**2. Surgical terminology**

While the MIS lateral interbody fusion technique is referred to as XLIF in this chapter, several other names exist for the same surgery. As of late, a general name for the surgery, lateral lumbar interbody fusion (LLIF), has emerged and increased in

popularity within the literature [14, 15]. Similarly, comparable industry-sponsored surgical techniques have been coined, including the direct lateral interbody fusion (DLIF [Medtroinic, Memphis, TN, USA]) [15]. Although the term XLIF is chosen to described the MIS lateral interbody fusion technique in this chapter, it is important for readers to understand that the same surgical technique may be referenced with other names in the larger scope of the literature.

### **3. Anatomy**

The XLIF approach is a retroperitoneal, transpsoas approach to the spinal column. The retroperitoneal space bordered by the posterior part of the transversalis fascia and the posterior parietal peritoneum, and encompasses critical organs including kidneys, adrenal glands, ureters, ascending, and descending segments of the colon, neurovascular structures including the aorta, inferior vena cava (IVC), lumbar plexus, and sympathetic trunk. In addition, spinal levels located in the posterior retroperitoneal space include T12 to the sacrum, and the psoas muscle is also located within this span.

Several muscular structures and layers are traversed during the XLIF procedure. First, the lateral abdominal muscle layers, starting superiorly from the external abdominal oblique, internal abdominal oblique, transversus abdominis, and rectus abdominis muscles, must be carefully dissected. Critical neurological structures to be mindful of during dissection include the iliohypogastric and ilioinguinal branches of L1, which supply sensation to skin over the lateral gluteal and hypogastric regions.

The psoas muscle, which is the major muscle encountered during the XLIF approach, acts as a hip abductor, lateral rotator, and flexor. The superficial part and origin of the psoas muscle begins at the T12 and L1 to L4 vertebrae, overlying the lumbar plexus. The deep part of the psoas muscle takes origin from the transverse processes of lumbar vertebrae L1 to L5, and the entire psoas muscle crosses the pelvic brim and inserts on the lesser trochanter of the femur. Of particular anatomical importance is the femoral nerve which is derived from the anterior rami of nerve roots, L2, L3 and L4. The femoral nerve is the largest branch of the lumbar plexus. The femoral nerve lies within the posterior 1/4th of the disc space at L4/5. Intraoperative nerve monitoring is helpful in reducing the risk of nerve injury [16, 17].

Furthermore, the diaphragm, and associated lumbar attachments of the right and left crura, pose an anatomical consideration during an XLIF procedure. Namely, adequate mobilization of the diaphragm around the thoracolumbar junction allows for improved disc exposure and a wider window through which a lateral XLIF corpectomy may be performed [18]. In addition, angled approaches may allow for successful XLIF completion with avoidance of the diaphragm.

## **4. Indications for XLIF**

There are multiple indications for the XLIF procedure, including [19]:


*Advancements in Minimally Invasive Lateral Interbody Fusion DOI: http://dx.doi.org/10.5772/intechopen.96208*


Oftentimes, the XLIF surgical approach is considered in patients with symptoms refractory to other treatments, including physical therapy, pain medication, and steroid injections. Additionally, specific spinal levels are best treated with the XLIF technique. High-risk patients with complicated histories may further benefit from XLIF surgery due to its minimally invasive nature. Minimal blood loss, tissue damage, and post-operative discomfort make it a viable option for complicated patients.

Furthermore, several patient conditions exclude the consideration of XLIF as a viable surgical technique. These conditions include, but are not limited to:


### **5. Procedure**

Following endotracheal anesthesia and intravenous line placement, the patient is positioned on their side in a true 90-degree lateral decubitus position [11]. The side through which the XLIF is performed is determined based on anatomical and clinical consideration. X-ray imaging is performed using a cross-table anterior–posterior (AP), and lateral technique to locate and confirm the disc of interest, and plan the surgical incision. The skin is aseptically treated and patient's spine is placed in flexion to achieve sufficient distance between the ribcage and iliac crest. Next, the pathway for instrumentation is calculated using a k-wire and lateral fluoroscopic imaging to identify the mid-position of the lumbar disc. This position is marked on the patient's lateral side at the level of the diseased disc and will serve as the working portal throughout the operation [11].

Prior to the introduction of surgical instruments, a second mark is made posterior to the working portal at the intersection of the erector spinae and abdominal oblique muscles. A 3–4 cm lateral incision is made here, large enough to allow the entry of the surgeon's index finger, which will be inserted anteriorly and advanced until the retroperitoneal space and peritoneum are identified [11]. Placement of the surgeon's finger will help protect the peritoneum, in which the visceral organs are encased, from injury while instruments are passed into and out of the working portal.

