Outcomes of Non-Operative Management for Pseudarthrosis after Pedicle Subtraction Osteotomies at Minimum 5 Years Follow-Up.

OBJECTIVE: Minimal data exist regarding non-operative management of suspected pseudarthrosis after pedicle subtraction osteotomy (PSO). This study reports radiographic and clinical outcomes of non-operative management for post-PSO pseudarthrosis at a minimum 5 years post-detection.
METHODS: Nineteen consecutive patients with implant breakage indicating probable pseudarthrosis after PSO surgery (13 women/ six men; mean age at surgery, 58 years) without severe pain and disability were treated with non-operative management (mean follow-up, 5.8 years; range, 5-10 years). Non-operative management included medication, intermittent brace wearing and avoidance of excessive back strain. Radiographic and clinical outcomes analysis was performed.
RESULTS: Sagittal vertical axis (SVA), proximal junctional angle, thoracic kyphosis achieved by a PSO were maintained after detection of pseudarthrosis through ultimate follow-up. Lumbar lordosis and PSO angle decreased at final follow-up. There was no significant change in Oswestry Disability Index (ODI) scores and Scoliosis Research Society (SRS) total score, or subscales of pain, self-image, function, satisfaction and mental health between detection of pseudarthrosis and ultimate follow-up. SVA greater than 11 cm showed poorer ODI and SRS total score, as well as the pain, self-image, and function subscales (p<0.05).
CONCLUSION: Non-operative management of implant failure of probable pseudarthrosis after PSO offers acceptable outcomes even at 5 years after detection of implant breakage, provided SVA is maintained. As SVA increased, outcome scores decreased in this patient population.

INTRODUCTION

Pedicle subtraction osteotomy (PSO) may be necessary to achieve correction of spinal deformity in cases with severe, rigid curves and may be employed to help restore both coronal and sagittal spinopelvic alignment [10]. Although PSO procedures are associated with greater correction of adult spinal deformity, these procedure are associated with significant risk, with complications described in 21% to 34% of patients [6,13,17,23-25].

Pseudarthrosis is one of the most common complications and also one of the most common indications for revision surgery after PSO [1-3,6,18,19]. Kim et al. [15] reported that the rate of pseudarthrosis after PSO was surprisingly high at 29%. However, not all of these pseudarthrosis patients have severe clinical discomforts meriting revision surgery [6,14,21,22]. Therefore, it is often difficult to predict which patients are likely to improve clinically and which will be functionally more compromised over time after detection of pseudarthrosis.

Several studies have previously demonstrated that revision rates after PSO range from 12% to 23% [1,3,7,12,15,18,19]. Most studies on PSO outcomes have typically reported revision rates up to 2 years of follow-up. Revision procedures for non-mechanical complications such as neurologic deficit, infection, and wound dehiscence typically occur within the first year after index surgery. However, revision surgery for mechanical complication such as pseudarthrosis, implant failure, junctional failure, and loss/lack of correction have been reported to occur between 2 years and 5 years as well, beyond the reported follow-up of most PSO studies [14].

To the best of our knowledge, there are no published reports on the results of non-operative management for pseudarthrosis after PSO with long-term follow-up. The specific aim of this study was to report radiographic and clinical outcomes at a minimum of 5 years after detection for non-operative management and to analyze the characteristics of probable pseudarthrosis after PSO.

MATERIALS AND METHODS

Patient population

After Institutional Review Board approval (Ulsan University Hospital 2018-09-016), a retrospective radiographic and clinical analysis was conducted of patients who had undergone PSO for spinal deformity between 1999 and 2009. Data was collected and analyzed by an independent senior spine surgeon not involved in the surgical treatment. Of 335 patients who underwent PSO, pseudarthrosis was found in 32 patients (9.6%). Non-operative management was initially attempted in patients with pseudarthrosis. Revision surgery was done in nine patients : five cases were due to patient’s severe pain and four cases were due to severe deformity. Twenty-three patients who had non-operative management (observation, medication, avoidance of excessive back strain, and intermittent brace wearing) for pseudarthrosis as a complication after a PSO were identified. However, four patients were lost to follow-up before the 5-year follow-up period. Nineteen patients had complete medical records, including preoperative and postoperative radiographic data, operative data, hospital data, and a minimum 5-year follow-up. Demographic data and complications were recorded. Radiographs and patient-reported outcome questionnaires were done prospectively and then data that had been collected was reviewed retrospectively.

