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Le bloc paravertébral par rapport à la péridurale thoracique pour les patients subissant une thoracotomie

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Résumé scientifique

Contexte

Les chirurgies sur les organes de la poitrine (généralement les poumons) impliquent une coupure entre les côtes (thoracotomie). Des douleurs post‐thoracotomie intenses peuvent résulter de lésions pleurales (la plèvre est le revêtement des poumons) et musculaires, d'une perturbation de l'articulation costo‐vertébrale (articulation de la cage thoracique) et de lésions du nerf intercostal (nerf qui longe les côtes) pendant la chirurgie. Un mauvais soulagement de la douleur après une chirurgie peut entraver la guérison et augmenter les risques de développer des complications telles que l'affaissement des poumons, les infections pulmonaires et les caillots sanguins dus à une respiration et une évacuation des sécrétions inefficaces. Une gestion efficace de la douleur aiguë après une thoracotomie peut prévenir ces complications et réduire la probabilité de développer une douleur chronique. Une approche multimodale de l'analgésie est largement utilisée par les médecins anesthésistes spécialisés en chirurgie thoracique qui combinent le blocage de nerfs par des techniques d’anesthésie dite régionale et l'analgésie systémique, avec des médicaments non opiacés et opiacés.

Il existe des données probantes indiquant que le blocage des nerfs à leur sortie de la colonne vertébrale (bloc paravertébral, BPV) pourrait être associé à un risque moindre de complications majeures en chirurgie thoracique, mais la majorité des médecins anesthésistes spécialisés en chirurgie thoracique préfèrent encore utiliser la périduralel thoracique (PT) comme analgésie pour leurs patients subissant une thoracotomie. Afin de faire évoluer la pratique, les anesthésistes ont besoin d'une revue qui évalue le risque de toutes les complications majeures associées à la péridurale thoracique et au bloc paravertébral faits pour des thoracotomies.

Objectifs

Comparer les deux techniques régionales de BPV et PT chez les adultes subissant une thoracotomie élective en ce qui concerne :

1. l'efficacité analgésique ;
2. l'incidence des principales complications (y compris la mortalité) ;
3. l'incidence des complications mineures ;
4. la durée du séjour à l'hôpital ;
5. le rapport coût‐efficacité.

Stratégie de recherche documentaire

Nous avons recherché des études dans le Registre Cochrane des essais contrôlés (CENTRAL 2013, numéro 9) ; MEDLINE via Ovid (1966 au 16 octobre 2013) ; EMBASE via Ovid (1980 au 16 octobre 2013) ; CINAHL via l'hôte EBSCO (1982 au 16 octobre 2013) ; et les références bibliographiques des études récupérées. Nous avons consulté le Journal of Cardiothoracic Surgery et le Journal of Cardiothoracic and Vascular Anesthesia (16 octobre 2013). Nous avons repris les recherches le 31 janvier 2015. Nous avons trouvé une étude supplémentaire qui est en attente de classification et qui sera traitée lorsque nous mettrons à jour la revue.

Critères de sélection

Nous avons inclus tous les essais contrôlés randomisés (ECR) comparant le BPV et la PT dans la thoracotomie, y compris la chirurgie digestive haute.

Recueil et analyse des données

Nous avons suivi les procédures méthodologiques standard définies par Cochrane. Deux auteurs de la revue (JY et SG) ont évalué indépendamment les études pour l'inclusion et ont ensuite extrait les données éligibles pour l'inclusion dans la synthèse qualitative et quantitative (méta‐analyse).

Résultats principaux

Nous avons inclus 14 études avec un total de 698 patients subissant une thoracotomie. Deux études sont en attente de classification. Les études ont démontré une grande hétérogénéité dans l'insertion et l'utilisation des deux techniques régionales, reflétant les différences réelles dans les techniques d'anesthésie. Dans l'ensemble, les études incluses présentent un potentiel de biais modéré à élevé, manquant de détails sur la randomisation, l’assignation secrète des groupes ou les dispositions prises pour que les patients ou les évaluateurs des critères de jugement soient aveugles. Des données probantes de qualité faible à très faible n'ont pas montré de différence significative dans la mortalité à 30 jours (2 études, 125 participants. Risque relatif (RR) 1,28, intervalle de confiance (IC) à 95 % 0,39 à 4,23, valeur P = 0,68) et les complications majeures (cardiovasculaires : 2 études, 114 participants. Hypotension RR 0,30, IC 95% 0,01 à 6,62, valeur P = 0,45 ; arythmies RR 0,36, IC 95% 0,04 à 3,29, valeur P = 0,36, infarctus du myocarde RR 3,19, IC 95% 0,13, 76,42, valeur P = 0,47) ; respiratoire: 5 études, 280 participants. RR 0,62, IC 95% 0,26 à 1,52, valeur P = 0,30). Des données probantes de qualité modérée ont montré une efficacité analgésique comparable à tous les moments, tant au repos qu'après une toux ou une physiothérapie (14 études, 698 participants). Des données probantes de qualité modérée ont montré que le BPV présentait un meilleur profil de complications mineures que la PT, y compris l'hypotension (8 études, 445 participants. RR 0,16, IC 95% 0,07 à 0,38, valeur P < 0,0001), nausées et vomissements (6 études, 345 participants. RR 0,48, IC 95% 0,30 à 0,75, valeur P = 0,001), prurit (5 études, 249 participants. RR 0,29, IC 95% 0,14 à 0,59, valeur P = 0,0005) et la rétention urinaire (5 études, 258 participants. RR 0,22, 95 % IC 0,11 à 0,46, valeur P < 0,0001). Les données probantes sur la douleur chronique (six ou douze mois) étaient insuffisantes. Aucune différence n'a été constatée en ce qui concerne la durée du séjour à l'hôpital (3 études, 124 participants). Nous n'avons trouvé aucune étude rapportant de coûts.

Conclusions des auteurs

Le bloc paravertébral a réduit les risques de développer des complications mineures par rapport à la péridurale thoracique. Le bloc paravertébral était aussi efficace que la péridurale thoracique pour contrôler la douleur aiguë. D'autres résultats ont manqué de données probantes. Il n'y avait aucune différence dans la mortalité à 30 jours, les complications majeures ou la durée du séjour à l'hôpital. Les données sur la douleur chronique et les coûts étaient insuffisantes. Les résultats de cette revue doivent être interprétés avec prudence en raison de l'hétérogénéité des études incluses et du manque de données probantes fiables. Les futures études dans ce domaine doivent être menées avec des ECR bien conçus et suffisamment puissants, qui se concentrent non seulement sur la douleur aiguë, mais aussi sur les complications majeures, la douleur chronique, la durée du séjour et les coûts.

PICO

Population
Intervention
Comparison
Outcome

El uso y la enseñanza del modelo PICO están muy extendidos en el ámbito de la atención sanitaria basada en la evidencia para formular preguntas y estrategias de búsqueda y para caracterizar estudios o metanálisis clínicos. PICO son las siglas en inglés de cuatro posibles componentes de una pregunta de investigación: paciente, población o problema; intervención; comparación; desenlace (outcome).

Para saber más sobre el uso del modelo PICO, puede consultar el Manual Cochrane.

Le bloc paravertébral par rapport à la péridurale thoracique pour les patients subissant une thoracotomie

Problématique de la revue

Nous avons examiné les données de l'effet du bloc paravertébral et de la péridurale thoracique pour les patients subissant une thoracotomie. Nous avons trouvé 14 études.

Contexte

Les chirurgies sur les organes de la poitrine (généralement les poumons) impliquent une coupure entre les côtes (thoracotomie), ce qui provoque une douleur intense. Un mauvais soulagement de la douleur après une chirurgie peut ralentir la guérison et augmenter les risques de complications. Une gestion efficace de la douleur aiguë après une thoracotomie peut prévenir ces complications et réduire la probabilité de développer une douleur à long terme. Nous voulions découvrir si le blocage des nerfs à leur sortie de la colonne vertébrale (bloc paravertébral, (BPV)) était meilleur ou pire que l'utilisation du bloc nerveux neuraxial central (péridurale thoracique, (PT)).

Ces données sont à jour au 16 octobre 2013. Nous avons repris les recherches le 31 janvier 2015. Nous avons trouvé une étude supplémentaire qui est en attente de classification et que nous inclurons lorsque nous mettrons à jour la revue.

Caractéristiques des études

Nous avons trouvé 14 études impliquant 698 patients. Alors que les 14 études ont comparé l'efficacité analgésique du BPV et de la PT chez les patients subissant une thoracotomie à ciel ouvert, il y avait des différences significatives dans le timing, la méthode d'insertion et les médicaments utilisés pour le BPV et la PT. Cela rend la comparaison directe difficile. Le suivi des patients était limité à la période suivant immédiatement l'opération (jusqu'à cinq jours après l'opération), seules deux études ont rapporté des critères de jugement à long terme tels que la douleur chronique. Deux études sont en attente de classification.

Résultats principaux

Nous n'avons trouvé aucune différence entre le BPV et la PT en termes de décès à 30 jours et de complications majeures. Le BPV s'est révélé aussi efficace que la PT dans le contrôle de la douleur post‐opératoire. La PT a été associé à des complications mineures telles que l'hypotension, les nausées et vomissements, les démangeaisons et la rétention urinaire, par rapport au BPV. Nous n'avons pas constaté de différence de durée du séjour à l'hôpital entre le BPV et la PT. Il n'y avait pas suffisamment d'informations pour évaluer la douleur chronique et les coûts de santé.

Qualité des données probantes

Nous avons trouvé des données de faible qualité pour le décès à 30 jours, avec des informations limitées fournies par seulement deux études rapportant ce critère de jugement. Nous n'avons trouvé que des données de faible à très faible qualité pour les complications majeures. Ceci est dû au manque d'informations, une seule étude faisant état de ces critères de jugement. Nous avons trouvé des données de qualité modérée pour le contrôle de la douleur aiguë dans la période postopératoire immédiate. Nous avons trouvé des données de qualité modérée pour les complications mineures.

