Keywords
thoracic disk herniation - interbody fusion - PEEK cage - pedicle-sparing transfacet
diskectomy - thoracic instrumentation
Background
Thoracic disk herniations (TDHs) are uncommon compared with cervical or lumbar disk
herniations and comprise ∼0.15 to 4.0% of all disk herniations.[1]
[2] Men are more likely than women to develop a TDH, and the highest prevalence is in
40- and 50-year-olds. The majority of TDHs occur at the lower thoracic levels, with
over 75% located below T8, primarily at T11–T12.[3]
[4] Similar to cervical and lumbar disk herniations, spontaneous resorption of herniated
disk material has been observed, and thus, conservative management is preferred unless
persistent axial back pain, intractable radiculopathy, and myelopathy exist.[1]
[2]
[3]
[4]
[5]
Surgical treatment is aimed primarily at alleviation of pain, decompression of neural
elements, improvement of functional status, prevention of progressive instability,
and correction of deformity.[6] Decompression with laminectomy has been associated with a high rate of morbidity.
Thus, multiple surgical techniques with anterior, lateral, and posterior approaches
have been developed and investigated.[1]
[2]
[3] Transthoracic approaches have been the mainstay of treatment,[1] especially for central, giant, and calcified TDHs due to their superior efficacy
in decompression of the ventral spinal cord.[7] However, limitations exist when respiratory comorbidities are present.[8] Posterior approaches offer a simpler and less invasive surgery than their transthoracic
or lateral extracavitary counterparts.
Pedicle-sparing transfacet approach was first described by Stillerman and colleagues
in 1995, and modified by Bransford et al, to allow for a safe access to thoracic disk
space without the need for rib excision or exploration of the pleural cavity, hence
avoiding long-term respiratory effects.[6] This procedure enables anterior column reconstruction with a bone graft or interbody
cage. Segmental fixation with pedicle screws ensures rigid fixation,[7]
[8]
[9]
[10]
[11]
[12]
[13]
[14]
[15] enables correction of the deformity, and maintains spinal stability until bony fusion
occurs.[9]
A few clinical series have reported the outcome of the pedicle-sparing transfacet
diskectomy and fusion in patients with TDH. The aim of this study was to evaluate
the outcome and complications of pedicle-sparing transfacet diskectomy and fusion
in a consecutive series of patients.
Materials and Methods
Patient Population
After approval by the institutional review board (ethics review board approval ID:
IR.SUMS.MED.REC.1400.027), medical records of our tertiary referral center were reviewed
to identify patients with TDHs who underwent pedicle-sparing transfacet thoracic diskectomy
with segmental instrumentation, between March 2015 and March 2019. Twenty-seven consecutive
patients were enrolled in this retrospective study. Patients who had undergone previous
cervical or lumbar spinal surgery, with medical and neurologic comorbidities and with
inconsistent follow-up and inadequate records, were excluded from the study. Age,
sex, presence of neurologic involvement (radiculopathy, myelopathy, and involvement
of the bladder and bowel), duration of symptoms, duration of surgery, blood loss,
and intraoperative and postoperative complications were noted. Visual Analog Scale
(VAS) for pain, Nurick grade, and the modified Japanese Orthopaedic Association (mJOA)
scoring system for thoracic myelopathy for objective assessment of functional disability
were assessed preoperatively and after 18 months of follow-up.
Surgical Technique
The same surgeon performed all the operations. An open technique was used. The surgical
technique has been described previously by Bransford et al.[6] A summary of the surgical procedure is presented below. Surgery was performed with
the patient in the prone position. Each patient received 2 g of intravenous cefazolin
about half an hour before skin incision. Intraoperative neuromonitoring increases
the surgical costs and was not routinely used. Subperiosteal dissection of the posterior
elements of the target level was performed up to the tips of the transverse processes
in a standard midline fashion. Pedicle screws were placed under fluoroscopic guidance,
and a unilateral rod (opposite to the site of facetectomy) was inserted with a slight
distraction to allow better disk space opening, diskectomy, and interbody cage placement.
