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Minimally invasive discectomy versus microdiscectomy/open discectomy for symptomatic lumbar disc herniation - PubMed

  • ️Wed Jan 01 2014

Review

Minimally invasive discectomy versus microdiscectomy/open discectomy for symptomatic lumbar disc herniation

Mohammad R Rasouli et al. Cochrane Database Syst Rev. 2014.

Abstract

Background: Microdiscectomy or open discectomy (MD/OD) are the standard procedures for symptomatic lumbar disc herniation and they involve removal of the portion of the intervertebral disc compressing the nerve root or spinal cord (or both) with or without the aid of a headlight loupe or microscope magnification. Potential advantages of newer minimally invasive discectomy (MID) procedures over standard MD/OD include less blood loss, less postoperative pain, shorter hospitalisation and earlier return to work.

Objectives: To compare the benefits and harms of MID versus MD/OD for management of lumbar intervertebral discopathy.

Search methods: We searched the Cochrane Central Register of Controlled Trials (CENTRAL) (November 2013), MEDLINE (1946 to November 2013) and EMBASE (1974 to November 2013) and applied no language restrictions. We also contacted experts in the field for additional studies and reviewed reference lists of relevant studies.

Selection criteria: We selected randomised controlled trials (RCTs) and quasi-randomised controlled trials (QRCTs) that compared MD/OD with a MID (percutaneous endoscopic interlaminar or transforaminal lumbar discectomy, transmuscular tubular microdiscectomy and automated percutaneous lumbar discectomy) for treatment of adults with lumbar radiculopathy secondary to discopathy. We evaluated the following primary outcomes: pain related to sciatica or low back pain (LBP) as measured by a visual analogue scale, sciatic specific outcomes such as neurological deficit of lower extremity or bowel/urinary incontinence and functional outcomes (including daily activity or return to work). We also evaluated the following secondary outcomes: complications of surgery, duration of hospital stay, postoperative opioid use, quality of life and overall participant satisfaction. Two authors checked data abstractions and articles for inclusion. We resolved discrepancies by consensus.

Data collection and analysis: We used standard methodological procedures expected by The Cochrane Collaboration. We used pre-developed forms to extract data and two authors independently assessed risk of bias. For statistical analysis, we used risk ratio (RR) for dichotomous outcomes and mean difference (MD) for continuous outcomes with 95% confidence intervals (CI) for each outcome.

Main results: We identified 11 studies (1172 participants). We assessed seven out of 11 studies as having high overall risk of bias. There was low-quality evidence that MID was associated with worse leg pain than MD/OD at follow-up ranging from six months to two years (e.g. at one year: MD 0.13, 95% CI 0.09 to 0.16), but differences were small (less than 0.5 points on a 0 to 10 scale) and did not meet standard thresholds for clinically meaningful differences. There was low-quality evidence that MID was associated with worse LBP than MD/OD at six-month follow-up (MD 0.35, 95% CI 0.19 to 0.51) and at two years (MD 0.54, 95% CI 0.29 to 0.79). There was no significant difference at one year (0 to 10 scale: MD 0.19, 95% CI -0.22 to 0.59). Statistical heterogeneity was small to high (I(2) statistic = 35% at six months, 90% at one year and 65% at two years). There were no clear differences between MID techniques and MD/OD on other primary outcomes related to functional disability (Oswestry Disability Index greater than six months postoperatively) and persistence of motor and sensory neurological deficits, though evidence on neurological deficits was limited by the small numbers of participants in the trials with neurological deficits at baseline. There was just one study for each of the sciatica-specific outcomes including the Sciatica Bothersomeness Index and the Sciatica Frequency Index, which did not need further analysis. For secondary outcomes, MID was associated with lower risk of surgical site and other infections, but higher risk of re-hospitalisation due to recurrent disc herniation. In addition, MID was associated with slightly lower quality of life (less than 5 points on a 100-point scale) on some measures of quality of life, such as some physical subclasses of the 36-item Short Form. Some trials found MID to be associated with shorter duration of hospitalisation than MD/OD, but results were inconsistent.

