Posterior Upper Rib Excision for Neurogenic Thoracic Outlet Syndrome---Feasibility and Early Outcomes

Surgical Management of Neurogenic Thoracic Outlet Syndrome: Exploring the Efficacy of the Posterior Intermuscular Approach in Cases Involving Bone Anomalies

BACKGROUND AND OBJECTIVES

This article presents a cohort study focusing on neurogenic thoracic outlet syndrome (NTOS) caused by bone anomalies in the cervicothoracic region, specifically the extraforaminal area and the scalene triangle. Our aim was to contribute to understanding NTOS diagnosis and management, particularly in patients with bone anomalies, and to highlight the potential benefits of the posterior intermuscular approach as a surgical option in this particular patient group.

METHODS

We retrospectively evaluated the patients who underwent surgery for NTOS with accessory ribs or an elongated cervical vertebrae 7 (C7) transverse process (n = 9). Patients' clinical data, preoperative neurophysiological tests, cervical computed tomography (CT) scans, CT angiography, and postoperative cervical CT scans were reviewed. A single experienced surgeon used the posterior intermuscular approach on all patients. The accessory rib and/or elongated C7 transverse process and fibrous bands were removed; C7, C8, and T1 branches of the plexus were decompressed; and neurolysis was performed. Quality of life, a functional outcome, was measured by using Disabilities of the Arm, Shoulder and Hand (DASH) questionnaire, and pain was measured using visual analog scale scores.

RESULTS

The mean follow-up time after surgery was 7 months (range: 4-10 months). Before surgery, the mean DASH score was 55.8 ± 5.6. At the 3- and 6-month postoperative evaluations, the mean DASH scores decreased to 15.7 ± 5.8 and 15.4 ± 5.7, respectively. The mean visual analog scale score was 8.2/10 before surgery and decreased to 2.4/10 and 2.1/10 at the 3- and 6-month postoperative evaluations, respectively. All patients experienced good or excellent recovery at the 3- and 6-month postoperative evaluations.

CONCLUSION

Cervicothoracic extraforaminal area may be the primary site of nerve compression in NTOS, and posterior decompression using the posterior intermuscular approach can provide efficient access to extraforaminal nerve roots.

Safety and Efficacy of Posterior Upper Rib Excision and Decompression Technique for Surgical Treatment of Neurogenic Thoracic Outlet Syndrome

BACKGROUND

There are several approaches used for surgical treatment of neurogenic thoracic outlet syndrome (n-TOS). The posterior upper rib excision and decompression technique is a novel technique that was developed and used by the author for the past 8 years. The purpose of this paper is to report clinical outcomes of patients treated with this approach.

METHODS

All patients with n-TOS operated by single surgeon from 2015 to 2023 were retrospectively analyzed. Demographic, clinical, radiologic, surgical, and postoperative data were collected and reported with emphasis on efficacy and complications. The surgical success was evaluated subjectively as excellent, good, fair, poor, and bad. Radiologic data were analyzed to assess the extent of accessory/first rib removal.

RESULTS

Eighty procedures were performed in 61 patients with a mean follow-up of 1153 (87-3048) days. The majority (60.7%) of patients were women, with 39.3% being men. In 11 cases (18%) causative factor was bone abnormality. Two patients were previously operated at another centers (3.3%). Total mean subjective improvement rate was 91.5%. More than half (55) of the patients reported "excellent" (>75%) and 6 "good" improvements (50%-75%); no fair, poor, and worse outcomes were reported. Patients reporting "good" outcome had statistically significant shorter follow-ups than the "excellent" group (P < 0.001). Complications included pleural opening, Horner syndrome, and apical hematoma, none of which were permanent.

CONCLUSIONS

The posterior upper rib excision and decompression approach provides excellent clinical outcomes in patients with n-TOS. It allows better intraoperative visualization and removal of the first rib and full decompression of the neurovascular bundle.

Surgical Anatomy of the Posterior Intermuscular Approach to the Brachial Plexus

Background: First rib resection and scalenectomy is a well-established treatment option for thoracic outlet syndrome. The posterior approach is rarely used due to extensive muscle sacrifice resulting in significant procedural morbidity. In this paper, we report the surgical anatomy of modified and less-invasive muscle-sparing posterior approach. Methods: Eleven human cadavers were used in this study. With specific care to preserve muscles' integrity, the brachial plexus was exposed by dissecting through the posterior neck musculature. A muscular triangle was found under the trapezius muscle, which provided direct access to deeper structures. Four anatomical reference points were identified to denote a 3-dimensional space enclosing proximal brachial plexus. Results: A muscular triangle was found under the trapezius muscle in all cadavers. It was bordered infero-medially by rhomboid minor, supero-medially by splenius capitis, and laterally by levator scapula muscles. The inferomedial border (rhomboid) was 55 mm (48-80), superomedial border (splenius capitis) was 60.5 mm (42-89), and the lateral border (levator scapulae) was 99 mm (60-130). A consistent vein was present inside the triangle and could be used as an anatomical landmark. The 4 reference points were C5, T1 intervertebral foramina, transverse tubercle, and scalene tubercle of the first rib. Removal of the first rib could be performed without brachial plexus retraction. The latter was exposed from neural foramina to lateral border of the first rib. Conclusions: The posterior approach provides ample space to for exposure and manipulation with the first rib and proximal brachial plexus.