Radiographic measurements

Standing 36-inch long cassette anteroposterior (AP) and lateral radiographs of the spine were measured preoperatively, immediate postoperatively, and at ultimate follow-up with a minimum 5-year. All radiographic measurements were performed by one author, an attending spine surgeon who was not part of the surgical team.

Radiographic criteria used to define pseudarthrosis were as follows : 1) loss of fixation, such as implant breakage, dislodgment of rods or hooks, or a lucent halo around a pedicle screw; 2) lack of bridging bone across motion segments on computed tomography; 3) subsequent disc space collapse at the distally instrumented motion segment compared with the findings at the first postoperative visit; 4) any motion on side bending or flexion/extension plain radiographs; and 5) progression of the deformity clinically or radiographically [14].

Proximal junctional angle (PJA) was defined using the caudal endplate of the upper instrumented vertebra (UIV) and the cephalad endplate of the vertebra 2 segments proximal to the UIV (UIV+2) and pedicle subtraction osteotomy angle (PSOA) was defined as the angle between the caudal endplate of 1 supra-adjacent vertebra above the osteotomy site and the caudal endplate of 1 infra-adjacent vertebra below the osteotomy site. The Cobb method was used to measure thoracic kyphosis (TK : T5–T12), thoracolumbar kyphosis (TLK : T10– L2), and lumbar lordosis (LL : T12–S1) [5]. Standard spinopelvic parameters were recorded, as was sagittal vertical axis (SVA).

Patient-reported outcomes

All clinical questionnaires were collected prospectively. Oswestry Disability Index (ODI) [8] and Scoliosis Research Society-30 (SRS) [11] patient-reported outcomes were collected preoperatively and at each follow-up visit. Total SRS scores were converted to a 100-point scale. In addition, pain, self-image, function, satisfaction, and mental health domain scores were evaluated.

Statistical analysis

Data were analyzed using SPSS ver. 10.0 software (SPSS Inc., Chicago, IL, USA). Statistical analysis included descriptive statistics, means, standard deviation, and ranges. For most variables for which data were collected before and after surgery, paired t tests were used to determine whether there was a significant change between time points. The Mann-Whitney U test was used to assess the difference of continuous measures across groups. A p value <0.05 was considered significant.

RESULTS

Patient data

Patient demographics information including age at time of surgery, sex, mean follow-up period from defection of pseudarthrosis, and pre-PSO diagnosis is presented in Table 1.

Table 1.

Demographic data

	Value
Gender	13 women; 6 men
Age at operation (years)	58.0±9.9 (39.5–69.0)
BMI (kg/m2)	26.4±6.1 (20.4–46.0)
Total follow-up (years)	8.5±2.3 (6.0–12.6)
Detection of pseudarthrosis to ultimate F/U (years)	5.8 ±1.3 (5–10)
Initial diagnosis	8 degenerative lumbar kyphoscoliosis
	7 adult idiopathic scoliosis
	3 postoperative state of Idiopathic scoliosis
	1 postoperative state of burst fracture
Level of PSO	4 at L2, 12 at L3, 3 at L4
No. of fused vertebrae	10.6±3.6 (5–16)
Comorbidity	5 patients (0 smokers; 6 comorbidities)
Common radiographic findings	Rod breakage (n=16, 84.2%; 13 in unilateral; 3 in bilateral)
	Disc space collapse (n=2, 10.5%)
	Pedicle screw pull-out (n=3, 15.8%; 2 in unilateral; 1 in bilateral)
	Halo sign around pedicle screw (n=1, 5.3%)
Site of pseudarthrosis	4 patients (21.2%) at PSO
	15 patients (78.8%) at non-PSO
Detection time of pseudarthrosis (months)	32.8±23.2 (range, 12–91)
	52.5±35 (range, 19–91) in pseudarthrosis at PSO site
	27.6±17.1 (range, 12–61) in pseudarthrosis at non-PSO site