Authors' conclusions: MID may be inferior in terms of relief of leg pain, LBP and re-hospitalisation; however, differences in pain relief appeared to be small and may not be clinically important. Potential advantages of MID are lower risk of surgical site and other infections. MID may be associated with shorter hospital stay but the evidence was inconsistent. Given these potential advantages, more research is needed to define appropriate indications for MID as an alternative to standard MD/OD.

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Conflict of interest statement

The authors performed no RCTs to compare these two methods. We declare that we have no interest in the results.

Figures

1
1

Study flow diagram.

2
2

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

3
3

Forest plot of comparison: Outcome 1. Leg pain in two groups of minimally invasive discectomy (MID) and micro/discectomy, medium term (one to five years).

4
4

Forest plot of comparison: Outcome 2. Low back pain in two groups of minimally invasive discectomy (MID) and micro/discectomy at six months, one year and two years.

5
5

Forest plot of comparison: Secondary outcome ‐ complication ‐ surgical sites and other infections

6
6

Forest plot of comparison: Secondary outcome 1e ‐ complications ‐ re‐hospitalisation due to recurrent disc herniation six months or greater.

1.1
1.1. Analysis

Comparison 1 Leg pain in two groups of minimally invasive discectomy (MID) and micro/discectomy, Outcome 1 Medium term (1‐5 years).

1.2
1.2. Analysis

Comparison 1 Leg pain in two groups of minimally invasive discectomy (MID) and micro/discectomy, Outcome 2 Leg pain in 2 groups of MID and micro/discectomy ‐ short term (at 1 day).

1.3
1.3. Analysis

Comparison 1 Leg pain in two groups of minimally invasive discectomy (MID) and micro/discectomy, Outcome 3 Leg pain in 2 groups of MID and micro/discectomy ‐ short term (at 3 days).

1.4
1.4. Analysis

Comparison 1 Leg pain in two groups of minimally invasive discectomy (MID) and micro/discectomy, Outcome 4 Leg pain in 2 groups of MID and micro/discectomy ‐ short term (at 5 days).

2.1
2.1. Analysis

Comparison 2 Low back pain ‐ minimally invasive discectomy (MID) versus micro/discectomy, Outcome 1 Sensitivity analysis for low back pain in 1 year.

2.2
2.2. Analysis

Comparison 2 Low back pain ‐ minimally invasive discectomy (MID) versus micro/discectomy, Outcome 2 Endoscopic discectomy vs. micro/discectomy.

3.1
3.1. Analysis

Comparison 3 Neurological deficit of lower extremity or bowel/urinary incontinency, Outcome 1 Persistent motor deficits post operative.

3.2
3.2. Analysis

Comparison 3 Neurological deficit of lower extremity or bowel/urinary incontinency, Outcome 2 Persistent sensory deficits post operative.

3.3
3.3. Analysis

Comparison 3 Neurological deficit of lower extremity or bowel/urinary incontinency, Outcome 3 Persistent reflex deficit postoperative (12 months).

3.4
3.4. Analysis

Comparison 3 Neurological deficit of lower extremity or bowel/urinary incontinency, Outcome 4 Persistent bladder dysfunction > 6 months' follow‐up.

4.1
4.1. Analysis

Comparison 4 Functional outcomes including daily activity and return to work, Outcome 1 Oswestry Disability Index > 6 months post operative.

4.2
4.2. Analysis

Comparison 4 Functional outcomes including daily activity and return to work, Outcome 2 Number of participants returned to work.

4.3
4.3. Analysis

Comparison 4 Functional outcomes including daily activity and return to work, Outcome 3 Postoperative work disability days ‐ return to work.