Authors' conclusions

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Implications for practice

In participants undergoing thoracotomy, we found no difference between PVB and TEB in 30‐day mortality, major complications and length of hospital stay. PVB provides comparable pain relief to TEB in the immediate postoperative period, but data on chronic pain are lacking. PVB also has a more favourable minor complication profile than TEB in thoracotomy.

Implications for research

Well‐conducted future research comparing PVB and TEB in thoracotomy should include a randomized controlled trial design, paying specific attention to randomization technique and method of blinding to minimize potential bias. Studies should try to incorporate best practice (for example, timing, method of insertion, concentration and volume of local anaesthetic), but at the same time be pragmatic in design to reflect real‐world variation in regional anaesthesia technique. Areas identified from this review that require further research include 30‐day mortality, major complications, chronic pain and health costs.

Summary of findings

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Summary of findings for the main comparison. Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (30‐day mortality and major complications)

Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (30‐day mortality and major complications)

Patient or population: Patients undergoing thoracotomy
Setting: In hospitals, worldwide
Intervention: Paravertebral blockade
Comparison: Thoracic epidural blockade

Outcomes

Anticipated absolute effects* (95% CI)

Relative effect
(95% CI)

№ of participants
(studies)

Quality of the evidence
(GRADE)

Comments

Risk with PVB

Risk with TEB

30‐day mortality

Study population

RR 1.28
(0.39 to 4.24)

125
(2 RCTs)

⨁⨁◯◯
LOW 1

Only 2 studies reported number of participants that died within 30 days

63 per 1000

80 per 1000
(24 to 265)

Low

64 per 1000

82 per 1000
(25 to 271)

Cardiovascular complications

Study population

Hypotension requiring inotropes RR 0.30
(0.01 to 6.62)

Arrhythmias

RR 0.36 (0.04, 3.29)

Myocardial Infarction

RR 3.19 (0.13, 76.42)

114
(2 RCTs)

⨁⨁◯◯
LOW 1

Only 2 studies reported number of participants with major cardiovascular complications

37 per 1000

22 per 1000
(4 to 105)

Moderate

111 per 1000

64 per 1000
(13 to 311)

Respiratory complications

Study population

RR 0.62
(0.26 to 1.52)

280
(5 RCTs)

⨁⨁◯◯
LOW 3

All respiratory outcomes combined

134 per 1000

83 per 1000
(35 to 204)

Moderate

163 per 1000

101 per 1000
(42 to 248)

Neurological complication (Delirium)

Study population

RR 0.30
(0.09 to 0.99)

125
(2 RCTs)

⨁⨁⨁◯
MODERATE 1 3

Definition of delirium unclear

156 per 1000

47 per 1000
(14 to 155)

Moderate

264 per 1000

79 per 1000
(24 to 261)

*The risk in the intervention group (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).

CI: Confidence interval; RR: Risk ratio

GRADE Working Group grades of evidence
High quality: We are very confident that the true effect lies close to that of the estimate of the effect
Moderate quality: We are moderately confident in the effect estimate: The true effect is likely to be close to the estimate of the effect, but there is a possibility that it is substantially different
Low quality: Our confidence in the effect estimate is limited: The true effect may be substantially different from the estimate of the effect
Very low quality: We have very little confidence in the effect estimate: The true effect is likely to be substantially different from the estimate of effect

1Only two studies reported outcome. Downgraded for small number of events, insufficient data available and for imprecision.

2Only one study reported outcome. Downgraded for small numbers of events, insufficient data available and for imprecision.

3Downgraded for lack of definition of delirium

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Summary of findings 2. Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (acute pain)

Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (acute pain)

Patient or population: Patients undergoing thoracotomy
Settings: In hospitals, worldwide
Intervention: Paravertebral blockade
Comparison: thoracic epidural blockade

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

No of Participants
(studies)

Quality of the evidence
(GRADE)

Comments

Assumed risk

Corresponding risk

Thoracic epidural blockade (TEB)

Paravertebral blockade (PVB)

VAS score at 2 ‐ 6 hours (at rest)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 1.0 to 3.4

The SMD VAS score at 2 ‐ 6 hours (at rest) in the PVB groups was
0.32 higher

0.30 lower to 0.94 higher

239
(6 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represents less pain and better pain control

VAS score at 2 ‐ 6 hours (on coughing/after physiotherapy)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 2.2 to 3.4

The SMD VAS score at 2 ‐ 6 hours (on coughing/after physiotherapy) in the PVB groups was
0.41 higher

0.20 lower to 1.03 higher

126
(3 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represent less pain and better pain control

VAS score at 24 hours (at rest)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 1.0 to 3.0

The SMD VAS score at 24hours (at rest) in the PVB groups was
0.16 higher

0.17 lower to 0.48 higher

239
(6 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represent less pain and better pain control

VAS score at 24 hours (on coughing/after physiotherapy)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 2.6 to 3.7

The SMD VAS score at 24 hours (on coughing/after physiotherapy) in the PVB groups was
0.23 lower

0.58 lower to 0.12 higher

126
(3 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represent less pain and better pain control

VAS scores at 48 hours (at rest)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 1.3 to 3.5

The SMD VAS scores at 48 hours (at rest) in the PVB groups was
0.12 lower

0.46 lower to 0.22 higher

220
(5 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represent less pain and better pain control

VAS scores at 48 hours (on coughing/after physiotherapy)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 2.1 to 3.6

The SMD VAS scores at 48 hours (on coughing/after physiotherapy) in the PVB groups was
0.25 higher

0.16 lower to 0.66 higher

126
(3 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represent less pain and better pain control

Failure of technique

(Number of participants)

Study population

RR 0.27
(0.09 to 0.86)

199
(4 studies)

⊕⊕⊕⊝
moderate1

Lower failure technique indicates more blocks inserted successfully.

112 per 1000

30 per 1000
(10 to 97)

Moderate

119 per 1000

32 per 1000
(11 to 102)

*The basis for the assumed risk (e.g. the median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
CI: Confidence interval; RR: Risk ratio; SMD: Standardized mean difference

GRADE Working Group grades of evidence
High quality: Further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: We are very uncertain about the estimate.

1Studies downgraded due to performance and detection bias.

Background

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Description of the condition

Operations on structures in the chest (usually the lungs) involve cutting between the ribs (thoracotomy). Post‐thoracotomy pain results from pleural (lung lining) and muscular damage, costovertebral joint (ribcage) disruption and intercostal nerve (nerves that run along the ribs) damage during surgery (Ng 2007). It is one of the most severe types of postoperative pain. Poor pain relief can lead to immobility and ineffective breathing and clearing of secretions, resulting in susceptibility to lung collapse (atelectasis), chest infections (pneumonia) and blood clots (pulmonary embolism) (Richardson 1994). The risk of respiratory complications has been reported to be between 15% and 32.5% (D'Arsigny 1998; Wang 1999) and has been observed to account for more than half of the 30‐day mortality after surgery to remove a lung (Powell 2009). In the same observational study, cardiac arrhythmias were reported in 20% of patients (Powell 2009). Pain relief after thoracic surgery is therefore important for patient comfort and for reduction of postoperative pulmonary and cardiac complications. 

Pain can often persist after thoracotomy and the incidence of chronic pain is high, with studies revealing that 30% to 50% of patients still experience pain up to five years after surgery (De Cosmo 2009; Rogers 2000). The exact mechanism of chronic post‐thoracotomy pain is unknown but intercostal nerve damage at thoracotomy is believed to be a major factor, as demonstrated by neurophysiological studies (Benedetti 1998). Electromyography and somatosensory evoked responses demonstrated that intercostal nerve damage led to a decreased pain threshold of the operative scar. A 'wind up' phenomenon of repeated stimulation of peripheral nerve fibres can cause a wide range of nerve fibres to become hyperexcitable and is associated with chronic pain. Aggressive management of acute pain following thoracotomy may reduce the likelihood of developing chronic pain (Katz 1996). A multi‐modal approach to analgesia is widely employed by thoracic anaesthetists using a combination of regional anaesthetic blockade and systemic analgesia, with both non‐opioid and opioid medications and local anaesthesia blockade.

There is some evidence that blocking the nerves as they emerge from the spinal column (paravertebral block) may be associated with a lower risk of major complications in thoracic surgery but the majority of thoracic anaesthetists still prefer to use a thoracic epidural as analgesia for their patients undergoing thoracotomy. Previous systematic reviews of analgesic techniques in thoracic surgery have only evaluated short‐term complications (Davies 2006; Joshi 2008; Kotze 2009). In order to bring about a change in practice, anaesthetists need a review that evaluates the risk of all major complications associated with thoracic epidural and paravertebral block in thoracotomy.

Description of the intervention

Thoracic epidural blockade

Thoracic epidural blockade (TEB) using local anaesthetic and opioid agents has been widely regarded as the gold standard for analgesia and the reduction of associated complications following thoracotomy. Good analgesia from an epidural can result in early extubation, better ventilatory mechanics and gas exchange and reduced rates of lung collapse, pneumonia and pain (De Cosmo 2009). However, the technique requires highly trained medical staff not only for insertion and removal of the epidural catheter but also for the management of the continuous infusion of pain medication. The risks associated with insertion of the epidural include accidental dural puncture, inadvertent high block, local anaesthetic toxicity and total spinal anaesthesia (inadvertent spinal injection of an epidural dose of local anaesthetic leading to local anaesthetic depression of the cervical spinal cord and the brainstem). Nerve injury, epidural haematoma and abscess are rare but serious complications. The UK National Audit Project led by the Royal College of Anaesthetists reported a low rate of permanent harm from all central blocks of 4.2 per 100,000, with rates twice as high in epidurals compared with other central neuraxial blocks (Cook 2009). A thoracic epidural blocks nerves bilaterally and sympathetic nerve block can result in hypotension due to both vasodilatation and cardiac depression. This requires cautious fluid administration in order to avoid fluid overload in susceptible patients (Marret 2005). Failure rates have been described as from 14% to 30% and can be influenced by the skills of the practitioner inserting the catheter and accidental dislodgement of the catheter (Davies 2006).

