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   Table of Contents  
ORIGINAL ARTICLE
Year : 2020  |  Volume : 11  |  Issue : 3  |  Page : 198-209  

Conservative versus operative management of postoperative lumbar discitis


1 Department of Orthopaedic Surgery, Bangabandhu Sheikh Mujib Medical University, Dhaka, Bangladesh
2 Department of Anesthesiology, Sarkari Karmachari Hospital, Dhaka, Bangladesh
3 GP, The Hashemite University School of Medicine, Alzarqa, Jordan
4 Department of Neurosurgery, Bangabandhu Sheikh Mujib Medical University, Dhaka, Bangladesh
5 Department of Neurosurgery, Neurosurgery Clinic, Birgunj, Nepal

Date of Submission11-Jul-2020
Date of Acceptance20-Jul-2020
Date of Web Publication14-Aug-2020

Correspondence Address:
Kamrul Ahsan
Department of Orthopaedic Surgery, Bangabandhu Sheikh Mujib Medical University (BSMMU), Dhaka
Bangladesh
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Source of Support: None, Conflict of Interest: None


DOI: 10.4103/jcvjs.JCVJS_111_20

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   Abstract 


Background: Treatment option of postoperative discitis (POD) is either conservative or operative, but till date, there are no established validated protocols of the treatment of postoperative lumbar discitis.
Aim: The aim of this study was to assess the outcome of conservative versus operative management of POD following single-level lumbar discectomy.
Methods: We prospectively studied a total of 38 cases of POD. The patients were diagnosed clinically, radiologically, and by laboratory investigations and followed up with serial erythrocyte sedimentation rate (ESR), C-reactive protein, X-ray, computed tomography (CT), and magnetic resonance imaging. Demographic data, clinical variables, length of hospital stay, duration of antibiotic treatment, and posttreatment complications were collected, and pre- and postoperative assessment was done using the Visual Analog Scale (VAS) and Japanese Orthopaedic Association (JOA) score. Functional outcome of the study was measured by the modified criteria of Kirkaldy–Willis.
Results: VAS score for pain was significantly decreased in both groups after treatment. However, posttreatment differences were not statistically significant. In posttreatment mean JOA score, differences were not statistically significant in both groups except the mean difference (−0.47) of restriction of daily activities, which was statistically significant (95% confidence interval: −0.88–−0.07, P = 0.025, unpaired t-test). About 73.7% and 84.2% of the patients had a satisfactory functional outcome in conservative and operative management groups, respectively, at the end of 12-month follow-up.
Conclusions: Operative management yielded better outcomes than traditional conservative treatment in terms of functional outcomes, length of hospital stays, and duration of antibiotic treatment as determined by both the pain and daily activity levels.

Keywords: Conservative and operative management, lumbar, postoperative discitis


How to cite this article:
Ahsan K, Hasan S, Khan SI, Zaman N, Almasri SS, Ahmed N, Chaurasia B. Conservative versus operative management of postoperative lumbar discitis. J Craniovert Jun Spine 2020;11:198-209

How to cite this URL:
Ahsan K, Hasan S, Khan SI, Zaman N, Almasri SS, Ahmed N, Chaurasia B. Conservative versus operative management of postoperative lumbar discitis. J Craniovert Jun Spine [serial online] 2020 [cited 2020 Oct 22];11:198-209. Available from: https://www.jcvjs.com/text.asp?2020/11/3/198/291910




   Introduction Top


Discitis or disc space infection is an infection or inflammation of the intervertebral disc space or vertebral endplate.[1] Frank Turnbull first described postoperative discitis (POD) in 1953 as a clinical entity.[2] It is a primary infection of the nucleus pulposus with secondary involvement of the cartilaginous endplate and the vertebral body. Iatrogenic cause was described and usually can occur following lumbar discectomies.[3] POD incidence varies from 0.2% to 4%.[4],[5],[6] Such type of infections may occur either by open procedure such as laminectomy, discectomy, fusion or instrumented fusions or by minimally invasive spinal procedure such as discography, myelography, paravertebral injection, lumbar puncture etc.[6] It can be septic or aseptic, but recent data suggest that POD is mainly septic bacterial infections.[3],[7]