5.1
5.1. Analysis

Comparison 5 Secondary outcomes ‐ complications of surgery, Outcome 1 Surgical site and other infections.

5.2
5.2. Analysis

Comparison 5 Secondary outcomes ‐ complications of surgery, Outcome 2 Procedure‐related complications.

5.3
5.3. Analysis

Comparison 5 Secondary outcomes ‐ complications of surgery, Outcome 3 Re‐hospitalisation due to recurrent disc herniation ‐ ≥6 months.

5.4
5.4. Analysis

Comparison 5 Secondary outcomes ‐ complications of surgery, Outcome 4 Surgical re‐intervention.

5.5
5.5. Analysis

Comparison 5 Secondary outcomes ‐ complications of surgery, Outcome 5 Dural tear.

5.6
5.6. Analysis

Comparison 5 Secondary outcomes ‐ complications of surgery, Outcome 6 Re‐hospitalisation due to recurrent disc herniation ‐ 2 years' follow‐up.

5.7
5.7. Analysis

Comparison 5 Secondary outcomes ‐ complications of surgery, Outcome 7 Subgroup analysis for duration of hospital stay.

6.1
6.1. Analysis

Comparison 6 Secondary outcomes ‐ quality of life measured by SF‐36 or SF‐12, and overall satisfaction of participants, which is usually reported by a Likert scale, Outcome 1 SF‐36 Physical Functioning subclass > 6 months.

6.2
6.2. Analysis

Comparison 6 Secondary outcomes ‐ quality of life measured by SF‐36 or SF‐12, and overall satisfaction of participants, which is usually reported by a Likert scale, Outcome 2 SF‐36 Bodily Pain subclass > 6 months.

6.3
6.3. Analysis

Comparison 6 Secondary outcomes ‐ quality of life measured by SF‐36 or SF‐12, and overall satisfaction of participants, which is usually reported by a Likert scale, Outcome 3 SF‐36 General Health subclass > 6 months.

6.4
6.4. Analysis

Comparison 6 Secondary outcomes ‐ quality of life measured by SF‐36 or SF‐12, and overall satisfaction of participants, which is usually reported by a Likert scale, Outcome 4 SF‐36 Physical Health component summary (6 months).

6.5
6.5. Analysis

Comparison 6 Secondary outcomes ‐ quality of life measured by SF‐36 or SF‐12, and overall satisfaction of participants, which is usually reported by a Likert scale, Outcome 5 SF‐36 Mental Health component summary (6 months).

6.6
6.6. Analysis

Comparison 6 Secondary outcomes ‐ quality of life measured by SF‐36 or SF‐12, and overall satisfaction of participants, which is usually reported by a Likert scale, Outcome 6 Overall success (number of participants).

7.1
7.1. Analysis

Comparison 7 Automated percutaneous discectomy versus microdiscectomy, Outcome 1 SO4b. Overall satisfaction of participants.

8.1
8.1. Analysis

Comparison 8 Preoperative pain versus postoperative pain at 12 months, Outcome 1 Low back pain at 12 months in discectomy/microdiscectomy.

9.1
9.1. Analysis

Comparison 9 Microendoscopy versus microdiscectomy/open discectomy (MD/OD), Outcome 1 Leg pain ‐ medium‐term follow‐up.

9.2
9.2. Analysis

Comparison 9 Microendoscopy versus microdiscectomy/open discectomy (MD/OD), Outcome 2 Low back pain ‐ 6 months' follow‐up.

9.3
9.3. Analysis

Comparison 9 Microendoscopy versus microdiscectomy/open discectomy (MD/OD), Outcome 3 Oswestry Disability Index (ODI) > 6 months' follow‐up.

9.4
9.4. Analysis

Comparison 9 Microendoscopy versus microdiscectomy/open discectomy (MD/OD), Outcome 4 Re‐operations due to recurrence of discopathy.

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  • doi: 10.1002/14651858.CD010328

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