Volume 12, Issue 3 (May & June 2021)                   BCN 2021, 12(3): 421-426 | Back to browse issues page


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Golmohammadi R, Delbari A. Report of a Novel Bilateral Variation of Sciatic and Inferior Gluteal Nerve: A Case Study. BCN 2021; 12 (3) :421-426
URL: http://bcn.iums.ac.ir/article-1-1530-en.html
1- Department of Anatomical Sciences, Cellular and Molecular Research Center, School of Medicine, Sabzevar University of Medical Sciences, Sabzevar, Iran.
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1. Introduction 
Sciatic nerve is the longest and thickest nerve in the human body, and it originates from the sacral plexus. After forming in the pelvis, it runs through the buttock and down the lower extremity. Sciatic nerve innervates nearly the whole skin of the leg and the muscles of the back of the thigh, and those of the leg and foot. It is orientated from the spinal nerves of L4-S3 and contains fibers from both the anterior and posterior divisions of the lumbosacral plexus.
Usually, the fibers unite to form a single nerve in front of the piriformis muscle. This muscle originates between the anterior sacral foramina on the anterolateral surface of the sacrum and exits the pelvis through the greater sciatic foramen to insert on the greater trochanter of the femur. Piriformis is used as a landmark in this region for muscles and neurovascular structures.
Sciatic nerve leaves the pelvis through the greater sciatic foramen and enters into the gluteal region by passing under piriformis. The inferior gluteal nerve and vessels, the internal pudendal vessels, and the pudendal nerve are located medial to this nerve. The nerve descends beneath the gluteus maximus muscle, between the greater trochanter of the femur and ischial tuberosity to reach the back of the thigh. Usually, at the superior angle of the popliteal fossa, sciatic nerve divides into two terminal branches: the tibial nerve and the common peroneal nerve. 
Tibial nerve passes through the popliteal fossa to enter the posterior compartment of the leg. The common fibular nerve descends obliquely along the lateral side of the popliteal fossa to the head of the fibula and winds around the head of the fibula.
Numerous anatomical variations have been reported both in the course and distribution of this nerve (Adibatti & Sangeetha, 2014; Anbumani, Thamarai Selvi & Anthony Ammal, 2015; Berihu & Debeb, 2015; Brooks et al., 2011; Desalegn & Tesfay, 2014; Patel, Shah, Vora, Zalawadia & Rathod, 2011; Saritha, Praveen Kumar & Supriya, 2012). For instance, it passes completely under the piriformis in the majority of the population, but in a small portion of cases, the tibial or common peroneal nerve passes through or over the muscle (Lewis, Jurak, Lee, Lewis & Gest, 2016). Such variations are significant in gluteal surgeries and in conditions called piriformis syndrome (Natsis et al., 2014).
On the other hand, the gluteal region is a frequently used area for intramuscular injections, and in the case of sciatic variations, the risk of nerve injury is noticeably higher, especially when intramuscular injections are applied for the treatment of piriformis syndrome (Akdemir Ozisik, Toru, Cem Denk, Taskiran & Gundogmus, 2014; Siddiq, Khasru & Rasker, 2014). In this syndrome, the drug is directly injected into the piriformis muscle to reduce patients’ pain.

