Spinal muscular atrophy (SMA) is a genetic disorder that causes degeneration of anterior horn cells, leading to muscle weakness and atrophy. In 2017, Health Canada approved intrathecal nusinersen to prevent the degeneration of motor neurons in the spinal cord. Repetitive intrathecal injections of nusinersen may be challenging in patients with spinal deformities, particularly if the patient has undergone scoliosis surgery or if the patient requires an anesthetic with every injection.
Inspired by others who have successfully implanted subcutaneous intrathecal catheter and port systems, Reference Strauss, Carson and Brigatti1,Reference Iannaccone, Paul, Castro, Weprin and Swift2,Reference Shashi, Stone, Berde and Padua3 the following technique was offered to six patients in an effort to facilitate repetitive nusinersen administration.
Two Health Canada-approved devices were combined to create each implant system: 1) an intrathecal catheter designed for intrathecal baclofen pumps and 2) an implantable subcutaneous port designed for intravascular medication administration.
The surgical technique was similar for every patient. An incision is opened on the anterior chest wall to implant the port. The port used in our cohort was a Medcomp 5-French MRCTI5084SM. The location of the implants is individualized to suit each patient’s anatomy. Placement of the intraspinal catheter is done in a manner analogous to the placement of an intrathecal baclofen pump catheter. In a situation where it is decided to place the catheter in the thoracic or cervical spine, a hemi-laminectomy is performed in order to expose the dura at that level and place the intraspinal catheter under direct vision with countertraction on the dura in order to minimize the risk of spinal cord injury during catheter placement. The Medcomp 5-French catheter is tunneled from the anterior chest wall incision to the posterior spinal incision. The anterior chest was chosen as the site for the port in this case series in an effort to maximize comfort for the patient and to allow the possibility of accessing the port while the patient is seated in their wheelchair. Both implants are then connected and secured to fascia at the posterior spinal incision site. The port is then accessed. Successful aspiration of cerebrospinal fluid (CSF) without resistance confirms patency of the system, which is ready for medication injection at this point if so desired.
Of our six patients, three experienced complications, which we will outline below.
A 26-year-old female with SMA type 2 (Case 1). She is a wheelchair ambulator and has previously undergone scoliosis surgery. Her scoliosis surgery was done in 2003 at the age of 10. Because of her scoliosis construct with sublaminar wires extending from the upper thoracic spine down to the pelvis, it was decided to place her intrathecal catheter in the cervical spine. Ten days after the operation, the patient developed a significant wound seroma, with serosanguinous drainage from the port (anterior chest wall) surgical site. The patient was re-admitted and the incision site was aspirated for cultures, which came back negative. She was started on intravenous cefazolin for 2 days then switched to oral cephalexin for 5 days. The swelling around the port subsided, and eventually went on to heal appropriately.
A 3-year-old female with SMA type 1 who was diagnosed at the age of 5 months (Case II). An intrathecal catheter and port system were implanted, in an effort to facilitate the repeated injections as she was requiring anesthesia with every lumbar puncture. She did not have scoliosis hardware, therefore it was decided to place the intrathecal catheter in her lumbar spine. Four weeks post-op, it was found that there was no CSF return when the port was accessed, and there was high resistance to injection. During that visit, the patient received her nusinersen dose through a lumbar puncture. X-rays subsequently revealed that her intrathecal catheter had pulled out from her spine. The catheter was curled up in the subcutaneous tissues of the lumbar spine, outside of the thecal sac. The patient returned to the operating room in order to replace and secure the intrathecal catheter correctly. The system now remains in good working order more than 3 years later.
A 19-year-old male who was diagnosed with SMA type 3 when he was 4 years old (Case III). A thoracic intrathecal catheter and port were placed since he had previously undergone scoliosis surgery with a pedicle screw and rod construct. Two weeks later, the patient was seen for his second nusinersen injection. The port was accessed and the drug was administrated without resistance; however, there was no CSF return upon withdrawal raising questions regarding the integrity of the system. A CT myelogram was therefore carried out, confirming a patent system.
All implant procedures in this case series were performed between May 2019 and July 2020. Minor complications (one of these requiring a return to the OR) were encountered early post-op as described above. No further complications have been observed since, and all patients continue to receive their nusinersen therapy via their implants to this day.
Intrathecal administration of nusinersen can be difficult in patients with spinal deformities and those needing anesthesia for its administration. Injecting the drug through an implanted subcutaneous port and intrathecal catheter is an alternative to repeated lumbar punctures. This technique avoids the need for fluoroscopically guided lumbar or C1–C2 punctures in patients who have undergone scoliosis surgery and avoids the need for anesthesia in younger patients who would otherwise require sedation. We hope that a medical device manufacturer will one day offer an implant that will consist of a catheter and port that can be anchored securely to the patient’s anatomy, allowing repeated access to the intrathecal space. This system could resemble current intrathecal pump systems, without the need for a pump.
This case series illustrates the benefits and pitfalls that may be associated with these implants. Catheters may be placed in the cervical, thoracic, or lumbar spine, depending on the patient’s anatomy.
Disclosures
Jordan Sheriko and P. Daniel McNeely received honoraria from Biogen Canada Inc. The remaining authors have no conflicts of interest to declare.
Statement of authorship
A.B: Chart review and writing the manuscript.
D.M: Patient selection, consent and reviewing the manuscript.
J.S: Patient selection and reviewing manuscript.
C.R: Reviewing the manuscript.