 mm) than at the origin (0.81), resulting in a reduced internal diameter of the lumen (2.77 mm vs. 3.66 mm). No other vascular variants were observed.
DISCUSSION
Numerous distal limb arterial variations have been reported in the literature [17, 21, 32, 38, 44, 49]. The present case reports a cadaveric dissection revealing distally tortuous ulnar and posterior tibial arteries, without any other vascular abnormalities. This is a particular import given that multi-site tortuosity is associated with systemic pathologies such as arterial tortuosity syndrome. While the exact cause of arterial tortuosity is unknown, several mechanisms have been suggested including calcification of the arterial wall as well as inconsistent arterial repair mechanisms [13]. Additionally, it can be related to age, loss of arterial elasticity, and position relative to the joint axis [45]. Both genetics and vascular pathologies, including hypertension and atherosclerosis, may play a role [13]. The presence of tortuous tibial arteries as well could suggest a systemic pathology, or genetic cause, as the reason for the tortuosity in this donor.
The ulnar artery is one of two terminal branches of the brachial artery. It arises from the brachial artery in the medial aspect of the forearm, typically distal to the antecubital fossa, and is the primary source of blood supply of the medial forearm. Typically, it is accompanied by the median nerve in the proximal forearm and by the ulnar nerve medially in the distal forearm and wrist. The ulnar artery terminates at the superficial palmar arch, where the arch anastomoses with a branch of the radial artery, the other terminal branch of the brachial artery [39]. The posterior tibial artery is the more posterior branch of the popliteal artery and supplies the posterior compartment of the leg. It gives rise to the fibular artery and terminally bifurcates into the medial and lateral plantar arteries. The posterior tibial artery courses with the tibial nerve and accompanying veins in the tarsal tunnel.
Variations in the upper limb vasculature have been well documented in the literature. Previous studies have described and classified upper limb arterial variations such as a superficial brachial artery, an accessory brachial artery, a superficial radial artery, and arteries with higher origins from the brachial artery, among others [22, 30, 38]. For the ulnar artery, thrombosis and aneurysmal dilatations are the most common [2]; other variations include proximal origins and superficial courses. There have been well-documented cases of variations such as a superficial ulnar artery, which poses a significant issue during forearm free flap harvesting [2, 3, 28] yet there are only a limited number of cases reporting a tortuous ulnar artery. It has been reported that a looped and tortuous ulnar artery is the rarest anatomical variation seen in the ulnar artery [44].
Arterial tortuosity has also been described in the lower limb. Tortuosity has also been reported in the popliteal artery and tibial-peroneal trunk [34]. Reported variation of the posterior tibial artery is primarily related to the level of its origin or terminal bifurcation, as well as aplasia or hypoplasia [20]. Studies examining tortuosity in the posterior tibial artery reported a prevalence of 26–35% [16, 18]; these studies focused on the region surrounding the tarsal tunnel.
Using ultrasound and Doppler, Ashraf et al. [1] determined that the mean average internal diameter of the ulnar and radial arteries were 2.4 ± 0.4 mm and 2.3 ± 0.4 mm on the right and 2.3 ± 0.3 mm and 2.2 ± 0.4 mm on the left. A cadaveric study also reports the mean internal diameter of the ulnar and radial arteries to be 2.5 and 3.2 mm on the right and 2.4 and 3.0 mm on the left [37]. We report an internal diameter of 4.2 mm of the left ulnar artery with an 8 mm external diameter suggesting that the tortuosity increases artery lumen and overall size. Early computational fluid dynamics studies in tortuous coronary arteries suggest that such changes may impede the ability of the artery to self-regulate blood flow during increased demand [47]. Nevertheless, tortuous distal limb arteries carry significant clinical implications.