Values are presented as mean±standard deviation (range) unless otherwise indicated. BMI : body mass index, F/U : follow-up, PSO : pedicle subtraction osteotomy

Surgical procedure (PSO)

Pedicle screws were placed at the upper instrumented vertebrae for all but one patient (hook). The LIV was S1 including the ilium in 16 patients (84.2%). The number of rods used in the PSO surgery were two in all except two patients (three rods) and the rod size was 5.5 mm stainless steel in diameter in all but three patients (6.35 mm stainless steel). Bone morphogenetic protein was used in 10 patients (Table 2).

Table 2.

Surgical procedure of pedicle subtraction osteotomy

	PSO level	Pseudarthrosis site	Radiographic finding	ASF	UIL	LIL	No. of rod	Size of rod (mm)	BMP (mg)
1	L2	L2–3	Right rod fracture	L3–4	T3 (S)	Ilium	2	5.5	0
2	L4	L5–S1	Right rod fracture	L3–4–5	T5 (S)	Ilium	2	5.5	302
3	L3	L5–S1	Both rod fracture	L5–S1	T10 (S)	Ilium	2	5.5	0
4	L3	L4–5	Left rod fracture	L5–S1	T9 (S).	Ilium	2	6.5	0
5	L3	L1–2	Screw pull out		L1 (S)	S1 (S)	2	5.5	0
6	L2	L5–S1	Disc space collapse, halo sign		T11 (S)	S1 (S)	2	5.5	36
7	L3 (picture)	L5–S1, T11–12	both rod fracture, screw pull out	L3–4–5–S1	T11 (S)	Ilium	2	5.5	72
8	L3	L5–S1	Left rod fracture	L5–S1	T4 (S)	Ilium	2	6.5	12
9	L2	L2–3	Right rod fracture	L3–4	T4 (S)	Ilium	3	5.5	24
10	L2	T10–11	Right rod fracture	L5–S1	T5 (H)	Ilium	2	5.5	0
11	L3	T12–L1	Left rod fracture	L5–S1	T12 (S)	Ilium	2	5.5	0
12	L4	T10–11	Left rod fracture		T3 (S)	Ilium	2	6.5	0
13	L3	L5–S1	Both rod fracture	L3–4–5–S1	T4 (S)	Ilium	3	5.5	0
14	L3	L3–4	Right rod fracture	L4–5	T9 (S)	S1 (S)	2	5.5	0
15	L3	T12–L1	Left rod fracture		T10 (S)	Ilium	2	5.5	25
16	L3	L5–S1 and T10–11	Left rod fracture	L5–S1	T11 (S)	Ilium	2	5.5	24
17	L3	L5–S1	Right rod fracture	L5–S1	T12 (S)	Ilium	2	5.5	48
18	L4	T11–12, L5–S1	Screw pull out, disc space collapse		T11 (S)	Ilium	2	5.5	132
19	L3	L3–4	Left rod fracture	L3–4	T11 (S)	Ilium	2	5.5	72

PSO : pedicle subtraction osteotomy, ASF : anterior spinal fusion, UIL : uppermost instrumented level, LIL : lowest instrumented level, BMP : bone morphogenic protein, S : pedicle screw, H : hook

Characteristics of probable pseudarthrosis

Radiographic characteristics of pseudarthrosis including level of PSO, radiographic findings, site of pseudarthrosis and detection time of pseudarthrosis are presented in Table 1. In terms of the numbers of broken rods, most of patients (13 of 16 patients with rod breakage) were unilateral, but three patients had bilateral rod breakage. All three patients with bilateral rod breakage had pseudarthrosis at the non-PSO site (lumbobsacral junction) in which anterior spinal fusion at L5–S1 was performed (Fig. 1). The non-PSO site included the lumbosacral junction (9/19) and thoracolumbar junction (6/19). The two disks space collapse occurred at the L5–S1 in which anterior spinal fusion was not performed, and all 3 pedicle screw pull-outs occurred at the UIV (1 in L1 and 2 in T11). Interestingly, all four of the patients with pseudarthrosis at the PSO site had an interbody device placed at either the PSO segment or the adjacent segment (Fig. 2).