Next, the primary 3–4 cm incision is made at the mark of the working portal and the initial tubular dilator is introduced laterally, with the index finger guiding it towards the psoas muscle and away from neurovasculature and the peritoneal sac. Electromyography (EMG) is performed at the psoas muscle to steer clear of lumbar nerve roots and branches of the lumbar plexus. The psoas muscle is delicately parted between the middle and anterior third of the muscle, allowing for direct manipulation of the spine with minimal risk of damage to nervous structures and large vessels coursing anterior to the operative corridor. Additional tubular dilators are introduced to further increase the dimension of the working portal, throughout which nerve monitoring and X-ray imaging are continued to ensure safety and precision at the level of the damaged disc. Once the working portal is dilated to an appropriate diameter, a retractor is inserted and expanded in a cranio-caudal direction to the appropriate aperture [11]. The aperture of the retractor may be adjusted periodically during the operation on an as-needed basis to provide appropriate visualization and access to the spinal column. A light and camera may then be inserted and fusion may now begin.

At this point, discectomy is performed in a standard fashion and using standard surgical instruments. The diseased disc is removed with preservation of the posterior annulus, and the interbody implant is able to be accommodated in the space, resting on the lateral margins of the epiphyseal ring to increase end plate support [11]. To close the surgical site, the operative site is irrigated and hemostasis is achieved. The facial and subcutaneous layers are sutured closed, with some skin glue to close the most superficial layers. Depending on the individual patients' status, additional support including pedicle screws, plates, or rods may be inserted to stabilize the patient.

### **6. Intraoperative risks**

The XLIF surgical approach has been associated with a unique set of complications involving multiple neurovascular structures and visceral organs that may be iatrogenically damaged during soft tissue dissection or surgical instrumentation.

### **6.1 Nerve injury**

Nerve injury is among the most commonly cited complications following XLIF procedures. Recent reviews have suggested that neurological injury - specifically ipsilateral sensorimotor deficits of the groin and/or thigh - may be experienced transiently by 30–40% of patients postoperatively and permanently by 4–5% of patients [15, 20]. Structures that may be damaged during the surgical approach and instrumentation include the sympathetic chain located in the lateral aspect of vertebral body, the lumbosacral plexus containing the genitofemoral nerve located on the anterior surface of psoas muscle, and the superior hypogastric plexus.

The femoral branch of the genitofemoral nerve provides sensation to the scrotum in males, mons pubis in females, and anterior thigh in both sexes while the genital branch provides motor innervation to the cremaster muscle in males. Radiographic studies have demonstrated the close proximity of the genitofemoral nerve to the L2/L3 disc space [21] while cadaveric studies suggest anatomic variation in the course of the genitofemoral nerve in 40–50% of individuals [22]. These anatomical factors place the nerve at high risk of trauma with no zone of absolute safety during the XLIF approach [23], so surgeons must carefully navigate the surgical interval to avoid neurological injury. Furthermore, prolonged muscle retraction time over 20–40 minutes per level has been shown to greatly increase the risk of

### *Advancements in Minimally Invasive Lateral Interbody Fusion DOI: http://dx.doi.org/10.5772/intechopen.96208*

nerve injury [24], and electromyographic monitoring has been shown to reliability predict nerve dysfunction [25], highlighting the importance of reducing operative time. Newer retractor systems and more refined surgical techniques may eventually decrease the incidence of retractor-related nerve damage [26, 27].

More recent studies have also demonstrated small (1.7–4.8%) risks of femoral and obturator nerve neurapraxia and/or axonotmesis in the immediate postoperative period, though full recovery is expected within 3 months [28, 29]. Of note, femoral nerve injury is almost exclusively observed at the L4-L5 lumbar levels as anatomic studies have demonstrated that the femoral nerve lies more proximal to the ideal discectomy site at L4-L5, placing it at increased risk within that region [30, 31]. Several studies have also noted the risk of contralateral femoral nerve injury secondary to overzealous endplate removal and osteophyte distraction [32, 33].

Additional nervous structures that may be damaged intraoperatively include the ilioinguinal, iliohypogastric, and lateral femoral cutaneous nerves that course through the retroperitoneal space and lateral abdominal wall, though the literature is scarce on these complications. Retrograde ejaculation is also theoretically possible if there is damage to the superior hypogastric plexus, but there has yet to be a report of this complication following XLIF. Finally, bowel and bladder dysfunction may be a rare complication associated with lumbosacral plexus injury.