Clinical implications
Vascular lesions in the ulnar artery, including a tortuous artery, can result in nerve compression. Reports have linked a tortuous ulnar artery to Guyon’s canal syndrome, a condition that causes hand numbness, pain, and tingling, resulting in a significant decline in quality of life [9]. The canal of Guyon, also called the distal ulnar tunnel, is a fibro-osseous space containing the ulnar nerve and its branches, the ulnar artery, as well as veins and lymphatic vessels [8]. Symptoms may be caused by ulnar nerve entrapment in Guyon’s canal, due to the proximity of the nerve to the mal-shaped ulnar artery [11, 15, 49]. This is also true of the tarsal tunnel in the lower extremity. Machiels et al. [25] reported that dilated or tortuous veins in the tarsal tunnel can cause compression of the posterior tibial nerve resulting in tarsal tunnel syndrome. The variation seen here in the posterior tibial artery may also have implications for tibial nerve blocks and calcaneal pin insertions. A tortuous posterior tibial artery is exceedingly rare in the literature, but it is reasonable to conclude that such an artery can compress the posterior tibial nerve and cause symptoms.
Tortuous vessels are problematic during surgery, imaging, and interventional procedures. On imaging, tortuous arteries can appear as solid masses, which can be mistaken for tumours [26]. A winding and tortuous artery is also more prone to laceration during surgery [26]. Further, the multiple bends seen in these vessels are at risk of perforation in various procedures [44]. The ulnar artery is also becoming more frequently used for percutaneous coronary intervention if the radial artery is deemed unusable [43]. In this circumstance, understanding the exact shape of the ulnar artery is necessary. In addition, the ulnar artery can be used for cerebral angiography under certain circumstances [23]. Finally, in patients undergoing dialysis, the ulnar artery can be used for creating arterio-venous fistulas [24].
In the aforementioned cases, knowledge of the ulnar artery’s actual shape and positioning is crucial. Ultrasound and magnetic resonance imaging can be used to determine this information when necessary, in attempts to reduce both the symptoms of disorders as well as iatrogenic mishaps.
The abnormal variation in the arterial pattern noted here would have an impact on blood pressure to the extremities. Blood is an incompressible viscous fluid, and basic fluid flow mechanics principles can be used to extrapolate the impact of the variation on velocity and pressure [29]. The Hagen–Poiseuille equation is used to calculate the flow of viscous fluid in a cylindrical pipe [29].
As per Poiseuille’s law, the viscosity of blood will cause a pressure drop, proportional to the length travelled [29], therefore the longer path created by the tortuosity seen here would result in lowered blood pressure travelling through the artery. While the vessels appear externally to be enlarged at the site of tortuosity this is an impact of increased wall thickness which actually results in a decrease in diameter of the lumen. When blood flows out of a larger circular pipe, into a narrower diameter its velocity will be increased; however, its pressure will decrease [33]. The narrowing of the vessel and the elongated path of the tortuosity could then be described cumulatively acting to result in decreased pressure. Additionally a decrease in pressure would be created by the inflection points (bends) [19].
Limitations of the study
The analyses presented here had a number of limitations, importantly the vessel’s external and internal diameter was measured in two dimensions, essentially a representation of flattened width versus true diameter but this was internally controlled as all were measured in the same manner. Additionally, the dryness of vessels as part of the embalming and dissection process may have led to some shrinkage of the tissues. While vessels from both sides of the body were able to be measured for the upper limb it was not possible to take measurements from the contralateral lower limb as the donor was cremated and returned due to the family’s urgent request.
CONCLUSIONS
The current report suggests that arterial tortuosity can occur in multiple sites distinct from the systemic, arterial tortuosity syndrome. A proper understanding of a patient’s specific regional anatomy is vital for radiologists, surgeons, and clinicians in general, as unknown variations can lead to unexplained pain and iatrogenic injuries. Raising awareness regarding ulnar artery tortuosity should help to reduce such events.
Acknowledgements
The authors sincerely thank those who donated their bodies to science so that anatomical research could be performed. Results from such research can potentially increase humanity’s overall knowledge that can then improve patient care. Therefore, these donors and their families deserve our highest gratitude.