The most common symptom of discitis is constant back pain that worsens at night and gradually increasing from mild to severe excruciating pain after an initial postsurgical relief of pain. It may be associated with radiating pain to buttocks, thighs, legs, scrotum, groin or perineum,[8] and constitutional symptoms such as fever, fatigue, and malaise (11%–68% of cases).[9],[10],[11] Postoperatively, back pain usually develops (1–6 weeks).[3],[8] While neurological deficits are uncommon, spinal tenderness is the most common sign detected on examination associated with restricted range of movement, pseudo-Gower sign (difficulty rising from bed), paravertebral muscle spasm, and loss of lumbar lordosis.[5],[8],[11] Hence, a high index of suspicion is necessary for every patient presenting with back pain after spinal surgery to start early diagnosis and treatment of discitis; otherwise, this can lead to increased morbidity and mortality.[3],[8],[12],[13]

Treatment options of POD are either conservative or operative, but till now, there are no established, validated protocols of the treatment of postoperative lumbar discitis. Although the mainstay for discitis treatment is a combination of bed rest and prolonged administration of antibiotics, the dosage, route, and duration of antibiotic therapy advocated by various investigators are still imprecise. Thus, surgical intervention is occasionally necessary for patients with failing conservative treatment.[3],[8],[12]

The duration of medical therapy is variable. Some authors advocate 6–8 weeks of intravenous therapy alone, whereas others propose 6–8 weeks of intravenous antibiotics, followed by 2 months or more of oral therapy, depending on clinical and laboratory responses.[3],[8],[12],[14] The prolonged period of antibiotic therapy and strict bed rest can lead to undesired medical and psychosocial effects.[15],[16] Unfortunately, there are no prospective, randomized studies or sufficient data in the literature to compare conservative management outcomes versus surgical treatment. Moreover, most of the surgically treated patients developed severe painful deformities and neurological impairments.

We present this prospective study to assess the outcome of conservative versus operative management of POD following single-level lumbar discectomy, which might be helpful to provide evidence-based information to physicians as well as patient groups regarding the appropriate treatment option for POD.


   Methods Top


This prospective study was conducted in the Department of Orthopaedic Surgery, BSMMU, Dhaka, from January 2017 to May 2020. Ethical clearance was obtained from the Institutional Review Board of BSMMU (ref. no. 11403), and informed written consent was taken from all patients before their inclusion in the study. The inclusion criteria for this study were as follows: (1) patients with diagnosed POD following single-level lumbar discectomy; (2) time framework for the development of back pain after 1–6 weeks of surgery; and (3) POD with radiculopathy. The exclusion criteria in this study were as follows: (1) patients with spontaneous discitis, (2) patients with multiple-level discectomy, (3) patients who lost following up during the 12 months after their discharge, (4) patients who started medical management before shifting to surgical treatment due to inadequate antibiotic response, and (5) patients with gross spinal instability.

A total of 38 cases of POD with applied inclusion criteria were taken as samples. Records of 12 men and 7 women aged 26–65 (mean, 42.53 ± 10.40) years who underwent conservative treatment for pyogenic POD (Group A) after single-level open discectomy at L3–L4 (n = 3), L4–L5 (n = 12), and L5–S1 (n = 4) and 14 men and 5 women aged 26–65 (mean, 45.95 ± 11.90) years who underwent operative treatment for POD (Group B) following single-level open discectomy at L3–L4 (n = 2), L4–L5 (n = 14), and L5–S1 (n = 3) were reviewed. All patients were treated in our spine unit by a single surgeon, and out of 38 patients, 12 patients were referred from other hospitals. All primary discectomy patients had a history of given two antibiotics (intravenous ceftriaxone plus flucloxacillin), 1 h before induction for 2 days, followed by another 5 days of oral antibiotics during discharge (including patients referred from other hospitals in our study). These patients were diagnosed clinically, radiologically, and by laboratory investigations.

All patients had constant back pain that worsens at night or gradually increasing from mild to severe excruciating pain described as continuous, deep seated, and associated with morning stiffness. This presentation was accompanied by severe paravertebral muscle spasm radiating to buttocks, thighs, groin, perineum, or abdomen. Typically, this pain was easily exacerbated by any motion (even with a gentle tap on the bed). On examination, they had severe restriction of movements, positive pseudo-Gower sign, and straight leg raising (SLR) test. Blood parameters such as complete blood count (CBC), erythrocyte sedimentation rate (ESR), C-reactive protein (CRP), blood culture, and other blood investigations (blood sugar, serum albumin, liver, and renal function tests) were done.