An epidural is not a suitable technique for all patients and is contraindicated in patients with local infection, previous spinal surgery, disorders of blood clotting and in those taking anti‐coagulant and anti‐platelet therapy. The epidural is inserted through the skin rather than placed under vision and requires a highly skilled practitioner to perform the technique. Trained staff are also needed to look after the patients postoperatively in order to avoid accidental dislodgement of catheters and to observe for side effects. These staff add to the cost of the technique to the healthcare system.

Paravertebral blockade

Paravertebral block (PVB) involves injecting local anaesthetic into the paravertebral space to block nerves after leaving the spinal cord. PVB can be given as a 'single shot' technique but is often given as a continuous infusion of local anaesthetic via a catheter placed directly through the skin (percutaneously) or under direct vision during thoracotomy. Thoracic paravertebral anaesthesia has a number of advantages over the thoracic epidural technique. PVB is a one‐side (unilateral) technique and so respiratory and sympathetic function is preserved on the other (contralateral) side (Ng 2007) and this may be associated with less hypotension, fewer pulmonary complications and less urinary retention (Davies 2006). The failure rate in adults has been reported as 10.1% (Lonnqvist 1995; Richardson 1999) and significantly lower than TEB (odds ratio (OR) 0.28, P value = 0.007) (Davies 2006). The complications reported include inadvertent vascular puncture (3.8% to 6.8%); hypotension (4.0% to 4.6%); haematoma (2.4%); pain at site of skin puncture (1.3%); signs of epidural or intrathecal spread (1.0%); pleural puncture (0.8% to 1.1%); and pneumothorax (0.5%) (Lonnqvist 1995; Naja 2001). Recent evidence suggests that short‐term side effects such as hypotension, urinary retention, nausea, and vomiting appear to be less frequent with PVB than with TEB (Daly 2009). The effect of paravertebral anaesthesia on blood pressure and heart rate is minimal, making this technique safe for patients with coexisting circulatory disease. PVB is thought to be associated with better pulmonary function and fewer pulmonary complications than TEB (Joshi 2008; Richardson 1999). Contraindications to thoracic epidural analgesia do not preclude PVB, which can also be safely performed in anaesthetized patients without an apparent increased risk of neurological injury. 

How the intervention might work

The primary purpose of both these techniques is to achieve good postoperative analgesia. They employ the same pharmacological agents and both have been shown to produce important benefits in this clinical setting. This review is less concerned with the mode of action of PVB than with the ease of use, broad applicability, and relative safety of this technique. Technically, PVB is easier to perform than TEB, needle placement for paravertebral block is away from the midline and spinal cord (Richardson 1999), and some patients who are unsuitable for TEB may be suitable for PVB.

Why it is important to do this review

TEB using local anaesthetic and opioid has been widely regarded as the gold standard for analgesia and reduction of the associated complications after thoracotomy. A survey of Australian thoracic anaesthetists in 1997 revealed that 79% regarded TEB as the method of choice for analgesia in thoracotomy (Cook 1997a). Similar results were found in the UK, with 80% of anaesthetists considering TEB as the best mode of pain relief for upper abdominal surgery (Cook 1997b). Recent evidence from two meta‐analyses and systematic reviews comparing the analgesic efficacy and side effects of epidural versus paravertebral blockade for thoracotomy pain control concluded that although the analgesia was comparable, paravertebral blockade had a better short‐term side‐effect profile, including urinary retention, hypotension, nausea and vomiting, and pulmonary complications (Davies 2006; Joshi 2008). The reviews suggest that paravertebral blockade may be superior to an epidural, but these reviews did not evaluate the more serious complications including mortality. A 2008 survey of all 38 thoracic units in the UK that was carried out by the Association of Cardiothoracic Anaesthetists (ACTA) reported that the majority of thoracic anaesthetists (2/3 units) prefer TEB to PVB, which suggests that most thoracic anaesthetists have yet to be convinced by the evidence available (Shelley 2008).

Compared to TEB, PVB may have several practical advantages. In patients on anti‐coagulants or anti‐platelet therapy, PVB can be placed with little concern about epidural haematoma, abscess, or neurological injury (Daly 2009; Luyet 2009). The catheter can be placed in the correct position under the direct guidance of the surgeon, ensuring accurate placement without damage to neurovascular structures or the pleura. Postoperative management of epidural infusion requires a specialized unit or ward whilst PVB can be managed on an ordinary ward (Daly 2009; Luyet 2009). PVB can be used in a higher proportion of patients and reduces their hospital stay, thereby reducing costs as well as improving the quality of patient care and satisfaction.

A large prospective multicentre investigation into analgesic techniques and morbidity following elective pneumonectomy for cancer (Powell 2009) shows that TEB was associated with more major complications, including significant arrhythmias or pulmonary complications requiring treatment or ventilator support, unexpected intensive care unit (ICU) admissions, 30‐day mortality, further surgery, inotrope usage than PVB (OR adjusted for patient and perioperative factors of 2.2, 95% confidence interval (CI) 1.1 to 3.8; P value = 0.02) (Powell 2009). A comprehensive review of the existing evidence is needed to establish whether paravertebral block is associated with a lower risk of major complications and to clarify whether further randomized trials are justified.

Objectives

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To compare the two regional techniques of TEB and PVB in adults undergoing elective thoracotomy with respect to:

  1. analgesic efficacy;      

  2. the incidence of major complications (including mortality);       

  3. the incidence of minor complications;    

  4. length of hospital stay;

  5. cost effectiveness.

Methods

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Criteria for considering studies for this review

Types of studies

We included only randomized controlled trials (RCTs). We have excluded quasi‐randomized trials, for example where allocation was determined by days of the week or hospital number.

Types of participants

We included all adults undergoing elective thoracotomy including for upper gastrointestinal surgery.

Types of interventions

We included continuous thoracic epidural infusions using local anaesthetics, opioids, and any adjuvant therapies. The comparator was continuous paravertebral blockade using local anaesthetics and adjuvant therapies.

Types of outcome measures

Primary outcomes

  1. Mortality to 30 days.

  2. Major complications including any of: cardiovascular complications (systemic hypotension requiring inotropic support, significant arrhythmias requiring anti‐arrhythmic or cardioversion treatment, myocardial infarction, pulmonary oedema); pulmonary complications requiring treatment (postoperative ventilatory support, reintubation for respiratory failure, acute carbon dioxide retention (CO₂ > 45 mmHg), pneumonia, atelectasis); neurological complications (delirium); unexpected admission to intensive care; any complications that lead to further surgery.

Secondary outcomes

  1. Analgesic efficacy including pain scores (visual analogue scales), acute pain, failure of technique, supplemental analgesia, morphine consumption.

  2. Minor complications including hypotension (not requiring inotropes), postoperative ileus, excessive sedation, nausea and vomiting, pruritis, and urinary retention.  

  3. Chronic pain at six months and one year.

  4. Duration of hospital stay and cost.

Search methods for identification of studies

Electronic searches

We searched for studies on thoracic epidural and paravertebral blocks in adults undergoing thoracotomy in the Cochrane Central Register of Controlled Trials (CENTRAL, 2013, Issue 9) see Appendix 1); MEDLINE via Ovid (1966 to 16th October 2013, see Appendix 2); EMBASE via Ovid (1980 to 16th October 2013, see Appendix 3); and CINAHL via EBSCOhost (1982 to 16th October 2013, see Appendix 4); trial reference lists; and in conference abstracts.

We limited the results to RCTs using the Cochrane highly sensitive search strategy (Higgins 2011). We did not impose any language restriction.

We combined a free‐text search with a controlled vocabulary search, from the inception of a database to the present.

We handsearched the Journal of Cardiothoracic Surgery and Journal of Cardiothoracic and Vascular Anesthesia (from 1996 to 2013).

We reran the search on 31st January 2015. We found one study of interest during that search which we will address when we update the review.

Searching other resources

We searched conference proceedings and abstracts of important meetings in cardiothoracic surgery and anaesthesia on 31st January 2015 and made all efforts to contact authors and experts in order to identify any unpublished research and trials still underway.

We also searched the databases of ongoing trials on 31st January 2015, such as: www.controlled‐trials.com/; clinicaltrials.gov/.

Data collection and analysis

Selection of studies

Two review authors (JY and SG) screened the abstracts of all publications obtained by the search strategies. We noted any reasons for study exclusion in RevMan 5.3. For trials that appeared to be eligible RCTs, we obtained the full articles to assess their relevance based on the predefined criteria for inclusion. We resolved any disagreement through discussion or, if required, we consulted with FG.

Data extraction and management

We used a data collection form to extract data (see Appendix 5). For eligible studies, two review authors (JY and SG) extracted data independently from original publications onto the agreed form. We resolved any disagreement through discussion or, if required, we consulted with FG. As far as possible, we contacted study authors for important information that was missing or unclear. We entered data into RevMan 5.3 and checked it for accuracy.

Assessment of risk of bias in included studies

Two review authors (JY and SG) independently assessed the risk of bias for each study using the criteria outlined in the Cochrane 'Risk of bias' assessment tool (Higgins 2011). We resolved any disagreement through discussion or, if required, we consulted with FG. We constructed a 'Risk of bias' table for all included studies in the review.

(1) Random sequence generation

We described for each included study the method used to generate the random sequence in sufficient detail to allow assessment of whether it should produce comparable groups.

We assessed the method as:

§ low risk of bias (any truly random process, e.g. random number table, computerized random number sequence);
§ high risk of bias (inadequate generation of randomization sequence, e.g. consecutive);
§ unclear risk of bias.

(2) Allocation concealment (checking for possible selection bias)

We described for each included study the method used to conceal the allocation sequence in sufficient detail and determine whether intervention allocation could have been foreseen in advance of or during recruitment, or changed after assignment.