A bilateral laminectomy was performed to relieve the local stenosis. Unilateral complete
facetectomy (from pedicle to pedicle) was performed for most cases, which were lateral-type
herniations ([Fig. 1]). In case of a central-type herniation, bilateral complete facetectomy and slight
tilt of the operating table are generally necessary for better visualization and access
to the disk space. The upper and lower nerve roots were preserved and need not be
sacrificed. The posterolateral annulus was incised and complete diskectomy with endplate
preparation was performed using endplate shavers, curettes, and rongeurs. Reverse-angle
curettes were used to push down the centrally located disk fragments and osteophytes.
After proper diskectomy, a polyetheretherketone (PEEK) cage, filled with local bone
graft, was inserted under C-arm fluoroscopy guidance. Finally, the other rod was inserted,
and short segmental instrumentation was performed ([Fig. 2]).
Fig. 1 Preoperative axial T2-weighted (T2W) magnetic resonance imaging of a 46-year-old
male patient with right paracentral T12/L1 disk herniation and cord compression.
Fig. 2 Intraoperative image of a T12/L1 disk herniation. Pedicle screws were inserted with
unilateral rod insertion and slight distraction to allow better disk space access.
Bilateral diskectomy was performed to relieve local stenosis. Unilateral complete
facetectomy (from pedicle to pedicle [white asterisks]) was performed. After complete diskectomy and disk space preparation, an interbody
cage was inserted. The upper and lower nerve roots were preserved.
Postoperative Care
Each patient received postoperative antibiotic therapy until their drains were removed
(usually 48 hours). Patients were mobilized early postoperatively. If necessary, a
postoperative computed tomography (CT) scan with a sagittal reconstruction to evaluate
the level of decompression, appropriate placement of instrumentation, and adequacy
of decompression was performed. Anteroposterior and lateral radiographs were requested
within 24 hours of the surgery to evaluate instrumentation. During follow-up visits,
flexion–extension radiographs and CT scan were obtained to evaluate for arthrodesis.
Results
Twenty-seven patients with symptomatic TDHs were identified. Six patients were excluded
because of previous lumbar surgery for stenosis (1 patient), previous cervical surgery
for cervical spondylotic myelopathy (1 patient), multiple sclerosis (1 patient), rheumatoid
arthritis (1 patient), and loss to follow-up (2 patients). Twenty-one individuals
were included with a mean age of 44 ± 15.7 years (range: 16–69 years). Sixteen patients
(76.2%) were males and 5 patients were females (23.8%).
All patients had single-level herniation. Disk herniation was located in 95.2% of
patients between T10 and L1. The most common location was T12–L1 (8 patients, 38.1%),
followed by T11–T12 (7 patients, 33.3%), T10–T11 (5 patients, 23.8%), and T4–T5 (1
patient, 4.8%). Disk herniation was lateral in 13 patients (61.9%) and central in
8 patients (38.0%). The herniated fragment was calcified in 10 patients (7 lateral
vs. 3 central).
The average duration of symptoms was 6.45 months (<1–60 months). All patients complained
of axial back pain. A neurologic examination revealed myelopathy and long tract signs
in 71.4% of patients (15 patients). The most common symptoms were radicular pain (16
patients, 76.1%) and lower extremity weakness (13 patients, 61.9%), followed by difficulty
walking (10 patients, 47.6%) and urinary dysfunction (10 patients, 47.6%). Five patients
complained of saddle hypesthesia (23.8%). Urinary retention was observed in 7 of 10
patients with urinary dysfunction ([Table 1]).