Radiological investigations such as X-rays and lumbosacral anteroposterior and lateral spine views were done to document endplate erosion, cavitation, reduction in disc space, and instability, followed by computed tomography (CT) if the previous failed to provide a definitive diagnosis, and magnetic resonance imaging (MRI) with gadolinium contrast enhancement was serially done for evaluation of response to treatment. CT-guided aspiration of the disc space (using a needle or trocar) for microscopy, culture, and biopsy was also performed to identify the bacterial pathogens. All hematological investigations, blood cultures, and CT-guided aspiration of the disc space were done just after admission and before starting empirical antibiotic treatment. Then, cases were followed up at 2 weeks, 1 month, 3 months, 6 months, 12 months, and yearly after that, with serial CBC, ESR, CRP, and repeated X-rays. CT, MRI, or both were done in some patients [Figure 1]d, [Figure 1]e, [Figure 1]f.
Figure 1: (a and b) T1 and T2 sagittal and (c) axial images of postoperative spondylodiscitis. (a and b) Acute stage with altered vertebral marrow signal intensity and associated endplate erosion. (d and e) Partially healed stage with minimum residual paradiscal vertebral marrow edema after 14 weeks. Conservative treatment (f) plain X-ray shows narrowing of disc space with healing after 2 years

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Patients who met the inclusion criteria with almost similar general health status were divided into two groups, as they were numbered in series according to their admission. Those with an odd serial number were classified as Group A, whereas patients with even numbers were classified as Group B. Furthermore, patients in Group A consisted of 19 patients receiving conservative treatment (4–6) weeks of intravenous antibiotics, followed by an additional 4–6 weeks of oral antibiotics, or until back pain, ESR, and CRP values were significantly improved, along with strict bed rest, nutritional diet, analgesic, orthosis, and physiotherapy. Group B consisted of 19 patients receiving operative treatment in the form of exploration and debridement only, a combination of debridement and fixation with posterolateral fusion, and transforaminal lumbar interbody debridement with fusion by titanium cage and autogenous bone graft and stabilization by pedicle screw and rod. After operation patients were treated by 2-3 weeks of intravenous antibiotics followed by 3 weeks of oral antibiotics or untill back pain, ESR and CRP values significantly improved.

Immediately after sending hematological investigations, blood culture, and CT-guided disc space aspiration, all patients started empirical intravenous antimicrobial therapy (ceftriaxone/meropenem with flucloxacillin for Gram-positive and Gram-negative organisms and metronidazole for anaerobic coverage). Then, an appropriate antibiotic was administrated according to the results of microbial culture and sensitivity. The dosage and treatment durations were based on the patient's weight and his/her renal and liver functions. The antibiotic therapy was withdrawn based on clinical improvements and the infection-related laboratory test results, such as the average levels of CRP and ESR.

The surgical method for each surgery is primarily dependent on surgeons' preferences, by which surgeons chose the approach and type of surgery they are most familiar with according to the situation of the infected site in the spine. Demographic data, clinical variables, length of hospital stay, duration of antibiotic treatment, tissue culture reports, and posttreatment complications were recorded. Pre- and postoperative assessments were done using the Visual Analog scale (VAS) or the Japanes Orthopaedic Association (JOA)score. The functional outcome of the study was measured by the modified criteria of Kirkaldy–Willis [Table 1]. All the data were analyzed statistically using the Statistical Package for the Social Science (SPSS, version- 25, Armonk, NY, IBM Corp.). The results were expressed as frequency, percentage, and mean ± standard deviation (SD). Paired and unpaired Student's t-test, Chi-square test, Fisher's exact test, and Z proportion test were performed as applicable. The level of significance was calculated at a confidence interval of 95% and P < 0.05. All the patients were followed up and evaluated at least 12 months postoperatively.
Table 1: The modified criteria of Kirkaldy–Willis for the functional outcome

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Surgical procedure

Following general anesthesia, all patients were positioned prone on frames or rolls to avoid abdominal compression and venous congestion. After adequate prepping, sterile washing, and draping, a posterior longitudinal incision was made, taking off the old surgical wound. All the revision surgeries were performed from the same site of the primary surgery. The epidural scar tissue from the previous surgery was separated from the margin of the residual lamina, and then, access to the normal anatomic planes of the epidural space was achieved by removing the residual lamina. The posterior elements were exposed, and the epidural scar tissue was detached and resected, showing the exposed dura and nerve roots on both sides. These neural structures were carefully dissected and lifted off the posterior longitudinal ligament using bipolar cautery. The nerve roots were then mobilized gently and retracted medially to expose the disc fragments. Then, the affected intervertebral disc was exposed and curetted out on one side, followed by the other. All visible inflammatory tissues were debrided, and disc space and wound area were irrigated adequately by gentamicin mixed with normal saline solution (NaCl 0.9%), followed by interbody fusion with titanium banana cage and autogenous cancellous bone grafts or posterolateral fusion by bone graft depending on the vertebral body destruction, collapse, and kyphotic deformity.