Fig. 1.

A 70-year-old female had sagittal imbalance due to proximal junctional kyphosis occurring after pedicle subtraction osteotomy. A : Standing AP and lateral radiographs at 1 year after pedicle subtraction osteotomy. B : Standing AP and lateral radiographs at 2 months after three column osteotomy. C : Standing AP and lateral radiographs at 4 years after three column osteotomy presents bilateral rod breakage at lumbosacral junction in which anterior spinal fusion in L5–S1 was performed. D : Standing AP and lateral radiographs at 6 years after detection of pseudarthrosis. AP : anteroposterior.

Fig. 2.

A 72-year-old female had sagittal imbalance due to degenerative lumbar kyphoscoliosis. A : Standing AP and lateral radiograph before pedicle subtraction osteotomy. B : Standing AP and lateral radiographs at 2 months after pedicle subtraction osteotomy on L3. C : Standing AP and lateral radiographs at 2 years after pedicle subtraction osteotomy presents right rod breakage at pedicle subtraction osteotomy site. The arrow indicating the broken portion of the rod. D : Standing AP and lateral radiographs at 5 years after detection of pseudarthrosis. The arrow indicating the broken portion of the rod. AP : anteroposterior.

Time-dependent radiographic changes

Time-dependent radiographic changes including SVA, PJA, TK, TLK, LL, PSOA, and pelvic incidence (PI) are presented in Table 3. Mean SVA, TK, LL, and PSOA were significantly different between preoperative and 2 months post-surgery (p<0.05). All of the radiographic changes were not significantly different between value at detection of pseuarthrosis and value at 1 year and 5 years after detection (p>0.05).

Table 3.

Time-dependent radiotraphic change

	Preop	PO #2 M	Detection of PS	#1 Y after detection	#5 Y after detection
SVA (cm)	16.9±7.4	2.9±5.6	8.5±5.8	9.0±6.2	8.9±5.8
P[*] (preop vs. PO)		P.000	P.000	P.000	P.000
P[*] (PS vs. #1 Y/#5 Y)				P.544	P.608
PJA (°)	9.2±12.0	11.5±11.2	12.6±10.1	13.7±10.4	13.6±9.7
P[*] (preop vs. PO)		P.160	P.162	P.080	P.082
P[*] (PS vs. #1 Y/#5 Y)				P.379	P.388
TK (°)	16.9±19.2	27.5±14.7	29.1±14.1	19.2±17.3	28.6±16.9
P[*] (preop vs. PO)		P.001	P.000	P.003	P.03
P[*] (PS vs. #1 Y/#5 Y)				P.928	P.771
TLK (°)	18.2±25.7	8.5±17.3	8.3±20.9	9.7±20.9	9.9±20.0
P[*] (preop vs. PO)		P.098	P.111	P.176	P.175
P[*] (PS vs. #1 Y/#5 Y)				P.216	P.177
LL (°)	-4.0±17.1	-43.5±15.9	-35.8±14.4	-33.6±16.1	-33.8±15.4
P[*] (preop vs. PO)		P.000	P.000	P.000	P.000
P[*] (PS vs. #1 Y/#5 Y)				P.051	P.042
PSOA (°)	14.9±17.0	-19.9±13.9	-18.1±15.9	-14.2±18.9	-13.4±18.7
P[*] (preop vs. PO)		P.000	P.000	P.000	P.000
P[*] (PS vs. #1 Y/#5 Y)				P.089	P.044
PI (°)	49.4±13.5	52.8±10.4	54.1±11.2	54.9±11.1	53.4±11.0
P[*] (preop vs. PO)		P.102	P.003	P.006	P.014
P[*] (PS vs. #1 Y/#5 Y)				P.365	P.303

Statistically significant if p<0.05.