Table 1
Frequency of symptoms in patients
|
Symptoms/signs
|
Proportion (%)
|
Cases
|
|
Lower extremity weakness
|
61.9
|
13
|
|
Paresthesia/numbness
|
23.8
|
5
|
|
Difficulty walking
|
47.6
|
10
|
|
Urinary dysfunction
|
47.6
|
10
|
|
Radicular pain
|
76.1
|
16
|
|
Myelopathy
|
71.4
|
15
|
The average operation time was 265.9 ± 43.1 minutes (range: 180–345 minutes). The
average estimated blood loss was 680 ± 403.5 mL (100–1,500 ml; ≤1,000 mL in 81.0%
of cases; [Table 2]). No dural tears or cerebrospinal fluid (CSF) leaks were encountered in our cases.
Following surgery, most patients were transferred to the ward (90.4%); only two patients
were transferred to the intensive care unit for an overnight observation due to previous
history of cardiac disease and postanesthetic precautions. The average length of postoperative
hospital stay was 4.41 days (range: 2–7 days). Drains were kept on average for 2.7
days during hospitalization (1–5 days).
Table 2
Summary of patient demographic and clinical characteristics
|
N
|
Age/sex
|
Level
|
Operative time (min)
|
Blood loss (mL)
|
Follow-up (mo)
|
Nurick
|
mJOA
|
pain
|
|
Pre-op
|
Final
|
Pre-op
|
Final
|
Pre-op
|
Final
|
|
1
|
47/M
|
T11/T12
|
250
|
350
|
34.5
|
4
|
1
|
6
|
10
|
1
|
0
|
|
2
|
22/M
|
T12/L1
|
270
|
400
|
50.4
|
1
|
0
|
9
|
11
|
7
|
0
|
|
3
|
20/M
|
T4/T5
|
255
|
900
|
37.5
|
5
|
1
|
0
|
8
|
5
|
5
|
|
4
|
61/M
|
T10/T11
|
180
|
400
|
27
|
4
|
4
|
3
|
5
|
1
|
1
|
|
5
|
16/M
|
T11/T12
|
345
|
350
|
44.5
|
3
|
1
|
5
|
9
|
3
|
1
|
|
6
|
47/M
|
T12/L1
|
270
|
1,500
|
59.3
|
4
|
1
|
3
|
10
|
7
|
0
|
|
7
|
32/F
|
T11/T12
|
270
|
600
|
15.3
|
2
|
1
|
8
|
10
|
6
|
5
|
|
8
|
40/M
|
T12/L1
|
240
|
600
|
70.4
|
4
|
3
|
4
|
7
|
7
|
4
|
|
9
|
53/M
|
T10/T11
|
270
|
750
|
51.5
|
2
|
1
|
6
|
10
|
7
|
4
|
|
10
|
62/F
|
T10/T11
|
280
|
1,300
|
29
|
5
|
4
|
1
|
6
|
4
|
0
|
|
11
|
35/M
|
T10/T11
|
315
|
600
|
47.4
|
2
|
1
|
6
|
10
|
3
|
0
|
|
12
|
46/M
|
T11/T12
|
210
|
450
|
67
|
3
|
3
|
5
|
8
|
7
|
4
|
|
13
|
63/M
|
T11/T12
|
195
|
500
|
40.5
|
4
|
1
|
5
|
8
|
6
|
2
|
|
14
|
35/M
|
T11/T12
|
225
|
300
|
32.9
|
3
|
3
|
5
|
5
|
5
|
3
|
|
15
|
59/M
|
T10/T11
|
225
|
450
|
49.2
|
2
|
1
|
7
|
10
|
7
|
3
|
|
16
|
24/M
|
T12/L1
|
315
|
100
|
35.9
|
2
|
1
|
7
|
9
|
1
|
1
|
|
17
|
46/M
|
T11/T12
|
300
|
500
|
33.2
|
2
|
1
|
7
|
10
|
1
|
1
|
|
18
|
69/F
|
T12/L1
|
315
|
500
|
46.2
|
4
|
4
|
3
|
6
|
5
|
4
|
|
19
|
53/F
|
T12/L1
|
315
|
1,350
|
31.3
|
2
|
0
|
3
|
10
|
6
|
3
|
|
20
|
60/F
|
T12/L1
|
270
|
1,400
|
30.3
|
4
|
1
|
3
|
10
|
7
|
0
|
|
21
|
34/M
|
T12/L1
|
270
|
1,000
|
47.6
|
5
|
1
|
2
|
8
|
7
|
2
|
|
Mean
|
44 ± 15.7
|
–
|
265 ± 43.1
|
680 ± 403.5
|
41.9 ± 13.5
|
3.1 ± 1.2
|
1.6 ± 1.2
|
4.6 ± 2.3
|
8.5 ± 1.8
|
4.9 ± 2.3
|
2 ± 1.8
|
Abbreviation: mJOA, modified Japanese Orthopaedic Association.