We assessed the methods as:

§  low risk of bias (e.g. telephone or central randomization; consecutively‐numbered sealed opaque envelopes);
§  high risk of bias (e.g. open random allocation; unsealed or non‐opaque envelopes; alternation; date of birth);
§  unclear.

(3)   Blinding (checking for possible performance bias)

We described for each included study the methods used, if any, to blind the study participants personnel and outcome assessment from knowledge of which intervention a participant received. We judged studies to be at low risk of bias if they were blinded, or if we judge that the lack of blinding could not have affected the results. We recognized that it may not be possible to blind clinicians or participants. 

We assessed the methods as:

§  low risk of bias, high risk of bias, or unclear risk of bias for participants;
§  low risk of bias, high risk of bias, or unclear risk of bias for personnel;
§  low risk of bias, high risk of bias, or unclear risk of bias for outcome assessors.

(4) Incomplete outcome data (checking for possible attrition bias through withdrawals, dropouts, protocol deviations)

We described for each included study, and for each outcome or class of outcomes, the completeness of data including attrition and exclusions from the analysis. We stated whether attrition and exclusions were reported, the numbers included in the analysis at each stage (compared with the total number of randomized participants), the reasons for attrition or exclusion where reported, and whether missing data were balanced across groups or were related to outcomes. Where sufficient information was reported, or could be supplied by trial authors, we re‐included missing data in the analyses which we undertook.

We assessed the methods as:

§  low risk of bias (where numbers and reasons for attrition, exclusion or re‐inclusion have been reported);
§  high risk of bias (where there are high numbers of dropouts and protocol deviations leading to loss to follow‐up);
§  unclear.

(5) Selective reporting bias

Where the original protocol of a study was available (for example, as a separate publication), we assessed whether all of the prespecified outcomes and analyses were presented.

We assessed the methods as:

§ low risk of bias (where it is clear that all of the study’s prespecified outcomes and all expected outcomes of interest to the review have been reported);
§ high risk of bias (where not all the study’s prespecified outcomes have been reported, one or more of the reported primary outcomes were not prespecified, outcomes of interest were reported incompletely and so cannot be used, the study fails to include results of a key outcome that would have been expected to have been reported);
§ unclear.

(6) Other bias

We described for each included study any important concerns we have about other possible sources of bias.

We assessed whether each study was free of other problems that could put it at risk of bias:

§ low risk of bias;
§ high risk of bias;
§ unclear.

(7) Overall risk of bias

We made explicit judgements about whether studies are at high risk of bias, according to the criteria given in the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2011). With reference to (1) to (6) above, we assessed the likely magnitude and direction of the bias and whether we considered it likely to impact on the findings. We explored the impact of the level of bias through undertaking sensitivity analyses; seeSensitivity analysis

Measures of treatment effect

Dichotomous data

For dichotomous data, we have presented results as a summary risk ratio (RR) with 95% confidence interval (CI). 

Continuous data

For continuous data, we used the mean difference (MD) if outcomes are measured in the same way between trials. When possible, we used the standardized mean difference (SMD) to combine trials that measure the same outcome but use different methods.  

Unit of analysis issues

Cluster‐randomized trials

We had intended to include cluster‐randomized trials in the analyses along with individually randomized trials but we found no suitable cluster‐randomized trials.

Dealing with missing data

For included studies, we noted levels of attrition. We explored the impact of including studies with high levels of missing data in the overall assessment of treatment effect, using sensitivity analysis. We performed sensitivity analysis for missing data by inclusion and exclusion of studies with a high proportion of missing data. We conducted sensitivity analysis by omitting studies with high attrition (> 15% of participants) from analysis (Gulbahar 2010; Perttunen 1995). We have described this in the Sensitivity analysis section.

For all outcomes, we conducted analyses as far as possible on an intention‐to‐treat (ITT) basis; that is, we attempted to include all participants randomized in the analyses in the groups to which they were allocated, regardless of whether or not they received the allocated intervention.

Assessment of heterogeneity

If we detected substantial heterogeneity we considered whether a pooled result would be meaningful and if so we used a random‐effects model analysis to produce it. We assessed statistical heterogeneity in each meta‐analysis using the I² and τ² statistics. We regarded heterogeneity as substantial if the I² statistic exceeded 30% and either τ² was greater than zero, there was a low P value (< 0.10) in the Chi² test for heterogeneity, or there was clearly substantial inconsistency between trials in the direction or magnitude of effects as judged by visual inspection.

Assessment of reporting biases

If there were 10 or more studies in a meta‐analysis we planned to investigate reporting biases such as publication bias, using funnel plots. We planned to assess funnel plot asymmetry visually and by formal tests. For continuous outcomes we planned to use the test proposed by Egger 1997, and for dichotomous outcomes the tests proposed by Harbord 2006 or Peters 2006. If any of these tests detected asymmetry or it was suggested by a visual assessment, we planned to perform exploratory analyses to investigate it.

Data synthesis

We carried out statistical analysis using the Review Manager 5 software (RevMan 5.3). We used a fixed‐effect model meta‐analysis for combining data where it was reasonable to assume that studies are estimating the same underlying treatment effect, that is, where trials were examining the same intervention and we judged the trial populations and methods to be sufficiently similar. If there was clinical heterogeneity sufficient to expect that the underlying treatment effects differed between trials, or if we detected substantial statistical heterogeneity, we used a random‐effects model analysis to produce an overall summary, if we considered this clinically meaningful. We presented the results of random‐effects analyses as the estimated average treatment effect with its 95% confidence interval, and the 95% prediction interval for the underlying treatment effect (Riley 2011). If an average treatment effect across trials was not clinically meaningful we did not combine heterogeneous trials. If we used random‐effects analyses, the results presented reflect the average treatment effect and its 95% confidence interval, the 95% prediction interval for the underlying treatment effect, and the estimates of τ² and I² statistic. 

Subgroup analysis and investigation of heterogeneity

If we identified substantial heterogeneity, we planned to investigate it using subgroup and sensitivity analyses.

We planned to consider whether an overall summary was meaningful and if so to use a random‐effects model analysis to produce it. We planned to carry out the following subgroup analyses.

  1. Different types of epidurals (e.g. local anaesthetics with or without added opioid).

  2. Different types of surgery (e.g. thoracic surgery, upper gastrointestinal surgery).

  3. Timing of insertion (before skin incision, after operation).

  4. Method of insertion (blind, under ultrasound guidance, under direct vision).

  5. Other additives used in local anaesthetic mixture (beside local anaesthetics and opiates).

We planned to use only the primary outcome (major complications) in subgroup analysis.

For fixed‐effect inverse variance meta‐analysis we planned to assess the differences between subgroups by interaction tests implemented in RevMan 5.3. For other types of analysis we planned to conduct interaction tests using mixed‐effects meta‐regression in external statistical software.

Sensitivity analysis

We planned to carry out sensitivity analysis to explore the effects of fixed‐effect or random‐effects analyses for outcomes with statistical heterogeneity and the effects of any assumptions made such as the value of the intracluster correlation coefficient (ICC) used for cluster‐randomized trials. There were no cluster‐randomized controlled trials in this review and the ICC was not calculated. We had also planned to use sensitivity analyses to explore the effects of inclusion of studies at high risk of bias (by assessing the effects of deletion of high‐risk studies), and the effects of missing outcome data (by assessing best‐case and worst‐case scenarios, and whether plausible values of missing data are likely to make a substantial difference to the results).

'Summary of findings' tables

We used the principles of the GRADE system (Guyatt 2008) in our review to assess the quality of the body of evidence associated with specific outcomes. We included the following as outcomes: cardiovascular complications, pulmonary complications, critical care admission, further surgery, 30‐day mortality, analgesia efficacy, minor complications, and constructed a 'Summary of findings' table using the GRADEpro software. The GRADE approach appraises the quality of a body of evidence based on the extent to which one can be confident that an estimate of effect or association reflects the item being assessed. The quality of a body of evidence considers within‐study risk of bias (methodologic quality), the directness of the evidence, heterogeneity of the data, precision of effect estimates, and risk of publication bias.

Results

Description of studies

See Characteristics of included studies and Characteristics of excluded studies.

Results of the search

See Figure 1


1 Study flow diagram (Search dates October 2013, reran January 2015)

1 Study flow diagram (Search dates October 2013, reran January 2015)

The electronic and handsearches described above and in the appendices in October 2013 retrieved 74 results. After removal of one duplicate, there were 73 unique results. After review of the abstracts we excluded 54 reports and reviewed the full‐text version of the remaining 19 citations. Of these, we considered 14 papers to be relevant to the research question. We were unable to obtain a full‐text version of one paper (Wedad 2004), which remains awaiting classification.

We reran the search on 31st January 2015 and found one study of interest (Raveglia 2014). There are two studies in total that are awaiting classification. We will address these studies when we update the review.

Included studies

We include 14 studies (Bimston 1999; Casati 2006; De Cosmo 2002; Grider 2012; Gulbahar 2010; Ibrahim 2009; Kaiser 1998; Kobayashi 2013; Matthews 1989; Messina 2009; Murkerjee 2010; Perttunen 1995; Pintaric 2011; Richardson 1999) involving a total of 698 participants in qualitative and quantitative analyses. Included studies were from 1995 to 2003, and of relatively small sample sizes, ranging from 20 to 100 participants. There was a high degree of clinical heterogeneity. Whilst all 14 studies compared the analgesic efficacy of paravertebral blockade (PVB) and thoracic epidural blockade (TEB) in participants undergoing open thoracotomy, there were significant differences in the timing, method of insertion and utilization of PVB and TEB in the peri‐operative setting (Table 1). In the majority of the studies, TEB was inserted at the beginning of the procedure before surgical incision was made, except for Matthews 1989 where the participants were randomized to the intervention at the end of the procedure and TEB was then placed by the anaesthetists after chest closure. Although TEBs were inserted before the surgical procedure in the remaining 13 studies, these were not used to provide pain relief until the end of surgery in five studies (Grider 2012; Kobayashi 2013; Messina 2009; Murkerjee 2010; Perttunen 1995). The time frames for data collection and follow‐up of participants ranged from two to 96 hours postoperatively.