Posterior instrumentation was carried out with pedicle screws, and rods and vertebral bodies above and below the affected segment were included; then, perioperative smears and tissue samples were taken for histological and microbiological assessment. Out of 19 patients, 8 patients were treated by debridement only, 5 patients by posterolateral fusion and posterior instrumentation, and 6 patients by interbody fusion with titanium banana cage and autogenous cancellous bone grafts and posterior instrumentation. Finally, the closure was then done in a routine fashion after the insertion of a subcutaneous suction drain. Besides, all patients received empirical broad-spectrum antibiotics perioperative. Then, appropriate antibiotics were administered according to the microbial cultures and sensitivities, and patients were encouraged to ambulate on the 3rd or 4th day after surgery and were followed up 2 weeks, 1 month, 3 months, 6 months, 12 months, and then once every year.


   Results Top


The mean follow-up periods were 14.8 months (range was 12–24 months) and 13.6 months (range was 12–24 months), and the mean pain-free interval after primary discectomy was 3.2 weeks (range was 1–6 weeks) and 3.6 weeks (range was 1–8 weeks) in the conservative and operative groups, respectively. Furthermore, the mean duration of symptoms before admission to the conservative group was 8.8 days (range was 5–21 days) and the operative group was 9.5 days (range was 7–21 days). All patients had moderate (n = 8) to severe back pain (n = 30), radiculopathy (n = 18), mild fever (n = 10), paravertebral muscle spasm (n = 26), SLR test positive (n = 24), and pseudo-Gower sign (n = 15), and the surgical site skin incision appeared to be normal in all patients. Local erythema, swelling, or a draining sinus was not seen except in one patient in the conservative group during the treatment period.

Among 38 patients, there were 5 service holders in each of the two groups (26.3%), 7 businessmen in the conservative group (36.8%) and 6 in the operative group (31.6%), and 3 homemakers in the conservative group (15.8%) and 4 in the operative group (21.1%). Furthermore, in each of the two groups, there were four patients with other occupations (21.1%) [Table 2].
Table 2: Demographics in patients with conservative and operative management groups

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Associated risk factors were as follows: chronic smoking as found in five patients in both the groups (26.32%), obesity (body mass index >30 kg/m2) as in six patients in the conservative group (31.58%) and eight patients in the operative group (42.11%), and diabetes mellitus with good glycemic control as found in seven patients in the conservative group (36.84%) and six patients in the operative group (31.57%). There were no other comorbidities such as rheumatoid arthritis, immunosuppression, collagen vascular diseases, widespread malignancy, or any comorbidity mandating steroid intake in any of our cases. However, there was only one malnourished patient (5.26%) in the conservative group.

The demographic characteristics in both the groups statistically showed no significant differences in age, sex, occupation, clinical presentation, pain-free interval for the development of symptoms of discitis, duration symptoms, disc level, and associated risk factors [Table 2]. ESR and CRP values were increased in all patients; 14 of 38 patients had white blood cell counts above 11,000/mm3, three patients had total lymphocyte count <1500/mm, and one patient had albumin level below 3.5 g/dl. The mean pretreatment ESR was 60.32 ± 18.02 and 62.11 ± 17.23 mm/h and posttreatment ESR was 14.37 ± 2.29 and 12.68 ± 1.94 mm/h in both the groups, respectively. The mean pretreatment CRP was 70.68 ± 19.82 and 72.84 ± 20.93 mg/L and posttreatment was 8.10 ± 2.97 and 6.21 ± 1.65 mg/L in both Groups A and B, respectively. However, after treatment, elevated ESR and CRP values of patients in both the groups started to decrease within (1–2) weeks, and elevated values returned to the preoperative baseline within 1–3 months. Finally, these values returned to normal in all patients within 6 months during follow-up [Table 3].
Table 3: Inflammatory markers (blood culture, aspiration, and tissue biopsy in Group A and Group B)