Preop : preoperative, PO : postoperative, M : month, PS : pseudarthrosis, Y : year, SVA : sagittal vertical axis, PJA : proximal junctional angle, TK : thoracic kyphosis, TLK : thoracolumbar kyphosis, LL : lumbar lordosis, PSOA : pedicle subtraction osteotomy angle, PI : pelvic incidence

Time-dependent clinical outcome changes

Time-dependent clinical outcomes changes are presented in Table 4. Both the ODI and SRS questionnaire scores improved significantly when comparing preop to ultimate follow-up scores. All scores worsened at detection of the pseudarthrosis but did not progressively worsen between detection and ultimate follow-up. There was no significant change in ODI scores and SRS total score, or subscales of pain, self-image, function, satisfaction, and mental health between detection of pseudarthrosis and ultimate follow-up (p>0.05).

Table 4.

Time-dependent clinical change

	Preop	PO #2 M	Detection of PS	#1 Y after detection	#5 Y after detection
ODI (100)	56.9±14.2	34.5±14.0	36±13.6	43.1±18.1	40.3±16.7
P[*] (preop vs. PO)		P.000	P.000	P.109	P.002
P[*] (PS vs. #1 Y/#5 Y)				P.106	P.103
SRS total score (100%)	47.2±14.1	70.8±12.9	67.4±13.6	65.2±14.0	62.9±13.9
P[*] (preop vs. PO)		P.000	P.000	P.000	P.000
P[*] (PS vs. #1 Y/#5 Y)				P.172	P.104
SRS pain (5)	2.2±0.8	3.2±1.03	2.9±0.9	2.8±0.9	2.7±0.8
P[*] (preop vs. PO)		P.000	P.002	P.015	P.041
P[*] (PS vs. #1 Y/#5 Y)				P.165	P.061
SRS self image (5)	2.1±0.8	3.5±0.7	3.3±0.9	3.0±0.8	30.0±0.7
P[*] (preop vs. PO)		P.000	P.000	P.002	P.002
P[*] (PS vs. #1 Y/#5 Y)				P.047	P.102
SRS function (5)	2.2±0.8	3.1±0.7	3.0±0.8	2.8±0.9	2.8±0.9
P[*] (preop vs. PO)		P.010	P.000	P.011	P.011
P[*] (PS vs. #1 Y/#5 Y)				P.053	P.053
SRS satisfaction (5)	2.4±0.9	4.0±0.9	3.9±1.1	3.8±1.0	3.8±1.0
P[*] (preop vs. PO)		P.000	P.002	P.003	P.003
P[*] (PS vs. #1 Y/#5 Y)				P.604	P.604
SRS mental health (5)	2.9±0.9	3.9±0.8	3.7±0.8	3.9±0.6	3.6±0.5
P[*] (preop vs. PO)		P0.002	P.003	P.001	P.006
P[*] (PS vs. #1 Y/#5 Y)				P.272	P.272

Statistically significant if p<0.05.

Preop : preoperative, PO : postoperative, M : month, PS : pseudarthrosis, Y : year, ODI : Oswestry Diability Index, SRS : Scoliosis Research Scociety

Comparison of clinical outcomes according to PI and SVA

We further evaluated the difference in outcomes by dividing the patients into two groups : group I, PI ≤60° and group II, PI >60° (Table 5). At ultimate follow-up, the mean ODI and total SRS scores were worse in group II vs. group I, respectively. All SRS subscales were also worse in the group II patients but none of these differences were statistically significant. In addition, there were significant differences between the patients with SVA ≤11 cm and >11 cm in ODI scores, SRS total, SRS pain subscores, SRS self-image subscores, and SRS function subscores at ultimate follow-up (p<0.05) (Table 5).

Table 5.

