Angle of approach to the superior rotator cuff of arthroscopic instruments depends on the acromial morphology: an experimental study in 3D printed human shoulders

Portal placement is crucial in shoulder arthroscopy not only to protect the neurovascular structures but also for good visualization and range of motion of surgical devices, such as tendon perforators [1‐5]. It appears advantageous to plan preoperatively which portals to use and what instruments to choose particularly in technically more demanding procedures such as rotator cuff repair [6]. However, we made the observation that in arthroscopic shoulder surgery, the subacromial space is not equally easy to access in all patients, even though the portals are usually placed in the same manner relative to the bony landmarks. We hypothesize that different shapes and orientations of the acromion as described in various anatomical studies [7‐10] might be a determining factor for the freedom of instrument positioning and mobility. In order to handle and penetrate a torn rotator cuff for suture placement, the suture-passing instrument used should preferably pass the tendon in a sufficiently steep angle which also allows to integrate different layers of a delaminated tendon tear. If the angle of approach with an instrument such as tendon perforators is too small, the instrument may only scratch the surface and the point of entry and exit of the tendon and the direction of perforation is very hard to control.

However, to the best of our knowledge, no study has investigated the influence of the size and the shape of the acromion as the determining anatomical landmark on the range of motion of arthroscopic instruments in the subacromial space. We hypothesized that the acromial shape and orientation have a significant influence on where arthroscopic instruments such as tendon perforators may enter the subacromial space and consequently on their freedom of motion of there. In particular, we hypothesized that a steep and dorsally orientated acromion will reduce the possible angle of approach to the rotator cuff from the posterior portals, while a small acromion provides easy access to the rotator cuff from the majority of the portals. The purpose of this study was to analyze the relation between different acromial shapes and the freedom of movement of arthroscopic instruments relative to the rotator cuff. A further goal is to predict a possible difficulty on the range of motion on standard radiographs allowing to plan which portal should be used for which acromial shape when the superior rotator cuff is addressed.

Preoperative planning is an important factor for consistent quality of surgical procedures, which also applies to arthroscopy. The experimental results of this study confirm our hypothesis that conventional preoperative imaging may be of considerable help in the planning of arthroscopic portal placement. The acromial size and position determines the possible placement of portals and therefore the freedom of mobility that surgical instruments will find in the subacromial space. As expected, the anterior supraspinatus tendon was very difficult to reach from the most posterior (“joint line”) portal and vice versa the posterior infraspinatus difficult to reach from the most anterior (“anterior edge”) portal, independent from the acromial shape. The highest variability of the angles of approach that a surgical instrument will find relative to the tendon surface was at the posterior supraspinatus tendon (perforation point 3). This was most evident from the posterior edge portal with a range of 0–77°. Interestingly, from this portal, the posterior supraspinatus and entire infraspinatus were best accessible, also better than from the more posterior joint line portal. The most versatile access to the rotator cuff could be achieved through the intermediate (lateral) portal with positive angles of approach for the entire width of the supraspinatus and infraspinatus in most of the shoulders. If the anterior supraspinatus is to be addressed, the best mobility of the surgical instrument will be achieved through the anterior edge portal and to a lesser extent also through the intermediate portal.

A new finding in this article is that the portal position and therefore subacromial maneuverability is strongly determined by the shape of the acromion. A large (big GAA) and a steep (small SBAA) acromion make the arthroscopy more difficult due to smaller angles of approach. However, a small and flat acromion, with small GAA and CSA and big SBAA allows for a larger angle of approach. This is especially the case for the joint line portal and the posterior edge portal as visualized in Figs. 6 and 7. For these two portals, the GAA and SBAA appear to be more important than the CSA. On the other hand, for the intermediate and anterior portal, the CSA appears to be the determining factor. This is not surprising, as the CSA is measured in the AP radiograph and is therefore a value for the lateral expansion of the acromion.

Baechler et al. described that 25° (corresponding to 115° supraglenoid tubercle angle) is desirable as a minimum arc of vertical clearance for arthroscopic instrumentation of the superior glenoid through lateral portals [14]. This requirement could be most reliably achieved through the anterior edge portal, relatively independent of the acromial shape (Fig. 5).

However, there are some limitations of this study. The most important confounding factor is that the surgeon has the intraoperative possibility to adapt the shoulder distraction, abduction, flexion, and rotation, which is an important factor to adapt to anatomical variations. Further, the possible combinations of the analyzed anatomical variables cannot be fully represented by the used samples. Other variables such as soft tissue coverage, tendon thickness, medial location of a possible tear, and mobility of the tendon could also not be reproduced in the used technique. It may be assumed that a large soft tissue coverage even potentiates the observed osseous restrictions on instrument maneuverability. Finally, the optimal angle of approach will also be determined by the type of surgical instrument used. Despite these limitations, however, the hypothesized relevance of anatomical variations of the acromion for the placement of arthroscopic portals and the consequent influence on surgical maneuverability could unambiguously be demonstrated and should be further assessed in the intraoperative clinical setting.

This study shows for the first time that depending on the acromial shape, defined points on the rotator cuff may either be well within reach or inaccessible through the same portal. As hypothesized, a small (small GAA) and flat (big SBAA) acromion provide an easier approach to the rotator cuff from almost every portal, while a larger acromion results in a more challenging procedure, especially from the posterior portals. Analysis of the lateral (Neer) view gives an estimation for the posterior acromial extension and therefore for the position of posterior and posterolateral portals. This information may be useful for the careful planning of portals and instruments in arthroscopy.