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In the conservative group, blood culture and CT-guided aspiration isolated 63% of organisms; 58.3% were Staphylococcus aureus, 33.3% were Staphylococcus epidermidis, and 8.3% were Escherichia coli. However, in the operative group, blood culture, CT-guided aspiration, and postoperative tissue biopsy isolated 73.7% of causative organisms. Among them, 57.1% were S. aureus, S. epidermidis 21.4%, E. coli 7.1%, Pseudomonas 7.1%, and Enterococcus 7.1% [Table 3]. Their biopsy reports showed a mixture of inflammatory cells, including neutrophils, plasma cells, and lymphocytes, but no granulomatous lesions [Table 3].

All patients obtained plain X-ray (anteroposterior and lateral views). Earlier reports showed little evidence of discitis (except for some reduction in disc space). On the other hand, 6–8 weeks later, they showed localized osteopenia, narrowing of the disc space, endplate erosion, cavitation, and kyphotic deformity. Dynamic X-ray was only done if the patient tolerated the pain. However, CT scans were done only for 26 out of 38 patients (68.42%) as this was a financial burden for the remaining 12 patients, which showed that endplate erosions suspected to be formed 3–6 weeks before.

The characteristic MRI findings of discitis were found in all of the patients as they appeared hypointense on T1-weighted images and hyperintense on T2-weighted images with diffuse and continuous heterogeneous contrast enhancement of the discs, endplate, and adjacent marrow [Figure 1]a, [Figure 1]b, [Figure 1]c and [Figure 2]a, [Figure 2]b, which mimic Modic type 1 changes or immediate postoperative period (<6 weeks) changes or recurrent disc herniation. The early pathognomonic sign of disc space infection is a disc within the disc [Figure 2]c. Severe pain after a pain-free interval following lumbar discectomy raises the possibility of a recurrent disc herniation. However, it is difficult to distinguish between a recurrent disc with postoperative changes and scar tissue via MRI, not before 6 months after surgery.[17] A recurrent disc appears on contrast MRI as a rarely enhancing, smooth polypoid, or lobulated margin, which can be contiguous with the remaining disc or appearing as a free fragment. Hence, it exerts a mass effect on the thecal sac and nerve roots.[18] On the other hand, the postoperative scar tissue is irregular, does not have a mass effect, noncontiguous with the disc, and enhances brightly with contrast.[18],[19]
Figure 2: (a and b) T1 and T2 sagittal and (c) axial images of postoperative discitis with altered vertebral marrow signal intensity and associated endplate erosion. (d and e) transforaminal lumbar interbody fusion with titanium cage with bone graft and stabilized by pedicle screws, follow-up at 6 months, and 15 months with union

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In the conservative group, 14 out of 19 patients (73.69%) improved with 30–42 days (4–6 weeks) of intravenous antibiotic use, followed by 35 days (5 weeks) of oral antibiotic use. However, another five patients required 42–49 days (6–7 weeks) of intravenous antibiotic use, followed by another 35–42 days (5–6 weeks) of oral antibiotic use, until the pain was relieved, and the acute-phase reactants had normalized. The mean duration of antibiotic use (both intravenous and oral) was 78.00 ± 5.35 (range, 69–92) days in Group A. However, in the operative group, all patients improved within 14–21 days of intravenous antibiotic use postoperatively, followed by oral antibiotics for 21–28 days, until pain, ESR, and CRP values significantly improved. The mean duration of administration of both intravenous and oral antibiotics was 40.15 ± 3.48 (as a range between 34 and 50) days in Group B.

Based on cultures and sensitivity tests, meropenem, flucloxacillin, linezolid, and fusidic acid were sensitive for S. aureus and S. epidermidis, whereas ciprofloxacin and tobramycin were found to be sensitive for E. coli, Enterobacter species, and Pseudomonas. However, a third-generation cephalosporin (ceftriaxone) was used as an empirical antibiotic and during primary surgeries was found to be resistant to S. aureus and S. epidermidis and E. coli in 40% of cases. Hence, all patients received intravenous empirical antibiotics initially, followed by culture-specific antibiotics.