Open in table viewer
Table 1. Technical aspects of PVB and TEB catheters

PVB

TEB

STUDY

METHOD OF INSERTION

METHOD OF USE

POSTOPERATIVE MEDICATION

METHOD OF INSERTION

METHOD OF USE

POSTOPERATIVE MEDICATION

Bimston 1999

Inserted under direct vision by surgeon

18 ml 0.5% bupivacaine bolus followed by infusion of 0.1% bupivacaine with 10 μg/ml fentanyl, 10 ‐ 15 ml/hr

infusion of 0.1% bupivacaine with 10 μg/ml fentanyl, 10 ‐ 15ml/min

Percutaneously by landmark technique before induction of GA

Uncertain whether catheter was used during operation

Infusion of 0.1% bupivacaine with 10 μg/ml fentanyl, 10 ‐ 15 ml/hr

Casati 2006 I

Percutaneously by landmark technique before induction of GA

Pre‐op Injections by landmark technique before induction of GA

15 ml of 0.75% ropivacaine

infusion of 0.2% ropivacaine at 5 ‐ 10ml/hr

Percutaneously by landmark technique before induction of GA

5 ml bolus of 0.75% ropivacaine

infusion of 0.2% ropivacaine at 5 ‐ 10 ml/hr

De Cosmo 2002

Inserted under direct vision by surgeons

Used at the end of operation only

20 ml of 0.475% ropivacaine as loading dose, infusion of 0.3% ropivacaine at 5 ml/hr post‐surgery

Percutaneously by landmark technique before induction of GA

5 ml bolus of 0.2% ropivacaine and sufentanil 10 µg given as bolus. Catheter used during operation if required

Infusion of 0.2% ropivacaine with 0.75 µg/ml of sufentanil at 5 ml/hr

Grider 2012

Inserted under direct vision by surgeon

Used at the end of the operation only

0.25% bupivacaine at 8 ml/hr

Percutaneously by landmark technique before induction of GA

Used at the end of operation

0.25% bupivacaine 2 ml/hr with 1 ml every 10 min PCEA with or without hydromorphine

Gulbahar 2010

Inserted under direct vision by surgeon

Used at the end of operation only

0.25% bupivacaine infusion at 0.0 ml/kg/hr PCEA

Percutaneously by landmark technique before induction of GA

Used at the end of operation

5 ml of 0.25% bupivacaine bolus, followed by 0.0 ml/kg/hr PCEA

Ibrahim 2009

Percutaneously by landmark technique before induction of GA

15 ‐ 20 ml 0.5% ropivacaine bolus followed by 0.375% ropivacaine 0.1 ml/kg/hr infusion

0.375% ropivacaine 0.1 ml/kg/hr infusion

Percutaneously by landmark technique before induction of GA

5 ‐ 8 ml of 0.5% ropivacaine bolus followed by 0.375% ropivacaine 0.1 ml/kg.hr infusion

0.375% ropivacaine 0.1 ml/kg/hr infusion

Kaiser 1998

Inserted under direct vision by surgeon

Used at the end of operation only

20 ml 0.5% bupivacaine bolus followed by 0.1 ml/kg/hr of 0.5% bupivacaine

Percutaneously by landmark technique before induction of GA

0.5% bupivacaine at 4 ‐ 6 ml/hr infusion during operation

4 ‐ 8 ml/hr of 0.25 ‐ 0.375% bupivacaine with 2 μg/ml fentanyl

Kobayashi 2013

Inserted under direct vision by surgeon

Used at the end of operation only

10 ml 0.375% ropivacaine bolus followed by 0.2% ropivacaine with fentanyl 9.5 μg/ml at 5 ml/hr infusion

Percutaneously by landmark technique before induction of GA

Used at the end of operation

5 ml 0.2% ropivacaine bolus followed by 0.2% ropivacaine with fentanyl 9.5 μg/ml at 5 ml/hr infusion

Matthews 1989

Percutaneously by landmark at the end of procedure

Used at the end of operation only

10 ml 0.25% bupivacaine bolus followed by infusion at 5 ml/hr

Percutaneously by landmark technique at the end of procedure

Used at the end of operation

10 ml 0.25% bupivacaine bolus followed by infusion at 5 ml/hr

Messina 2009

Percutaneously by landmark technique before induction of GA

Used at the end of operation only

0.125% levobupivacaine with fentanyl 2 μg/ml at 0.08 ml/kg/hr infusion

Percutaneously by landmark technique before induction of GA

Used at the end of operation

0.25% levobupivacaine with fentanyl 1.6 μg/ml at 0.1 ml/kg/hr infusion

Murkerjee 2010

Percutaneously by landmark technique before induction of GA

Used at the end of operation only

15 ml of 0.25% bupivacaine with 50μg of fentanyl bolus

Percutaneously by landmark technique before induction of GA

Used at the end of operation

7.5 ml of 0.25% bupivacaine with 50 μg of fentanyl bolus

Perttunen 1995

Inserted by surgeon under direct vision

Used at the end of operation only

0.25% bupivacaine bolus according to height, infusion of 4 ml/hr, 6 ml/hr, 8 ml/hr

Percutaneously by landmark technique before induction of GA

Used at the end of operation

0.25% bupivacaine bolus according to height, infusion of 4 ml/hr, 6 ml/hr, 8 ml/hr

Pintaric 2011

Percutaneously by landmark technique before induction of GA

0.5% levopubivacaine with 30 μg/kg morphine, dose depends on height

0.125% levobupivacaine with 20 μg/ml morphine infusion at 0.1 ml/kg/hr with PCEA

Percutaneously by landmark technique before induction of GA

0.25% levopubivacaine with 30 μg/kg morphine, dose depends on height

0.125% levobupivacaine with 20 μg/ml morphine infusion at 0.1 ml/kg/hr with PCEA

Richardson 1999

Inserted by surgeon under direct vision

Pre‐op Injections by landmark technique before induction of GA

20 ml of 0.5% bupivacaine

20 ml bolus of 0.5% bupivacaine, followed by infusion at 0.1 ml/kg/hr

Percutaneously by landmark technique before induction of GA

10 ‐ 15 ml bolus of 0.25% bupivacaine

10 ml bolus of 0.25% bupivacaine, followed by infusion at 0.1 ml/kg/hr

GA: general anaesthesia
hr: hour
kg: kilogram
ml: millilitres
PCEA: patient‐controlled epidural analgesia
PVB: paravertebral blockade
TEB: thoracic epidural blockade
µg: micrograms

There was further heterogeneity in the placement of PVB. In three studies (Casati 2006; Messina 2009; Richardson 1999), the paravertebral space was identified using landmark technique, and local anaesthetic was injected as a bolus to initiate the blockade. The most popular insertion method of PVB catheter was by the surgeon under direct vision, and eight studies used this technique (Bimston 1999; De Cosmo 2002; Grider 2012; Gulbahar 2010; Kaiser 1998; Kobayashi 2013; Perttunen 1995; Richardson 1999). PVB catheters were inserted by anaesthetists percutaneously before surgical procedure in five studies (Casati 2006; Ibrahim 2009; Messina 2009; Murkerjee 2010; Pintaric 2011) and post‐procedure in one study (Matthews 1989).

The content of infusions used for TEB and PVB also varied in terms of timing and volume of boluses/loading dose, infusion rates, local anaesthetic used (bupivacaine, levobupivacaine, ropivacaine), concentration of local anaesthetic (0.1% to 0.5%), whether opiates were added and what type of opiates (fentanyl, morphine, hydromorphine) (see Table 1). For further details refer to the Characteristics of included studies tables.

Excluded studies

There were three excluded studies (Elsayed 2012; Kanazi 2012; Kozar 2011). Elsayed 2012 was a retrospective analysis of patient records looking at complications in post‐thoracotomy patients. Kanazi 2012 described a subpleural catheter but without review of described technique, and did not represent a PVB so was excluded. Although Kozar 2011 compared thoracic epidural and paravertebral block and the incidence of chronic pain, pain was measured at three months and did not meet our selection criteria. Data were not included in our analysis. For further details refer to the Characteristics of excluded studies tables.

Studies awaiting classification

There are two studies awaiting classification. Wedad 2004 compared thoracic epidural, paravertebral and interpleural analgesia with wound infiltration. Despite strenuous efforts, we did not manage to obtain a copy of the article to include in our review. Raveglia 2014 was a prospective randomized study of 71 participants undergoing thoracotomy, comparing the impact of thoracic epidural and paravertebral blockade on pain control and respiratory function. For further details refer to the Characteristics of studies awaiting classification tables.

Ongoing studies

There are no ongoing studies

Risk of bias in included studies

See Figure 2 and Figure 3 for summaries of the 'Risk of bias' assessments for the 14 included studies.


Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.


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

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

Allocation

The majority of studies did not report how the randomization sequence was generated, simply saying that allocation was "random". Six studies reported the randomization method used and were at low risk of selection bias (Bimston 1999; Casati 2006; De Cosmo 2002; Ibrahim 2009; Pintaric 2011; Richardson 1999). Three studies reported adequate methods of allocation concealment and were at low risk of selection bias (Casati 2006; Ibrahim 2009; Pintaric 2011). The majority dd not mention how the random sequence was applied, or whether allocations were adequately concealed before assignment.

Blinding

Two studies reported blinding of participants and clinicians and were at low risk of performance bias (Grider 2012; Ibrahim 2009). This was achieved by putting both types of analgesia in place but only infusing one. The remainder of the studies either stated that participants and clinicians were aware of treatment allocations, or did not mention blinding, which probably means they were not blinded. Four studies described measures to blind observers of outcomes and were at low risk of detection bias (Grider 2012; Casati 2006; Ibrahim 2009; Pintaric 2011). In most studies, the main outcomes were self‐reported by the participants, who were not blinded.

