A novel technique for stabilising sacroiliac joint dislocation using spinal instrumentation: technical notes and clinical outcomes

A titanium alloy-based spinal instrumentation (USS II Ilio-Sacral, Modular System for Stable Fixation in the Sacrum and Ilium, Depuy Synthes Co., Zuchwil, Switzerland) was used. The sacral and iliac USS II dual-core cancellous polyaxial screws have an outer diameter of 6.2–8.0 mm and length of 30–80 mm (length is 65 mm only in a screw with an outer diameter of 6.2 mm). The inner diameters of the screws correspond to the cancellous and cortical bone thickness, which increase the pull-out strength. Rod-bridging screws have two diameters (5.0 and 6.0 mm). The instrument is equipped with a polyaxial 3-D head, sleeve, and nuts to connect the rod and screw, enabling the assembly of a side-loading polyaxial screw system, a combination of the screw head and sleeve that retains the rod as if it is wrapped. Thus, the force loaded on the nut is reduced, resulting in a firm construction. In addition, the rod can be easily set because the head has circumferential mobility of ± 25°. We utilised the implants of the EXPEDIUM VERSE spinal system (Depuy Synthes Co., Zuchwil, Switzerland) for the last four cases. Differences between the USS II Ilio-Sacral and EXPEDIUM VERSE spinal system are that in the latter, the screws are cannulated (Verse cannulated CFX screws) and have size variations. The rod has a fixed diameter of 5.5 cm, and it is stabilised by a top-loading system. Moreover, the most significant differences are in the structures and properties of the screw heads and set screws. In the EXPEDIUM VERSE spinal system, screw heads are available with favoured angles and can be selected from a maximum of 50° to a minimum of 20°, and the set screws, called the “correction keys”, can lock the angles of the heads. At this point, the rod slides in the screw heads, and compression is applied along the rod between the screws so that the implant can be stabilised using the locking properties. The unitised set screws can easily achieve the final locking if no compression is necessary.

Of the patients with pelvic ring fractures who underwent surgery between May 2012 and December 2020 at two medical facilities, ASIS was performed in 11 patients for sacroiliac joint fracture–dislocation or sacroiliac joint dislocation.

For ASIS, the patient was placed in a supine position on a radiolucent operating table with access to a C-arm fluoroscopic unit under the table for anteroposterior, inlet, and outlet projections. The surgical field and the lower limb on the affected side were disinfected and draped to prepare for manual or direct traction during surgery.

A skin incision of approximately 12 cm was made along the iliac crest starting at the medial point of the anterior superior iliac spine. This is the first window in the ilioinguinal approach. The external oblique muscle was elevated off and over the iliac crest. After entering the iliac fossa, the iliacus muscle was elevated off the inner table using a Cobb elevator, and the psoas muscle was elevated over the iliac brim. Then, the abdominal and pelvic contents were retracted. Feeding vessels to the iliopsoas muscles located 1–2 cm lateral to the anterior line of the sacroiliac joint, which is at the iliac fossa, were ligated. Bleeding was controlled using bone wax if these vessels were injured and occluded by thrombosis.

The sacroiliac joint is covered by the anterior sacroiliac ligament and appears to bulge, making it easy to identify. The injured ligaments were excised to confirm the reduction of the sacroiliac joint. The methods achieved better visualisation of the area extending from the sacroiliac joint or iliac fossa to the proximal side of the arcuate line. First, a large retractor was inserted at the medial side of the sacroiliac joint, and then the iliacus was retracted medially to gain direct visualisation of the sacral ala after carefully securing the L5 nerve root. Second, an intestinal spatula was inserted into the proximal side of the arcuate line, locating the lesser pelvis just above the greater sciatic notch, with the bone serving as a fulcrum, after retracting the skin medially and distally.