2. Case Presentation 
In this paper, we report an interesting bilateral multiple variations of the sciatic nerve in a male cadaver (Figure 1).
On both sides, the sciatic nerve was divided into its terminal branches in the pelvis, and the tibial nerve and common peroneal nerve had their epineurium emerging in the gluteal region.
In the right lower limb, the most interesting variation was the existence of a third thick nerve medial to terminal branches of the sciatic nerve, which was nearly equivalent in diameter with tibial and common peroneal nerve (Figure 2).
Judging from its termination in the gluteus maximus muscle, it was the inferior gluteal nerve. The inferior gluteal nerve is the main motor nerve of the gluteus maximus muscle, which arises from the dorsal branches of the ventral rami of L5, S1, and S2 sacral nerves. 
In the left lower limb, these variations were detected:
1. Tibial and common peroneal nerves passed over the piriformis muscle to reach the gluteal region (Figure 3).
2. The inferior gluteal nerve was a branch of the common fibular nerve (Figure 3). Interestingly this nerve on the left side was remarkably thinner than its counterpart on the other side.
3. The route of the common fibular nerve was more vertical and it did not cross the head and neck of the fibula and reached the lateral aspect of the leg nearly 5 cm below the head of the fibula (Figure 4).
3. Discussion 
Researchers have reported many variations of the sciatic nerve and the relationship between this nerve and the piriformis muscle. Ignoring these variations can cause irreparable damages to patients. SU Rao et al. reported that sciatic nerve in 16% (8 limbs of 50 dissected lower limbs) of cases bifurcates at a higher level (in the gluteal region after emerging below the piriformis [7 limbs] or at lower one-third of the back of the thigh [1 limb]). Other studies reported this type of variation 13.7% (Gabrielli, Olave, Mandiola & Rodrigues, 1997), 4% (Ugrenović et al., 2005), 20.9% (Pokorný, Jahoda, Veigl, Pinskerová & Sosna, 2006), 16.3% (Prakash et al., 2010), 48% (Güvençer, Iyem, Akyer, Tetik & Naderi 2009), 20.1% (Ogeng’o, El-Busaidy, Mwika, Khanbhai & Munguti, 2011), 8% (Adibatti & Sangeetha, 2014),18% (Anbumani et al., 2015), and 31.66% (Budhiraja et al., 2016). In Bryan Jason Bergsteedt study, 170 South African cadavers (340 lower limbs) were dissected to assess anatomical variations in relation to the piriformis and sciatic nerve bifurcation among the South African population. She reported that in 21.4% of cases, sciatic nerve bifurcation has not occurred in the popliteal fossa (Bergsteedt, 2019). These studies show that this type of variation ranges from 4% to 48%, suggesting that race can play a unique role in anatomic variations. 
Another anatomic variation in the more clinically important region is the relationship of the sciatic nerve with the piriformis muscle. Beaton and Anson classified six variants regarding the anatomical relationship between these two structures: type 1, an undivided sciatic nerve below the piriformis muscle (normal course); type 2, a divided sciatic nerve passing through and below the piriformis muscle; type 3, a divided nerve passing above and below an undivided muscle; type 4, an undivided sciatic nerve passing through the piriformis muscle; type 5, a divided nerve passing through and above the muscle heads; and finally type 6, the undivided sciatic nerve passes above the piriformis muscle (Beaton & Anson, 1938). The right and left sides of the present case can be considered as subgroups of types 1 and 6, respectively. Types 1, 2, and 3 have been reported frequently in literature. The other types are rarer (less than 1% of the populations studied) (Tomaszewski et al., 2016). Types 5 and 6 were only hypothesized and not seen in Beaton and Anson’s study sample.
In the present case, the high division of the sciatic nerve was observed both in the right and left sides. Besides, on the right side, there was a thick inferior gluteal nerve ‏medial to terminal branches of sciatic nerves that its diameter was nearly equal to the tibial and common peroneal nerve. However, the injury of the inferior gluteal nerve is rare but often happens as a complication of posterior approach in hip replacement. Indeed, such a thick inferior gluteal nerve increases the risk of nerve injury during such procedures.
On the left side, tibial and common peroneal nerves have emerged above the piriformis muscle. We know that intramuscular injection is an essential procedure for administering a variety of medications (Ramtahal, Ramlakhan & Singh, 2006), and unfortunately, injury to the sciatic nerve is a worldwide problem resulting from a misplaced intramuscular injection in the gluteal region (Mishra & Stringer, 2010). In the present case that the emerging point of the sciatic nerve parts in the gluteal region is nearer to the safe area of muscular injection, the risk of nerve injury increases noticeably, and such variations are very important clinically. On the other hand, local injection to piriformis is used to manage piriformis syndrome (Benzon, Katz, Benzon & Iqbal, 2003). If such a variation exists in a candidate for this treatment, the risk of nerve damage is very high.
The other variation in the left side was the vertical route of the common fibular nerve (It did not cross the head and neck of the fibula and reached the lateral aspect of the leg nearly 5 cm below the fibular head). Although such a route reduces the nerve injuries due to proximity of head and neck of fibula, it increases the risk of its cutting in upper leg surgeries.
Although some of these variations, like division of sciatic nerve in the pelvis, are more common, and some are relatively rare, a collection of these variations in a single cadaver is unique and has not been reported ever. 

4. Conclusion 
Medical students, as future physicians and nurses, learn in gross anatomy classes a general description of the human body, and soon, they will diagnose and treat all patients based on this knowledge. It is often overlooked that anatomy is a description of most people’s bodies and not all of them. In the case of the gluteal region, what students learn about the sciatic nerve and its relation with piriformis muscle may be quite different from what they will experience in the clinic and operating room. Anatomical variations of the sciatic nerve, at least partly, contribute to some injuries to the gluteal region by the medical team. So having up-to-date knowledge of anatomical variations of the region is necessary to reduce this type of injury.
This case report indicates that peripheral nerve distribution patterns may be different to a great extent from what students learn as normal anatomy of the human body. This concept can promote the vision of our future physicians, nurses, and other medical team members in selecting better diagnostic and therapeutic procedures for patients. Finally, medical progress needs more accurate knowledge of the human body variations to improve diagnosis and therapeutic management (Khanday, 2019).

Ethical Considerations
Compliance with ethical guidelines

This study was approved by the Ethics Committee of Sabzevar University of Medical Sciences (Code: IR.MEDSAB.REC.1399.038).

Funding
This research did not receive any grant from funding agencies in the public, commercial, or non-profit sectors.

Authors' contributions
Both authors equally contributed to preparing this article.

Conflict of interest
The authors declared no conflict of interest.


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Type of Study: News and Reports | Subject: Clinical Neuroscience
Received: 2019/06/13 | Accepted: 2020/04/19 | Published: 2021/05/1

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