Incomplete outcome data

Ten studies reported outcomes for all randomized participants and were at low risk of attrition bias (Bimston 1999; Casati 2006; Grider 2012; Ibrahim 2009; Kobayashi 2013; Matthews 1989; Messina 2009; Murkerjee 2010; Pintaric 2011; Richardson 1999). There was no study reporting high levels of missing data (less than 15% in all cases). However, we rated two studies at high risk of bias: Gulbahar 2010 excluded 6/50 participants (12%), but all from the epidural arm; Perttunen 1995 excluded 6/51 randomized participants (12%). We examined the treatment effects according to quality components (concealed treatment allocation, blinding of participants and caregivers, blinded outcome assessment).

Selective reporting

None of the included studies was registered on trial registries and it was unclear whether there was selective reporting bias. In one study (Messina 2009), several potentially important outcome measures were not published, including VAS on movement, sedation scores and arterial blood gases.

Other potential sources of bias

Six studies had low risk of other bias (Casati 2006; De Cosmo 2002; Ibrahim 2009; Kobayashi 2013; Perttunen 1995; Pintaric 2011). In Bimston 1999 the two arms were treated differently; the epidural arm was under the care of anaesthetists, but the paravertebral block arm was under the care of the surgical team. This led to differences in the care received, and hence differences in outcome may be due to differences in treatments received other than the randomized intervention. In Messina 2009, the authors stated that their institution had extensive experience in the insertion of TEB catheters but the insertion of PVB catheters was a novel technique to the anaesthetists who had only performed 30 PVBs prior to the study. The differences in the analgesic efficacy of the two techniques, especially PVB, could be influenced by the disparity in experience.

Effects of interventions

See: Summary of findings for the main comparison Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (30‐day mortality and major complications); Summary of findings 2 Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (acute pain)

Primary outcomes

1. Mortality at 30 days

There was low‐quality evidence on mortality at 30 days, with only two studies reporting 30‐day mortality (Kaiser 1998; Richardson 1999), and a total of 125 participants (17.9% of total participants included in this review). Five out of 61 (8.2%) participants died in the PVB group and four out 64 (6.3%) participants died in the TEB group, an absolute risk reduction of 1.9%. The risk of dying within 30 days following PVB was not statistically higher (RR 1.28, 95% CI 0.39 to 4.24, P value = 0.68) (Analysis 1.1)

2. Major complications

We had intended to report the overall risk of suffering a major complication with each of the techniques under study; however, none of the included studies reported the number of individuals who suffered a major complication. Rather, they each reported the number of individuals with each individual complication, and it is not clear how many such complications each individual may have suffered. We have therefore reported here on each major complication individually.

Cardiovascular complications

There was low‐quality evidence on major cardiovascular complications, with limited data available. Two studies with a total of 114 participants (16.3% of total participants included in this review) reported cardiovascular complications (Matthews 1989; Richardson 1999); 2/56 (3.6%) had cardiovascular complications following PVB, while 4/58 (6.9%) reported the same in the TEB group. There was no difference in hypotension requiring inotropes (RR 0.30, 95% CI 0.01 to 6.62, P value = 0.45), arrhythmias (RR 0.36, 95%CI 0.04 to 3.29, P value = 0.36) and myocardial infarction (RR 3.19, 95% CI 0.13 to 76.42, P value = 0.47), Figure 4. In Matthews 1989, one participant in the TEB group suffered persistent hypotension despite fluid resuscitation and received inotropic support (RR 0.30, 95% CI 0.01 to 6.62, P value = 0.45), Analysis 2.1. Three participants from the TEB group and one participant from the PVB group developed arrhythmias but there was no information on the treatment that they received (RR 0.36, 95% CI 0.04 to 3.29, P value = 0.36, Analysis 2.1). Richardson 1999 reported one participant in the PVB group who had a myocardial infarction and died as a result (RR 3.19, 95% CI 0.13 to 76.42, P value = 0.47, Analysis 2.1).


Forest plot of comparison: 2 Major complications, outcome: 2.1 Cardiovascular complications.

Forest plot of comparison: 2 Major complications, outcome: 2.1 Cardiovascular complications.

Pulmonary complications

There was low‐quality evidence on pulmonary complications. Five studies with a total of 280 participants (40.1% of total) reported pulmonary complications (Bimston 1999; Grider 2012; Kaiser 1998; Perttunen 1995; Richardson 1999). Eleven of 131 (8.4%) participants in the PVB group reported respiratory complications, while 20/149 (13.4%) reported the same in the TEB group. This difference of 5% was not statistically significant (RR 0.62, 95% CI 0.26 to 1.52, I² statistic = 26%, P value = 0.30, Figure 5). In subgroup analyses by specific complications reported, there was no statistically significant difference between the PVB and TEB groups. Two participants from the TEB group developed respiratory distress and were reintubated and ventilated in the intensive care unit (ICU) in Grider 2012.


Forest plot of comparison: 2 Major complications, outcome: 2.2 Respiratory complications.

Forest plot of comparison: 2 Major complications, outcome: 2.2 Respiratory complications.

In Perttunen 1995, respiratory depression (PaCO₂ > 4.5 kPa) was observed in five participants in the TEB group and six participants in the PVB group for more than two hours after the operation. Pneumonia was diagnosed in participants from three studies, in 18 out of 175 participants (Bimston 1999; Kaiser 1998; Richardson 1999). The risk of developing pneumonia post‐thoracotomy was not significantly different between the PVB and TEB groups (RR 0.38, 95% CI 0.10 to 1.45, I² statistic = 28%, P value = 0.16, Analysis 2.2). Atelectasis was not observed in our included studies.

Neurological complications

Major neurological complications were poorly reported. There was moderate‐quality evidence on delirium only. Delirium was described in two clinical trials involving 125 participants (Perttunen 1995; Richardson 1999) but no definition of delirium was reported.

In Perttunen 1995, seven out of 15 participants developed delirium in the TEB group compared to two out of 15 participants in the PVB group. Three out of 49 participants in the TEB group developed delirium compared with one out of 46 participants in the PVB group in Richardson 1999. The risk of developing delirium following thoracotomy was lower in the PVB group compared to TEB, but did not reach statistical significance (RR 0.31, 95% CI 0.09 to 1.00, P value = 0.05, Analysis 2.3).

Unexpected admission to intensive care

There was low‐quality evidence on unexpected admission to intensive care with very limited data from two studies of 139 participants (Gulbahar 2010; Richardson 1999). Three out of 25 participants in the TEB group were admitted to the ICU compared to one out of 25 participants in the PVB group in Gulbahar 2010. Three participants each from both the TEB and PVB groups were admitted to ICU unexpectedly in Richardson 1999. There was little heterogeneity and fixed‐effect analysis was used. Unexpected admission rates to ICU were not statistically significant between the PVB and TEB groups (RR 0.63, 95% CI 0.19 to 2.07, P value = 0.44) Analysis 2.4.

Any complications that lead to further surgery

There was very low‐quality evidence on complications that lead to further surgery, with only one study of 45 participants (Perttunen 1995). In Perttunen 1995, one out of 15 participants in the TEB group needed further surgery (RR 0.31, 95% CI 0.01 to 8.28).

Secondary outcomes

1. Analgesic efficacy including pain scores

Although all 14 included studies reported on analgesic efficacy of PVB and TEB, studies differed significantly in the way acute pain was assessed and reported. Pooling of results from all studies was not possible, due to significant clinical heterogeneity. Visual analogue scale scores (VAS) were used in all of the studies but the scales were different; a majority of studies used the 0 to 10 scale, but Kaiser 1998 used VAS in 0 to 4 categories (reported as mean and standard deviation (SD)), and two studies (Ibrahim 2009; Perttunen 1995) used VAS 0 to 5. Types and concentrations of local anaesthetic used in bolus and infusions also varied, with some studies adding opiates to the infusion mixture and some allowing participant‐controlled top‐up (see Table 1).The method and time intervals of VAS score assessments also differed between the studies, with some measuring VAS at rest and some at coughing or on movement, with intervals ranging from every two to four hours to only once every 24 hours (see Table 2). No subgroup analysis was possible.

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Table 2. VAS measurements by study

STUDY

VAS range

VAS reported

Timing of VAS

Time points VAS reported

Supplementary analgesia

CONCLUSION

Bimston 1999

0 ‐ 10

Mean

At rest

8, 16, 24, 32, 49, 48, 56, 64, 72, 80, 88, 96 hrs

Not reported

TEB superior to PVB for first 32 hrs

Casati 2006

0 ‐ 10

Mean (SD)

At rest

On coughing

Recovery, 12, 24, 48 hrs

Not reported

PVB as effective as TEB

De Cosmo 2002

0 ‐ 10

Mean (SD)

At rest

On movement

1, 4, 8, 12, 24, 36, 48 hrs

Overall mean consumption of ketolorac reported

PVB as effective as TEB

Lower VAS scores in TEB first 8 hrs

Grider 2012

0 ‐ 10

Mean (SD)

At rest

During physiotherapy

Recovery, day 1 am, day 2 am/pm, day 3 am/pm, day 4 am

Number of participants in whom technique failed and PCA prescribed

PVB as effective as TEB (plain LA) however TEB with opiate was superior

Gulbahar 2010

0 ‐ 10

Mean

At rest

Day 1, 2, 3

Daily number of PCEA request

PVB as effective as TEB

Ibrahim 2009

0 ‐ 5

Mean

At rest

4, 8, 12, 16, 20, 24 hrs

Rescue morphine recorded but not published

PVB as effective as TEB

Kaiser 1998

0 ‐ 4

Mean (SD)

At rest

Day 0, 1, 2, 3, 4, 5

Mean daily consumption of nicomorphine

PVB as effective as TEB

PVB superior at 72 and 96 hrs

Kobayashi 2013

0 ‐ 10

Mean (SD)

At rest

On coughing

On exercise

2, 5, 16, 20, 24, 48 hrs

Frequency of additional analgesic (non‐specified)