Preoperatively, 10 patients (47.6%) had difficulty walking and were unable to walk
without help with 3 patients using a wheelchair. However, 1 to 150 days following
surgery (mean: 35.08 days), all patients could walk either independently or with minimal
help.
Preoperative axial back pain and radicular symptoms, as assessed by the VAS scores,
were improved in all patients. No neurologic deterioration was observed. The VAS scores
diminished from 4.9 ± 2.3 (range: 1–7) preoperatively to 2 ± 1.8 (range: 0–5) 18 months
after surgery (p < 0.001; [Fig. 3a]; [Table 2]). Functional disability was assessed with Nurick and mJOA criteria preoperatively
and 18 months after surgery. Both scores improved significantly 18 months after surgery.
The average mJOA score increased from 4.6 ± 2.3 to 8.5 ± 1.8 (p < 0.001), and the average Nurick grade decreased from 3.1 ± 1.2 to 1.6 ± 1.2 (p < 0.001; [Figs. 3b] & [3c]; [Table 2]). There were no cases of pseudarthrosis or hardware failure and successful fusion
was observed in all cases ([Fig. 4]).
Fig. 3 The average preoperative and final values of (a) Visual Analog Scale, (b) Nurick's grade, and (c) modified Japanese Orthopaedic Association (mJOA) score.
Fig. 4 Sagittal and coronal reconstructions of spinal T12/L1 computed tomography (CT) scan
depicting successful interbody fusion 18 months after surgery.
Discussion
TDHs have a very low incidence relative to cervical and lumbar disk disease, and controversy
still remains as to the best way to manage them.[2]
[6]
[8] Multilevel TDHs occur much less commonly than single-level herniations. Asymptomatic
and small TDHs with minimal symptoms are managed conservatively; however, surgery
management is recommended for patients with persistent axial back pain, intractable
radiculopathy, and myelopathy. In our experience, 21 patients with symptomatic TDHs
were included. All patients had single-level TDHs, and 95.2% were located between
T10 and L1 in the thoracolumbar region, with T12–L1 (38.1%) and T11–T12 (33.3%) being
the most common sites. Our findings were consistent with previous studies by Yamasaki
et al[1] (T10–T11 and T12–L1), Machino et al[14] (T11–T12), Kim et al[16] (T11–T12), Ibrahim et al[9] (T11–T12), and Krishnan et al[17] (T11–T12). The presenting neurologic symptoms and deficits of our patients were
similar to those reported in previous case series, and consisted of axial back pain,
radicular pain, difficulty walking, lower extremity weakness, myelopathy, and urinary
dysfunction.