Comparison of clinical outcomes according to PI and SVA

	PI ≤60	PI >60	p-value[*]	SVA ≤11 cm	SVA >11 cm	p-value[*]
ODI (100)
Preop	57.6±14.5	55.5±14.7	0.773	52.0±13.1	59.2±14.6	0.318
PO #2 M	33.6±14.3	42.8±12.0	0.192	29.36±14.5	39.8±13.0	0.133
Detection of PS	33.1±10.0	45.0±17.8	0.079	30.0±10.2	40.0±14.2	0.140
#1 Y after detection	39.4±18.0	51.0±16.9	0.205	30.54±13.5	48.9±17.3	0.035
#5 Y after detection	36.7±15.7	48.0±17.5	0.180	28.3±11.9	45.8±15.9	0.029
SRS total score (100%)
Preop	47.8±13.7	49.2±16.3	0.853	54.8±17.6	45.3±11.8	0.179
PO #2 M	66.8±13.9	64.5±11.8	0.727	73.4±17.1	62.7±9.5	0.096
Detection of PS	68.8±13.8	64.5±13.9	0.537	79.7±8.8	61.7±11.7	0.004
#1 Y after detection	67.7±12.9	58.9±15.7	0.215	74.5±14.7	60.5±11.8	0.041
#5 Y after detection	65.1±12.9	58.1±16.1	0.321	73.9±12.6	57.8±11.7	0.015
SRS pain (5)
Preop	2.2±.8	2.1±0.9	0.759	2.6±0.8	2.0±0.8	0.182
PO #2 M	3.4±1.1	2.8±0.7	0.207	3.5±1.3	3.1±0.8	0.464
Detection of PS	3.2±0.9	2.4±0.7	0.081	3.6±0.8	2.6±0.8	0.042
#1 Y after detection	3.0±0.9	2.3±0.8	0.106	3.3±1.0	2.5±0.8	0.092
#5 Y after detection	2.8±0.8	2.2±0.8	0.142	3.2±0.9	2.4±0.7	0.040
SRS self image (5)
Preop	2.0 ±0.8	2.0±0.8	0.970	2.4±0.9	1.9±0.7	0.207
PO #2 M	3.2±0.7	3.2±0.7	0.969	3.6±0.9	3.0±0.5	0.085
Detection of PS	3.3±0.8	3.2±1.1	0.314	4.1±0.3	2.8±0.7	0.001
#1 Y after detection	3.1±0.7	2.7±0.9	0.646	3.5±0.4	2.7±0.8	0.037
#5 Y after detection	3.0±0.7	2.7±0.8	0.592	3.5±0.4	2.7±0.7	0.034
SRS function (5)
Preop	2.2±0.7	2.3±0.9	0.748	2.8±0.7	1.9±0.6	0.021
PO #2 M	2.96±0.7	2.6±0.6	0.154	3.1±0.7	2.7±0.7	0.249
Detection of PS	3.0±0.8	2.8±0.9	0.933	3.6±0.4	2.6±0.7	0.019
#1 Y after detection	2.8±0.9	2.5±0.8	0.586	3.4±0.7	2.4±0.9	0.040
#5 Y after detection	2.8±0.9	2.5±0.8	0.586	3.4±0.7	2.4±0.9	0.040
SRS satisfaction (5)
Preop	2.3±0.8	2.7±1.2	0.400	2.9±1.2	2.1±0.8	0.111
PO #2 M	4.0±0.6	3.6±1.5	0.453	4.3±0.4	3.7±1.1	0.178
Detection of PS	3.7±1.2	4.1±0.7	0.552	4.3±0.6	3.6±1.2	0.268
#1 Y after detection	3.8±0.9	3.5±1.1	0.481	4.0±1.3	3.6±0.8	0.354
#5 Y after detection	3.8±0.9	3.5±1.1	0.481	4.0±1.3	3.6±0.8	0.354
SRS mental health (5)
Preop	2.8±0.9	2.9±0.9	0.974	2.8±0.9	2.9±0.9	0.943
PO #2 M	3.3±0.7	3.4±1.0	0.786	3.9±0.6	3.1±0.7	0.058
Detection of PS	3.6±0.8	3.9±0.6	0.401	4.2±0.4	3.4±0.7	0.034
#1 Y after detection	3.9±0.6	3.7±0.5	0.458	4.1±0.6	3.7±0.6	0.212
#5 Y after detection	3.6±0.5	3.3±0.2	0.269	3.5±0.4	3.5±0.5	0.968

Statistically significant if p<0.05.