PVB as effective as TEB

Matthews 1989

0 ‐ 10

Mean (SD)

At rest

4, 12, 24 hrs

Not recorded

PVB as effective as TEB

Messina 2009

0 ‐ 10

Mean (SD)

At rest

On movement

Recovery, 6, 24, 48, 72 hrs

Median cumulative morphine daily (mg)

PVB as effective as TEB

Murkerjee 2010

NA

NA

NA

NA

NA

Single bolus PVB superior, lasted statistically significantly longer than TEB

PVB: 171.66 (77.31) vs TEB: 105.83 (33.28)

Perttunen 1995

0 ‐ 5

Mean (Range)

At rest

On coughing

1, 2, 4, 6, 20, 24, 30, 48 hrs

Mean cumulative PCA morphine consumption every 3 hrs

PVB as effective as TEB

Pintaric 2011

0 ‐ 10

Mean (SD)

At rest

After physiotherapy

6, 24, 48 hrs

Mean consumption of piritramide

PVB as effective as TEB

Richardson 1999

0 ‐ 10

Mean, median, IQR

At rest

On coughing

4, 8, 12, 16, 20, 24, 28, 32, 36, 40, 44, 48 hrs

Mean cumulative morphine consumption

PVB superior to TEB

am: ante meridiem
hr: hour
IQR: interquartile range
LA: local anaesthetic
mg: milligram
NA: not applicable
PCA: patient‐controlled analgesia
PCEA: patient‐controlled epidural analgesia
PVB: paravertebral blockade
TEB: thoracic epidural blockade
pm: post meridiem
SD: standard deviation
VAS: visual analogue scale;

Findings from all the studies are summarized in Table 2. Due to clinical heterogeneity and lack of reported data, we were only able to extract data from six studies with a total of 239 participants (De Cosmo 2002; Grider 2012; Kobayashi 2013; Matthews 1989; Messina 2009; Pintaric 2011) for meta‐analysis of VAS scores. Due to the heterogeneity of the studies, we used the random‐effects model to analyse standardized mean difference between the VAS scores of the PVB and TEB groups at each time point. We found no significant differences in analgesic efficacy of TEB and PVB in terms of VAS scores (on coughing/after physiotherapy) at any time points (see Table 3); we also calculated 95% prediction intervals to determine the distribution of values and underlying treatment effect. Because there were few trials in the analyses, the estimates of the treatment effects were imprecise, as shown by the 95% prediction intervals. The results were also statistically non‐significant.

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Table 3. VAS measurements by time points

Visual Analogue Scales

Studies

Effect of intervention

2 ‐ 6 hrs at rest

De Cosmo 2002

Grider 2012

Kobayashi 2013

Matthews 1989

Messina 2009

Pintaric 2011

No difference

Standard mean difference 0.32, 95% CI ‐0.30 to 0.94

P value = 0.31

95% PI ‐2.35 to 3.15

2 ‐ 6 hrs during coughing/on movement

De Cosmo 2002

Grider 2012

Pintaric 2011

No difference

Standard mean difference 0.41, 95% CI ‐0.20 to 1.03

P value = 0.06

95% PI ‐10.66 to 11.64

24 hrs at rest

De Cosmo 2002

Grider 2012Grider 2012

Kobayashi 2013

Matthews 1989

Messina 2009

Pintaric 2011

No difference

Standard mean difference 0.16, 95% CI ‐0.17 to 0.48

P value = 0.34

95% PI ‐0.25 to 0.69

24 hrs during coughing/on movement

De Cosmo 2002

Grider 2012

Pintaric 2011

No difference

Standard mean difference ‐0.23, 95% CI ‐0.58 to 0.12

P value = 0.20

95% PI ‐3.73 to 3.33

48 hrs at rest

De Cosmo 2002

Grider 2012

Kobayashi 2013

Messina 2009

Pintaric 2011

No difference

Standard mean difference ‐0.12, 95% CI ‐0.46 to 0.22

P value = 0.49

95% PI ‐1.26 to 1.14

48 hrs during coughing/on movement

De Cosmo 2002

Grider 2012

Pintaric 2011

No difference

Standard mean difference 0.25, 95% CI ‐0.16 to 0.66

P value = 0.22

95% PI ‐1.54 to 2.10

CI: confidence interval
95% PI: 95% prediction interval. Analysed using random‐events model
VAS: visual analogue scale

Acute pain at two to six hours

There was moderate‐quality evidence on acute pain at two to six hours. Six studies with 365 participants were included (De Cosmo 2002; Grider 2012; Kobayashi 2013; Matthews 1989; Messina 2009; Pintaric 2011). Comparing VAS scores at two to six hours at rest and on coughing/after physiotherapy, there was no statistically significant difference between the PVB and TEB groups (SMD 0.35, 95% CI ‐0.09 to 0.78, P value = 0.12, Analysis 3.1).

Acute pain at 24 hours

There was moderate‐quality evidence on acute pain at 24 hours. Six studies with 365 participants have been included (De Cosmo 2002; Grider 2012; Kobayashi 2013; Matthews 1989; Messina 2009; Pintaric 2011). Comparing VAS scores at 24 hours at rest and on coughing/after physiotherapy, there was no statistically significant difference between PVB and TEB groups (SMD 0.02, 95% CI ‐0.24 to 0.28, P value = 0.90, Analysis 3.2).

Acute pain at 48 hours

There was moderate‐quality evidence on acute pain at 48 hours. Five studies with 346 participants have been included (De Cosmo 2002; Grider 2012; Kobayashi 2013; Pintaric 2011; Messina 2009). Comparing VAS scores at 48 hours at rest and on coughing/after physiotherapy, there was no statistically significant difference between the PVB and TEB groups (SMD 0.02, 95% CI ‐0.26 to 0.30, P value = 0.90, Analysis 3.3).

The remaining studies where we were unable to pool the reported results in the meta‐analyses are summarized below, while the results of each are given in Table 2.

Four studies found PVB as effective as TEB in the postoperative period (Casati 2006; Gulbahar 2010; Ibrahim 2009; Perttunen 1995).

Casati 2006 was a single‐centre study carried out in Italy. Forty‐two consecutive participants undergoing elective thoracotomy for lung lobectomy were randomized into two groups, with 21 participants in the TEB group and 21 participants in the PVB group. Participants were followed up for 48 hours postoperatively: maximal drop in systolic blood pressure was recorded for each group, along with daily oxygenation and 12‐hourly record of VAS.

Gulbahar 2010 recruited 50 participants scheduled for elective thoracotomy in a single‐centred RCT in Turkey. Data from 25 participants were collected from the PVB group but only data from 19 out of 25 participants were analysed from the TEB group, due to catheter misplacement and early cessation of TEB blockade. The study team collected VAS scores from participants for three days post‐surgery as well as oxygen saturation, pulse rate, blood pressure, arterial blood gases and spirometry values.

Perttunen 1995 had three arms; 51 thoracotomy participants were randomly assigned to receive single‐shot intercostal blockade, continuous TEB or continuous PVB as analgesia. Only the results in the TEB and PVB groups were analysed in this review. Participants were followed up for 48 hours post‐surgery and pain was assessed with regular VAS scores at rest and when coughing. Segmental spread of sensory block in each group was recorded, as were morphine consumption, plasma bupivacaine, arterial blood gases, respiratory function tests and respiratory rate.

Ibrahim 2009 recruited 50 participants scheduled for elective thoracotomy, with 25 participants assigned to each group. Intra‐operative pulse rate and blood pressure were recorded and participants were followed up for 24 hours post‐surgery. The extent of sensory block and VAS scores were collected from both groups every four hours. Additional data were collected also for plasma cortisol and glucose levels, respiratory function tests and number of complications observed.

Three studies reported better pain relief with PVB than TEB (Kaiser 1998; Murkerjee 2010; Richardson 1999).

Kaiser 1998 recruited 30 participants who were undergoing thoracotomy in a single‐centred RCT in Switzerland. Fifteen participants were allocated to each group. and they did not differ significantly in terms of age, gender, type and duration of surgical procedures and pre‐operative respiratory function. Participants were followed up for five days after surgery and data on daily VAS scores, consumption of opioid analgesics, respiratory function tests and plasma level of bupivacaine were collected. The study found PVB to be as effective as TEB in acute pain control and also evidence that reported that PVB provided better pain relief on days two and three post‐surgery than TEB

Murkerjee 2010 was a single‐centred study carried out in India which recruited 60 thoracotomy participants. Thirty participants each were randomly allocated to the TEB and PVB groups. The effectiveness of the two regional techniques was assessed by the duration of analgesia from the initial bolus, and the time point when a participant requested additional pain relief was recorded as the end of the trial. The study found that single bolus PVB provided statistically significantly longer duration of pain relief compare with TEB (PVB mean 171.66 min (SD 77.31) versus TEB mean 105.83 min (SD 33.28), P value < 0.0001).

Richardson 1999 was the largest study, with 100 participants. In five participants, the insertion of a TEB catheter was not possible and they were excluded from the study, leaving 49 participants in the TEB group and 46 participants in the PVB group. VAS scores were collected both at rest and on coughing, along with respiratory function tests, oxygen saturation, plasma level of cortisol and glucose. The study concluded that the analgesic efficacy of PVB was superior to TEB with statistically significantly lower VAS scores both at rest and on coughing (P value = 0.02 and P value = 0.0001 respectively).

Only one study provided evidence that TEB provided superior analgesia compared to PVB. Bimston 1999 was a single‐centre study that recruited 50 participants. All participants were followed up for four days during their hospital stay. The respiratory function of participants was assessed by forced expiratory volume over one second (FEV₁) and forced vital capacity (FVC) measured pre‐operatively, at one hour, eight hours, 24 hours, 48 hours and 72 hours after surgery. Serum levels of bupivacaine and fentanyl were measured every six hours post‐surgery until 72 hours. VAS scores were recorded every eight hours after the operation until 96 hours.It was the only study to conclude that TEB was superior to PVB. Statistically significantly higher VAS scores were found in the PVB group for the first 40 hours, after which differences in quality of analgesia was no longer significant.