Decompression with laminectomy alone is associated with less-than-ideal results and
major morbidity.[2]
[8] Removing disk material anterior to the thoracic spinal cord is difficult and mechanical
damage with resulting neurologic injury, such as increased paresis or paralysis, is
inevitable. Therefore, transthoracic approaches were developed for the management
of TDHs, especially calcified TDHs in patients with myelopathy. The lateral extracavitary
and the costotransversectomy approaches were originally developed for the surgery
of traumatic fractures or Pott's disease, and intended to overcome the limitations
of posterior and posterolateral approaches.[2]
[6]
[8] Although these approaches provide an excellent exposure of the ventral aspect of
the spinal cord, these procedures are limited by high complication rates, considerable
blood loss, and long postoperative hospital stay. Mulier and Debois reported a higher
pulmonary complication rate of 7% following transthoracic approach versus 0% in those
treated with a posterolateral approach, and concluded that a posterolateral approach
was a reasonable option in patients with pulmonary comorbidities. In our series of
21 cases, we had no pulmonary complications.[2]
Posterior approaches allow for a simpler and less invasive surgery than their transthoracic
or lateral extracavitary counterparts. These procedures provide access to ventral
neural decompression with relatively low morbidity, have improved clinical outcomes,
and require less specialized facilities than anterior approaches. Pedicle-sparing
transfacet approach was first described by Stillerman and colleagues in 1995, and
modified by Bransford et al.[6] The modified approach includes complete uni- or bilateral facetectomies (from pedicle
to pedicle), and provides adequate access to the thoracic intervertebral disk space.
However, a bilateral transfacet approach greatly augments visualization of the ventral
thecal sac and ensures a safe and complete decompression.
The need for a fusion following thoracic diskectomy remains controversial. In the
absence of preexisting deformity, symptomatic spinal instability following either
anterior or posterior procedures is a rare occurrence. Patients with previous laminectomy,
severe thoracic axial pain, kyphotic deformity, osteoporosis, Scheuermann's disease,
multilevel diskectomies, and diskectomy at the thoracolumbar area may need fusion
to prevent further deterioration.[18]
[19] However, the final decision regarding the need for fusion rests with the surgeon.
In our experience, we performed unilateral complete facetectomies for lateral-type
herniations and bilateral complete facetectomies for central-type herniations with
segmental instrumentation. We agree with other authors that segmental fusion prevents
long-term progressive instability, minimizes postoperative axial back pain, and facilitates
early patient mobilization.[6] No long-term complications of instrumentation (hardware failure or malpositioning)
occurred in this study. To date, a few clinical series have been published to report
the outcome of this procedure in patients with TDH.
Consistent with previous reports by Machino et al[14] and Krishnan et al,[17] arthrodesis was achieved in all patients. Our findings demonstrate that the pedicle-sparing
transfacet approach, when combined with a transforaminal interbody and segmental fusion,
offers a high fusion rate and good postoperative stability.
The goal of any surgical procedure is to reduce patients' pain, improve their functional
status, and, ultimately, improve patients' quality of life. In our case series, no
postoperative neurologic deterioration was observed. The VAS scores diminished and
the the functional status, as assessed with Nurick and mJOA criteria, significantly
improved 18 months after surgery. All patients reported significant improvement in
their quality of life. These findings were consistent with previous reports in the
literature.
The most common complications reported in previous reports were postoperative infections
and CSF leaks. No major complications such as surgical site infection, CSF leak, wrong-level
surgery, and pedicle screw requiring revision were observed in our case series of
21 patients.
We acknowledge that the current study presents a small number of successfully treated
central calcified TDHs, and the limitations of posterior techniques in providing adequate
ventral access for these cases should not be underestimated. A relatively small cohort
size derived from a single institution and the retrospective design of the study were
our major limitations. Although the majority of patients were referred to our center,
there were similarities between our surgically treated patients and patients in previous
studies regarding outcome and distribution of TDHs. Future trials with bigger sample
sizes are recommended.
Conclusion
The current series reports excellent clinical outcome with the transfacet approach
and provides greater evidence that this approach can be applied to a much broader
morphologic and anatomic range of TDHs. Based on previous reports and our findings,
pedicle-sparing transfacet thoracic diskectomy, combined with transforaminal interbody
and segmental fusion, offers an acceptable surgical approach in patients with symptomatic
TDH with favorable clinical outcome and few complications.