The conservative group was treated with antibiotics, analgesics, orthosis, and physiotherapy. Nevertheless, the operative group was treated with surgical intervention in the form of debridement alone in eight patients (42.1%), debridement with posterolateral fusion by autogenous bone graft and stabilization by pedicle screw and rod in five patients (26.3%), and transforaminal lumbar interbody debridement with fusion by titanium cage and autogenous bone graft and stabilization by pedicle screw and rod in six patients (31.6%), followed by antibiotics, analgesics, and orthosis [Figure 2]d and [Figure 2]e.

The pretreatment mean (±SD) VAS score was 7.16 (±1.98) and 7.53 (±1.73) in both the groups and posttreatment mean (±SD) VAS score was 2.47 (±1.93) and 1.32 (±1.59), respectively, and the P value was 0.543ns and 0.053ns, respectively. The pain was significantly decreased in both the groups after treatment. Nevertheless, posttreatment differences were not statistically significant [Table 4]. The mean overall JOA score of the patients improved significantly from 8.79 ± 3.03 to 23.00 ± 2.87 postoperatively with an estimated mean difference of − 14.21 (95% confidence interval [CI]: −16.57–−12.78, P < 0.001) in Group A and from 9.16 ± 3.08 to 23.95 ± 2.72 in Group B with an estimated mean difference of − 14.79 (95% CI: −16.58–−13.00, P < 0.001). However, posttreatment (JOA) score, mean differences were not statistically significant in both the groups (mean difference: −0.95, 95% CI: −1.12–0.07, P = 0.166ns) except for the mean difference (−0.47) of restriction of daily activities, which was statistically significant (95% CI − 0.88–−0.07, P = 0.025s) [Table 4]. The mean (±SD) length of hospital stay was 52.32 (±6.51) days in Group A and 30.11 (±4.41) days in Group B.
Table 4: Clinical and functional outcome assessment by VAS, JOA and modified criteria of Kirkaldy-Willis

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POD symptoms were reduced without any complications in 12 (63.2%) and 17 (89.5%) patients in Groups A and B, respectively. In Group A, 7 (36.8%) patients developed complications; among them, wound infection was found in one patient (5.3%), urinary incontinence was found in one patient (5.3%), persistent pain was found in one patient (5.3%), and other four patients developed complications due to longer duration of antibiotic therapy (26.3%), two of whom developed drug-induced hepatitis: one developed phlebitis (at intravenous cannula site) and one developed increased serum urea and creatinine, suggestive for renal pathology. Fortunately, all patients gradually improved over 8 weeks. Only one patient had persistent pain and difficulty walking due to the collapse of disc space and kyphotic deformity persisting after 6 months of follow-up, even after taking 12 weeks of antibiotic therapy and bed rest. Subsequently, this patient was advised to undergo operative treatment.

In Group B, one patient (5.3%) developed an allergic reaction due to antibiotic use, and one patient (5.3%) developed postoperative superficial wound infection, which was managed accordingly [Table 5]. All patients were regularly followed up with serial blood tests/X-rays after 1, 3, 6, and 12 months after discharge and then once every year after that [Figure 1]f, [Figure 2]d and [Figure 2]e. Fusion status was evaluated at 6 and 12 months by radiography and CT scan postoperatively. Fortunately, none of the patients during the conservative and operative treatment suffered neurological deterioration.
Table 5: Surgical data and complications in Group A and Group B

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Compared to the conservative group (Group A), even though the operative group (Group B) required a significantly shorter hospital stay, shorter duration of bed rest, and shorter antibiotic duration, there was a reduction in their discitis symptoms with fewer complications. However, blood transfusions (63.16% vs. 31.58) and total cost of the treatment procedure (115,000/$ 1352 vs. 80,000/$ 940) were more in the operative group than in the conservative group. Thus, according to the modified criteria of Kirkaldy–Willis, 6 (31.58%) and 9 (47.4%) patients had excellent results, 8 (42.11%) and 7 (36.8%) patients had good results, 4 (21.05%) and 3 (15.8%) patients had fair results, and 1 (05.26%) and 0.0% patients had poor results in both the groups, respectively. The satisfactory rate was 73.69% in Group A and 84.2% in Group B [Table 4] at the end of the 12-month follow-up.