### **6.2 Vascular injury**

Vascular injury is extremely rare in XLIFs compared to approaches such as the ALIF, as great vessels such as the aorta and iliac arteries are avoided. However, dissection of segmental arteries can result in serious complications that may occur during or shortly after an XLIF procedure. In one case, a large retroperitoneal hematoma was detected five days following an L3-L4 and L4-L5 XLIF [34]. Arteriography identified active bleeding from the L2 segmentary artery as the underlying etiology. This branch was promptly embolized with fibre coils, and the patient suffered no further complications. A similar case by Santillan et al. described the development of a retroperitoneal hematoma 48 hours after an uneventful L2-L3 XLIF [35]. An angiogram showed iatrogenic arterial wall disruption of the L2 lumbar artery and a traumatic pseudoaneurysm, both of which were successfully embolized with no further sequelae. Finally, a fatal case of bleeding was reported by Assina et al. in a 50-year old patient undergoing XLIF for an L4-L5 degenerative disc [36]. Imaging showed that the anterior detachable blade tip (Scoville type retractor) had transected the right common iliac vein and was within the lumen of the left common iliac vein. Furthermore, multiple perforations along the distal IVC were noted. Despite 29 units of packed red blood cells, multiple other heroic measures, and a 4-week intensive care unit stay, the patient developed a retroperitoneal abscess with bacteremia that ultimately led to hemodynamic instability and fatal multiple organ failure secondary to septic shock.

### **6.3 Visceral structures**

Injury to non-neurovascular structures is uncommon in the setting of XLIFs and described primarily in case reports. The ureter traverses the retroperitoneal space close to XLIF surgical corridor in approximately 16% of cases [37] and may be damaged by retractors or retroperitoneal dissection particularly at the L2-L3 level [38], though no cases of urological injury have been reported on XLIFs specifically. However, ureteral complications have been reported in several patients undergoing OLIF, which utilizes a similar surgical approach to the XLIF [39–42].

Peritoneal damage following XLIF is exceedingly rare and has been described in just a few case reports. Balsano et al. reported an iatrogenic perforation of the splenic curvature of the colon following an L3-L4 and L4-L4 XLIF for degenerative disc disease [43]. The patient experienced peritonitis and underwent an exploratory laparotomy that identified the colonic perforation, and a colostomy was maintained for 3 months after which the patient fully recovered. Tormenti et al. described a cecal perforation during the transpsoas approach of an XLIF for treating adult degenerative thoracolumbar scoliosis [44]. The patient underwent an emergency exploratory laparotomy and segmental bowel resection and recovered uneventfully.

Finally, delayed incisional hernias have been described following XLIF. Plato-Bello et al. reported the development of an abdominal pseudohernia requiring surgical repair 5 months after an uneventful L3-L4 LLIF [45]. Similarly, Gundanna and Shah presented a patient who exhibited herniation of abdominal contents through the original incision site 2 years after an L3-L4 XLIF and required laparoscopic hernia repair surgery [46].

### **7. Postoperative course and recovery**

The postoperative course of XLIF surgery has been shown to minimize complications and recovery time. A prospective study of 600 patients treated with XLIF surgery revealed an average inpatient length of stay (LOS) of 1.21 days, and empirical evidence suggests that many patients may be able to ambulate within a day of the operation [47]. A similar study with a smaller cohort of 84 patients demonstrated a mean LOS of 2.6 days, with robust evidence of successful fusion on follow-up imaging [48].

On a comparable note, patient pain outcomes have been shown to significantly improve following the XLIF procedure. Improvements in two independent pain scoring metrics, the first being the visual analog scale (VAS) and the second being the Oswestry Disability Index (ODI), have been demonstrated in the literature. Specifically, a 2010 study by Youssef et al. reported a 77% and 56% increase in VAS and ODI respectively following XLIF at one-year follow-up [48]. Similarly, a 2011 study by Rodgers et al. demonstrated a 65% immediate improvement in VAS following XLIF, with 86.7% of patients satisfied with their operation at one-year follow-up [47]. The findings of both studies, with respect to improvements in patient-reported pain outcomes following XLIF, have been explored further and confirmed in several contemporary studies with similar conclusions [49, 50].

However, a major complication to consider following XLIF is graft subsidence, which threatens the long-term efficacy of the procedure. Several studies have demonstrated high rates of cage subsidence, as defined as >2 mm of cage settlement into the vertebral body, following the XLIF procedure [51, 52]. In many of these cases, 18-mm-wide and 22-mm-wide cages are used, and although previous studies have demonstrated their relative safety and efficacy, the rates of reported cage subsidence at these dimensions is suboptimal. A recent study by Lang et al. demonstrated that 26-mm-wide may reduce rates of cage subsidence while achieving excellent outcomes on both radiologic and clinical follow-up evaluation [53].

### **8. Advantages and disadvantages over similar techniques**

The XLIF is a relatively new technique that is being quickly added into the toolkits of spine surgeons around the world. However, despite the rapid adoption of this surgical approach, there are both advantages and disadvantages to this technique compared to conventional approaches such as ALIF, TLIF, PLIF, and OLIF.