PI : pelvic incidence, SVA : sagittal vertical axis, ODI : Oswestry Diability Index, Preop : preoperative, PO : postoperative, M : month, PS : pseudarthrosis, Y : year, SRS : Scoliosis Research Scociety

DISCUSSION

In order to prevent complications after PSO, perfect correction is important. All of the cases in this journal have undergone primary PSO for “spinopelvic harmony” (SVA <5 cm, PT <20 degrees, and LL=PI±9 degrees), but pseudoarthrosis following POS has occurred [20].

SVA, PJA, and TK achieved by a PSO were maintained after detection of pseudarthrosis through ultimate follow-up, but were not preserved from the correction obtained immediately post-surgery. LL (p=0.042) and PSO angle (p=0.044) decreased at final follow-up, although this decrease was not significant (Table 3). We postulate that LL and PSOA decreased at final follow-up due to the fact that most pseudarthrosis events occurred at either the L5–S1 segment (nine in 19 patients, 47.4%) or the PSO site (four in 19 patients, 21.1%).

We previously reported on successful radiographic and improved clinical outcomes after revision surgery for pseudarthrosis following PSO [14]. In the current study, the ODI and all SRS subscores improved by PSO did not change significantly at ultimate follow-up. On the other hand, our previous report, regarding the SRS questionnaire, there was only significant improvement of the pain subscale after revision surgery and the self-image subscale was unchanged and the mental health subscale decreased after revision surgery for pseudarthrosis. We believe this might be due to different patient population. Most of the patients in the current study had not experienced prior surgeries and did not have many comorbidities which adversely affected the scores in contrast with the patients included in the previous study [14].

Interestingly, despite the loss by ultimate follow-up of LL and PSOA corrections initially achieved via PSO, ODI and SRS scores generally did not worsen after the time of initial pseudarthrosis detection. We think this might be due to maintenance of SVA achieved by PSO through ultimate follow-up. Glassman et al. [9] reported that sagittal balance using C7 SVA is the most important and reliable radiographic predictor of clinical health status, as patients with positive sagittal imbalance reported worse self-assessment in SRS 22 pain, function, and self-image subscores.

ODI and all SRS subscores of the patients with a PI >60° demonstrated a trend toward poorer than in patients with a PI ≤60°, but the differences were not significant. This reinforces that patients with a high PI also need a high degree of correction of sagittal balance which could not be achieved by a single PSO [4,15,16]. This correction deficit may lead to higher strain forces on the instrumentation with an unbalanced equilibrium, in turn triggering a non-union or implant failure [16].

There are several limitations to this study. First, as a retrospective review. Second, our study did not analyze comparison between post-PSO pseudarthrosis patients who did undergo revision surgery vs. those who chose non-operative treatment. In addition, this study only evaluated patients who had a minimum 5 years follow-up. It is unclear whether a higher follow-up rate would impact our findings. We acknowledge the limitation of diagnosing pseudarthrosis based on radiographs alone. In other words, there may be a likelihood of possible pseudarthrosis which does not require revision surgery and they are usually discovered in a purely incidental fashion through follow-up without apparent symptoms related to definite pseudarthrosis. Most of patients in this current study had modest, but satisfactory improvement in symptoms with non-operative management and declined revision surgery.

We believe that non-operative management for probable pseudarthrosis following PSO can provide acceptable radiographic and clinical outcomes at a minimum 5 years after detection of pseudarthrosis, particularly in patients with a PI <60 degrees.

CONCLUSION

Non-operative management of possible pseudarthrosis after PSO offers acceptable outcomes even at 5 years after detection of pseudarthrosis, provided SVA is maintained. Based on this, it is considered better to try to conservative treatment for pseudarthrosis after POS, provided SVA is maintained. As SVA increased, clinical outcome scores decreased. Patients with a PI <60 degrees typically fared better at final follow-up.