Southern California Orthopedic Institute, UCLA affiliate, Van Nuys, CA, USA.
Clin Orthop Relat Res. 2021 Oct 1;479(10):2323-2331. doi: 10.1097/CORR.0000000000001779.
Traditional total shoulder arthroplasty is performed through the deltopectoral approach and includes subscapularis release and repair. Subscapularis nonhealing or dysfunction may leave patients with persistent pain, impairment, and instability. Alternative approaches that spare the subscapularis include rotator interval and posterior shoulder approaches; however, to our knowledge, a cadaveric study describing pertinent surgical anatomy for a posterior shoulder approach regarding shoulder arthroplasty has not been performed.
QUESTIONS/PURPOSES: (1) What are the distances from important neurologic structures of the shoulder for arthroplasty through a posterior approach? (2) What surgical landmarks can help identify the internervous interval between the infraspinatus and teres minor?
Twelve hemitorso cadaver specimens with intact rotator cuffs were dissected to study posterior shoulder anatomy regarding posterior shoulder arthroplasty. The median (range) age of the specimens was 79 years (55 to 92). Six of the 12 specimens were right-hand dominant, and 10 specimens were male. Cadaver height was a median 171 cm (155 to 191) and weight was a median of 68 kg (59 to 125). A posterior deltoid split and internervous approach between the infraspinatus and teres minor were used. A posterior T capsulotomy was performed. The distances to important neurologic structures were measured with an electronic caliper and provided in median (range) distances in millimeters. Although not as meaningful as distance ratios accounting for a specimen's body size, neurologic distances in millimeters are surgically practical and provide intraoperative usefulness. Surgical landmarks that can help identify the infraspinatus and teres minor plane were noted. Practical visual and tactile cues between the infraspinatus and teres minor were identified. Posterior rotator cuff tendon morphologies and widths were recorded.
The closest important neurologic structure was the axillary nerve, measuring a median (range) 17 mm (9 to 19) from the inferior glenoid rim while the infraspinatus branch of the suprascapular nerve measured 21 mm (15 to 36) from the posterior glenoid rim. The axillary nerve measured 84 mm (70 to 97) from the posterior tip of the acromion in the deltoid split. Three surgical landmarks were helpful for identifying the plane between the infraspinatus and teres minor in all 12 specimens: (1) identifying the triangular teres minor tendon insertion, (2) medial palpation identifying the low point between the prominent muscle bellies of the infraspinatus and teres minor, and (3) identifying the distinct and prominent teres minor tubercle, which is well localized and palpable.
A major benefit of the posterior approach for shoulder arthroplasty is subscapularis preservation. Multiple practical surgical cues are consistently present and can help identify the infraspinatus and teres minor interval. We did not find the presence of fat stripes to be helpful. The suprascapular nerve is in proximity to posterior surgical dissection and differs from the deltopectoral approach. This is an important distinction from an anterior approach and requires care with dissection. Future studies are necessary to assess iatrogenic risk to the posterior rotator cuff and external rotation strength. This may entail intraoperative nerve conduction studies of the posterior rotator cuff and clinical studies assessing external rotation strength.
Studying posterior shoulder anatomy is an initial first step to assessing the feasibility of the posterior approach for anatomic shoulder arthroplasty. Additional studies assessing the degree of glenohumeral exposure and possible iatrogenic posterior rotator cuff injury are necessary. Because of the proximity of neurologic structures, it is recommended that surgeons not perform this technique until sufficient evidence indicates that it is equivalent or superior to standard anterior approach total shoulder arthroplasty. After such evidence is available, proper training will be necessary to ensure safe use of the posterior shoulder approach.
传统的全肩关节置换术通过三角肌胸大肌入路进行,包括肩胛下肌的切开和修复。肩胛下肌不愈合或功能障碍可导致患者持续疼痛、功能障碍和不稳定。包括旋转间隔和后肩关节入路在内的替代方法可以保留肩胛下肌;然而,据我们所知,尚未进行关于肩关节置换的后肩关节入路相关手术解剖的尸体研究。
问题/目的:(1) 通过后入路进行关节置换时,重要的肩部神经结构的距离是多少?(2) 哪些手术标志可以帮助识别冈下肌和小圆肌之间的神经间隙?
对 12 具完整肩袖的半侧尸体标本进行解剖,研究后肩关节置换的后肩关节解剖。标本的平均(范围)年龄为 79 岁(55 岁至 92 岁)。其中 6 例为右手优势,10 例为男性。尸体身高中位数为 171 厘米(155 至 191),体重中位数为 68 公斤(59 至 125)。采用三角肌后部分离和冈下肌与小圆肌之间的神经间隙入路。行后盂肱关节囊切开术。用电子卡尺测量重要神经结构的距离,并以毫米为单位提供中位数(范围)距离。尽管距离比考虑标本体型的距离更有意义,但毫米级的神经距离在手术上是实用的,并提供术中有用性。记录了有助于识别冈下肌和小圆肌平面的手术标志。确定了冈下肌和小圆肌之间的实际视觉和触觉线索。记录了后肩袖肌腱的形态和宽度。
最重要的神经结构是腋神经,从后关节盂下缘测量,距离为 17 毫米(9 至 19),而肩胛上神经的冈下肌分支距离后关节盂缘 21 毫米(15 至 36)。腋神经在三角肌劈开处距肩峰后缘 84 毫米(70 至 97)。在所有 12 个标本中,有 3 个手术标志有助于识别冈下肌和小圆肌之间的平面:(1)识别三角形小圆肌肌腱插入点,(2)内侧触诊确定冈下肌和小圆肌突出肌腹之间的最低点,(3)确定明显而突出的小圆肌结节,该结节位置明确且易于触诊。
肩关节置换后入路的主要优点是保留肩胛下肌。有许多实际的手术线索始终存在,可以帮助识别冈下肌和小圆肌间隔。我们没有发现脂肪条纹有帮助。肩胛上神经靠近后入路的手术部位,与三角肌胸大肌入路不同。这与前入路有重要区别,需要注意分离。需要进一步的研究来评估对后肩袖的医源性损伤和外旋力量。这可能需要对后肩袖进行术中神经传导研究和评估外旋力量的临床研究。
研究后肩关节解剖是评估解剖性肩关节置换后入路可行性的第一步。还需要进一步研究评估盂肱关节的暴露程度和可能的医源性后肩袖损伤。由于神经结构的接近性,建议在有足够的证据表明该技术与标准的前侧入路全肩关节置换术等效或更优之前,外科医生不要进行这种技术。在有了这样的证据之后,需要进行适当的培训,以确保安全使用后肩关节入路。