   Discussion Top


Postoperative disc space infection is a dreaded complication of disc surgeries, associated with significant morbidity, mortality, and an increase in the cost of health care. Intervertebral discs are largely avascular and derive their nutrition from the vertebral endplates and through the cartilaginous endplates by diffusion from capillary plexuses.[20] The avascular nature of the disc leaves it vulnerable to the iatrogenic introduction of bacteria during interventional disc procedures.[21] This can be either septic or aseptic, where aseptic discitis arises as a result of traumatization of the disc causing vascular compromise during surgery.[22] However, many studies showed that POD could be due to bacterial causes.[3],[7],[10],[23] Most patients of POD can be managed conservatively with immobilization (bed rest and orthosis) and analgesic along with intravenous antibiotic therapy.[24],[25],[26] However, surgery can only be recommended when there are complications such as neurological impairment, severe pain, abscess formation, spinal instability (due to extensive bony destruction), severe kyphosis, or failure of nonsurgical management.[27],[28],[29]

Even though the traditional conservative treatment produces a good outcome in the majority of patients, the prolonged period of strict bed rest and antibiotic therapy which can last up to several months might lead to undesired medical and psychosocial consequences[8],[30],[31] and antibiotic-related major complications (colitis, renal failure, allergic reactions, and phlebitis).[32] However, patients treated with antibiotics have no risk of surgery-related complications. Nevertheless, prolonged antibiotic treatment may not be effective where some degree of vertebral body destruction, nerve root impingement, progressive kyphosis, and prolonged back pain may still occur after successful treatment.

On the other hand, early surgery can achieve infection control and immediate pain relief in advance of extensive vertebral destruction leading to spinal instability and kyphotic deformity, but patients may still suffer from procedure-related complications. However, following conservative treatment, the overall long-term prognosis is good, with reported success rates of 70%–83%.[3],[4],[10] Furthermore, one study reported that 90% of patients are pain free after the resolution of the infection, with 75% going on to either bony ankylosis or stable fibrous union within 2 years of their infection. In contrast, a recent study reported that following conservative treatment, in only 35% of cases, bony ankylosis occurs within 2-year period, and most of the patients frequently complain of residual mechanical back pain.[33],[34]

A study by Hadjipavlou et al. shows that 64% of patients treated with medical means complained of mechanical back pain as opposed to 26% of patients treated surgically.[35] Furthermore, those patients failing nonoperative management usually have progression and spread of their infection with worsening symptoms and elevated laboratory markers and the development of significant spinal deformity. These two clinical scenarios often require operative intervention. A recent study reported good results in 17 consecutive patients treated operatively with debridement, autologous bone grafting, and internal fixation at a mean follow-up of 30 months.[36] Our study is a prospective study that assesses the outcome of conservative versus operative management of POD following single-level lumbar discectomy, which might help provide evidence-based information to the physician and patient groups about the appropriate treatment option for POD.

Compared to the conservative group (Group A), the operative group (Group B) required a significantly shorter hospital stay, shorter duration of bed rest, and antibiotic therapy, and their symptoms of discitis were reduced more with fewer complication rates. Similar findings were almost observed in other studies.[3],[37],[38],[39] The overall functional outcome for patients who received operative treatment at the end of 12-month follow-up was 84.2%, whereas in the conservative treatment group, it was 73.69%. A study by Chang et al.[39] and Das et al.[40] showed that satisfactory outcomes were 80% and 100% in the operative management group. Based on our results, we suggest that all patients at an early stage of pyogenic POD (within 3 weeks of the onset of symptoms) and suitable for surgery should be treated surgically by debridement immediately after the confirmation of the diagnosis to achieve better outcomes. However, those who are in late stages with neural element compression, instability, and kyphotic deformity and then radical and aggressive debridement, fusion, and instrumentation must be initiated for improvement or maintenance of sagittal balance.[25],[27],[28],[29],[35] Hence, conservative treatment is indicated if the patient is not suitable for surgery.

Other authors have advocated that early surgical debridement, followed by antibiotics, is superior to the traditional treatment with antibiotics alone.[41],[42] Similarly, in cases of conservative treatment, if treatment starts within 2 weeks of the onset of symptoms, then 6 weeks of treatment is sufficient, but when treatment is delayed for a mean of 6–7 weeks after the onset of symptoms, then antibiotic treatment for 4–8 weeks is associated with an increased recurrence rate as compared with treatment for 12 weeks and more.[14]

The reasons for improved surgery outcomes with antibiotic groups most likely reflect the nature of the disease itself since the most critical issue in the treatment of pyogenic POD is the infection itself and the resultant spinal instability. Undoubtedly, antibiotics are effective for infection treatment, but they may be relatively ineffective in correcting spinal instability. Surgery, in contrast, can be used to remove inflammatory debris tissues and provide enhanced spinal stability, as well as for obtaining tissue for histopathological examination, Gram/acid-fast bacilli staining, and accurate bacterial culture laboratory tests. Thus, it is the combination of surgery and antibiotics that may result in better outcomes than treatment with antibiotics alone, as this combination provides treatment of both the infection and the spinal instability at the same time.