Reduction of the dislocated ilium was achieved by a combination of several techniques. A Schanz pin with a diameter of 5 mm was inserted into the iliac crest using the joy-stick manoeuvre (Fig. 1). A ball-point spike pusher to push the ilium and distraction of the lower leg are the choices for reducing rotational and vertical displacements.

The fifth lumbar nerve root was securely retracted, and the entry point of the sacral screw was made at the medial side of the sacroiliac joint and the centre of the lateral part of the sacrum. Insertion points for iliac and sacral screws are described in Fig. 2a, b. Subsequently, a probe was inserted in an appropriate direction through the entry point. While inserting the probe, an inlet oblique view was used to confirm that the probe tip did not to go outside the sacrum and passed through the sacroiliac joint (Fig. 3a). The probe was maintained parallel to the sacroiliac joint and on the lateral side of the sacral foramina in the anteroposterior and outlet views. An outlet oblique view was obtained by tilting the C-arm to display the sacroiliac joint more clearly, which was more useful in deciding the precise insertion route (Fig. 3b). When the probe was advanced into the sacrum, the surgeon ensured the ideal insertion direction by feeling the long screw using the hand. The screw insertion route was then confirmed as safely secure using a pedicle sounder, and a screw with a 70 mm diameter was inserted.

Next, the insertion point and direction of the iliac screws were determined. The entry point was 2 cm lateral and 1 cm distal to the anterior point of the sacroiliac joint, and the goal of the screw was to reach the ischial spine or ischial tuberosity, following a direction similar to that of the posterior column screw for acetabular fractures (Fig. 2b). The screw was inserted carefully to avoid entry into the hip joint. The insertion process was the same as that performed for the sacral screw. The screw heads were bridged using a rod. In the USS II Ilio-Sacral system, rod bending and connection using a side-loading polyaxial system are needed. In the EXPEDIUM VERSE spinal system, rod connection is easier because of the top-loading polyaxial system, which allows attachment of a rod on the groove of the screw head (Fig. 4).

If a reduction force from the implants is needed to fix the sacroiliac joint dislocation, the direction of the iliac screw should be along the sacral screw and parallel to the sacroiliac joint, heading toward the posterior superior iliac spine, and the screw should be as long as possible. The head of the sacral screw and the rod were attached first, followed by compression between the screws along the rod with a compressor, and finally, the iliac screw and rod were locked (Fig. 5).

The median age was 63 years (interquartile range [IQR]: 26–74 years), and five and six patients were men and women, respectively. The cause of injury was a fall from a height in two patients, traffic accident in six, compression by a heavy item in one, and fall from a standing position in two. The fracture type was AO/OTA class 61B1.1 in two patients, B2.2 in five, B2.3 in two, and C1.2 in two.

All procedures were performed as planned after confirming that bleeding had stopped based on the vital signs and laboratory data. The median operative time was 195 min (IQR: 163–239 min), the median blood loss was 570 g (IQR: 381–945 g), 8 patients (72.3%) required blood transfusion, and the median volume of blood transfusion was 560 mL of red cell concentrate (IQR: 0–560 mL) and 0 cm³ of fresh frozen plasma (IQR, 0–480 mL). Inserted sacral and iliac screws were of diameter 6.0–8.0 mm and 6.2–8.0 mm and length 50–70 mm and 40–80 mm, respectively. Two patients underwent other fracture operations (lower leg fracture, 1; distal radius fracture, 1) along with ASIS. Clinical courses were surveyed for all patients. The median follow-up period was 12 months (IQR: 9–44 months), during which bone union was achieved, and no marked loss of reduction occurred in all cases. Deep infection occurred in one patient and was treated with lavage and debridement. The Majeed pelvic score [7] is a patient-reported outcome obtained by evaluating five areas: pain (30 points), work (20 points), sitting (10 points), sexual intercourse (4 points), and standing (36 points). At the final follow-up, the median Majeed score was 85 (IQR: 79–90) out of 96, excluding the sexual intercourse score. Patient demographic data and details of the operations and outcomes are summarised in Table 1.