Surgery at the L4/5 and L5/S1 level through anterior approach is quite difficult and morbidity is high, so all surgery for POD cases were performed through the posterior approach. Re-exploration, debridement and curettage of disc space granulation tissue were done in all cases but inter-transpedicular fixation were done only in 11 cases. The disc space can be approached more easily from the posterior side. However, despite an active infection, instrumentation after radical debridement will not increase the risk of recurrent infection. Moreover, instrumentation helps in stabilizing the infected spine more effectively and hastens the healing process.[43],[44] Another study by Przybylski and Sharan[36] reported that single-stage debridement, arthrodesis, and internal fixation could be used as surgical management of pyogenic discitis with vertebral osteomyelitis without much complication.

The primary aim of the surgical technique is debridement with biopsy for culture and histology. However, following decompression, drainage, and sequestrectomy, the spine may become unstable. Thus, mechanical stabilization is needed in the same or subsequent operations. Nowadays, two different surgical philosophies can be applied: less invasive surgery (LIS) or classic open surgery. The open surgery approach is still the gold standard nowadays, especially if massive bone destruction is evident, whereas LIS can either be CT scan guided or endoscopy guided, which is technically demanding but offers good results when applied early.[35] Moreover, the percutaneous transpedicular discectomy and drainage will result in immediate pain relief.[45]

In all of our 19 operatively treated patients, 8 patients were treated by exploration and debridement only, 5 patients by a combination of debridement and instrumentation with posterolateral fusion, and 6 patients by interbody fusion with titanium banana cage and autogenous cancellous bone grafts and posterior instrumentation depending on the duration of onset of symptoms, severity of pain, and resultant instability. Almost all patients were mobilized within 48–72 h after surgery. None of them had any neurological deterioration except one patient who developed superficial wound infection. Finally, all patients returned to their normal daily activities within 6 months.

The incidence of fusion with bone graft is 97%, compared to the 90% debridement alone or chemotherapy alone without surgery, which achieves a solid fusion in 65%–79% of cases.[46] Careful re-exploration, debridement, and transpedicular fixation with posterolateral fusion result in spontaneous anterior interbody fusion (which is accelerated if a disc space debridement is done).[3] Meanwhile, debridement combined with posterior instrumentation and fusion using autologous bone grafts achieves a fusion rate of 93%–96% and excellent clinical outcomes.[34],[47] Interbody fusion rate in our study was observed in 89.5% within 12 months, and two patients (10.5%) showed a delayed union in the operative group. In the conservative group, spontaneous interbody fusion within a year was observed in 26.3% of cases, probably due to less osteogenic potential to induce spontaneous fusion in pyogenic spondylodiscitis than tuberculous spondylodiscitis.[5]

A study by Veeravagu et al.[48] shows that patients with a wound infection following spinal intervention have a more extended hospital stay, higher mortality, and higher return rates to the operation room as compared to those without surgical wound infections. Besides, these infections represent an additional cost to health care. Furthermore, Thalgott et al.[49] report an average additional cost of $200,000 for each of these patients. Our study shows doubling of the total cost in these procedures compared to the primary surgery, which is significant in the operative group more than the conservative group (115,000/$ 1352 vs. 80,000/$ 940 vs. 35,000/$ 416).


   Conclusions Top


Early diagnosis and appropriate prompt management can eradicate the infection and limit damage to local tissues, including the neural elements. Even though the results were similar for both the treatment groups in terms of infection control, early surgical intervention is recommended, evidenced by shortened hospital stays, shorter duration of antibiotic therapy, higher infection clearance, and a bigger chance of preventing kyphosis. After all, this provides better functional outcomes and improved quality of life, evidenced by the resolution of pain and returning to daily activities.

Financial support and sponsorship

Nil.

Conflicts of interest

There are no conflicts of interest.



 
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    Figures

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    Tables

  [Table 1], [Table 2], [Table 3], [Table 4], [Table 5]



 

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