Failure of technique

Failure of technique was often not reported as an outcome, but was included as part of general results or the description of methods. There was moderate‐quality evidence on failure of technique. Four studies with 199 participants reported number of participants where inserted technique had failed were included (Gulbahar 2010; Kaiser 1998; Perttunen 1995; Richardson 1999). There was little heterogeneity and fixed‐effect analysis was used. Our analysis suggests there was a lower risk of failure of technique in participants receiving PVB, which was statistically significant. The failure rate was 1.98% (two events in 101 participants) for PVB while the rate for TEB was 11.22% (11 events in 98 participants ) (RR 0.27, 95% CI 0.09 to 0.86, P value = 0.03, Analysis 3.4)

In Gulbahar 2010, it was not possible to insert a TEB catheter in two out of 19 participants; all 25 PVB catheters were inserted successfully. Perttunen 1995 reported similar findings, with two out of 15 participants in the TEB group unable to have catheters sited and none reported from the PVB group.

In Richardson 1999,TEB catheter insertion was also unsuccessful in five out of 49 participants in the TEB group compared with none from the PVB group.

Kaiser 1998 was the only study in which both TEB and PVB catheters were misplaced (two from each group of 15 participants respectively).

Supplemental analgesia consumption

The use of supplemental analgesia was not reported in detail by the included studies. Types of additional analgesia included opiates and non‐steroidal anti‐inflammatory medication (NSAIDs). There were insufficient data for meta‐analysis and we have provided a narrative description in this review.

In Casati 2006, only the number of participants requiring rescue morphine analgesia was reported, and this was found to be similar between the two groups (4/21 TEB versus 5/21 PVB, P value = 0.99).

De Cosmo 2002 reported no statistically significant difference between mean ketolorac consumption between the PVB and TEB groups (mean 72 (SD 26.5 mg) PVB versus mean 75.8 (SD 28.8 mg) TEB).

In Grider 2012, morphine patient‐controlled analgesia (PCA) was prescribed for participants if it was felt that a regional technique failed to provide adequate analgesia. There were significantly more participants that required PCA in the PVB (local anaesthetic only) group compared to the other two groups (5/23 PVB, 3/18 TEB, 1/24 TEB with added opiate, P value < 0.05).

Gulbahar 2010 and Perttunen 1995 reported no statistical difference in mean cumulative morphine consumption between the PVB and TEB groups.

Kaiser 1998 reported lower nicomorphine administration in the PVB group compared with TEB, which reached statistical significance on postoperative day two.

In Kobayashi 2013, additional analgesia was only given to participants if VAS was greater than 6 mm, but the type of analgesic given was not specified. The authors recorded the frequency in the administration of additional analgesics and found no statistically significant difference between the TEB and PVB groups at any time points (Days 0, one and two).

Messina 2009 found statistically significantly higher cumulative morphine consumption in the PVB group compared to TEB (median 36, interquartile range (IQR) 22 to 42 mg PVB versus median 9, IQR 2 to 22 mg TEB).

Pintaric 2011 reported comparable mean consumption of piritramide (synthetic opioid) between the PVB and TEB groups with no statistically significant difference at six, 24 and 48 hours after surgery.

Similar results were also seen in Richardson 1999, where cumulative morphine consumption was statistically significantly lower in the PVB group in the first and second 24‐hour period (mean 85.5 (SD 30) mg PVB versus 105.8 (SD 20.4) mg TEB; P value = 0.008 and mean 210.7 (SD 63.8) mg PVB versus 262 (SD 67) mg TEB; P value = 0.005 respectively).

2. Minor complications

In this review, the included studies did not provide enough data to allow for pooling of results. Although the number of participants who developed a minor complication was reported in some studies, it was unclear whether these participants developed one or multiple complications. We have collated all available data and have separately analysed the risk of developing minor complications.

Hypotension (not requiring inotropes)

Hypotension was the most commonly reported minor complication, with eight included studies reporting episodes of low blood pressure that did not require inotropic support. Bimston 1999 described postural hypotension in one participant each from the TEB and PVB groups, with no statistically significant differences between the two groups. All other studies reported hypotension in the TEB group only.

Casati 2006 defined hypotension as a drop of more than 30% from baseline blood pressure. Four out of 21 participants in the TEB group suffered hypotension compared with no participants in the PVB group (P value = 0.04).

In Grider 2012, three participants in the TEB group suffered persistent hypotension on postoperative day two and received local anaesthetic infusion of lower concentration, and no reported hypotension in the PVB group.

Similarly in Gulbahar 2010, two participants from the TEB group had their epidural infusions stopped temporarily due to persistent hypotension, whereas no participants from the PVB group suffered hypotension.

Ibrahim 2009 recorded regular blood pressure reading intra‐operatively and postoperatively. Mean arterial pressure in the TEB group was significantly lower than that in the PVB group 20 minutes after injection of lower anaesthetic through infusion catheters and persisted until 10 hours after surgery. Hypotention (more than 30% decrease from baseline) was found in six participants from the TEB group and none from the PVB group.

Kobayashi 2013 described hypotension requiring the use of vasopressor in two out of 35 participants (PVB group) compared to five out of 35 participants (TEB group).

In Matthews 1989, hypotension was defined as a drop of 30 mmHg from baseline blood pressure recording. One participant from the TEB group was withdrawn from the study due to intractable hypotension and six further participants (out of a total of nine) suffered hypotension. No participants from the PVB group were found to be hypotensive.

Richardson 1999 described postoperative hypotension requiring cessation of infusion in seven out of 49 participants receiving epidural analgesia. There was no postoperative hypotension in participants receiving paravertebral analgesia.

There was moderate‐quality evidence on hypotension. Data were available from eight included trials (Bimston 1999; Casati 2006; Grider 2012; Gulbahar 2010; Ibrahim 2009; Kobayashi 2013; Matthews 1989; Richardson 1999) in a total of 445 participants. Overall, the risk of hypotension was significantly lower in the PVB group compared to TEB (RR 0.16, 95% CI 0.07 to 0.38, P value < 0.0001, Analysis 4.1).

Hypotension was not reported in Pintaric 2011 as fluid management of participants was protocolized to achieve desired oxygen delivery index (DO₂I) of more than 500 ml/min/m² by using colloid boluses (to optimize intravascular volume status), infusion of dobutamine (inotrope) and boluses of vasopressor. It was interesting to note that a significantly higher volume of colloid was required to achieve DO₂I in the TEB group compared with the PVB group (TEB 554 ml, 95% CI 456 to 652 versus PVB 196 ml, 95% CI 49 to 343, P value = 0.04). Higher doses of vasopressor were also required in the TEB group compared with the PVB group (TEB 40 µg, 95% CI 21 to 59 versus PVB 17 µg, 95% CI 8 to 25, P value = 0.04). These results suggest that the effect of TEB on the cardiovascular system was greater than PVB.

Postoperative ileus, nausea and vomiting

Postoperative ileus was not reported in any included studies. We defined nausea and vomiting as any report of either nausea or vomiting in the study participants. Our analysis found that the risk of nausea or vomiting was significantly lower in PVB (RR 0.48, 95% CI 0.30 to 0.75, I² statistic = 0%, P value = 0.001, Analysis 4.2). There was moderate‐quality evidence. Six studies with a total of 345 participants (49.4% of the total) reported postoperative nausea and vomiting (Bimston 1999; De Cosmo 2002; Ibrahim 2009; Kobayashi 2013; Perttunen 1995; Richardson 1999). Twenty‐three of 176 (13.1%) participants had nausea or vomiting following PVB, while 45/169 (26.6%) participants reported the same in the TEB group.

Excessive sedation

We defined excessive sedation as any report of change in mental status, drowsiness or somnolence. There was moderate‐quality evidence on excessive sedation. Three included studies with a total of 175 participants documented excessive sedation (Bimston 1999; Perttunen 1995; Richardson 1999). Our analysis found that the risk of excessive sedation was lower in the PVB group compared with the TEB group but this was not statistically significant (RR 0.84, 95% CI 0.57 to 1.24, P value = 0.39, Analysis 4.3)

Pruritis

There was moderate‐quality evidence on pruritis. Five included studies with 249 participants described pruritis as a minor complication from regional anaesthesia (Bimston 1999; De Cosmo 2002; Grider 2012; Gulbahar 2010; Perttunen 1995), and all reported higher incidence in the TEB group. Our analysis showed that the risk of developing pruritis was statistically significantly lower in the PVB compared to the TEB group (RR 0.29, 95% CI 0.14 to 0.59, P value = 0.0005, Analysis 4.4).

Urinary retention

There was moderate‐quality evidence on urinary retention. Urinary retention requiring bladder catheterization was noted in five included studies with 258 participants (Bimston 1999; De Cosmo 2002; Gulbahar 2010; Matthews 1989; Richardson 1999), all reporting higher incidence of urinary retention in the TEB groups compared with the PVB groups. The risk of urinary retention was statistically significantly lower in the PVB compared to the TEB group (RR 0.22, 95% CI 0.11 to 0.46, P value < 0.0001, Analysis 4.5).

3. Chronic pain at six months and one year

The incidence of chronic pain was very poorly reported, with two studies describing participants complaining of pain after hospital discharge (Grider 2012; Richardson 1999). Participants from Grider 2012 were followed up at 12 months, and 11 participants complained of ongoing chest pain. Six participants were described as suffering from intercostal neuralgia (two from the PVB group and four from the TEB group) and four participants had malignancy‐related pain (one from the PVB group and three from the TEB group).

At six‐month follow‐up, 10 participants from the TEB group reported persistent burning chest pain compared to three participants from the PVB group in Richardson 1999. The chronic pain in these participants was not related to tumour recurrence or infection. There were insufficient data for statistical analysis.

4 Duration of hospital stay and cost

Duration of hospital stay was reported in six included studies, with no statistically significant differences between the intervention groups (Bimston 1999; De Cosmo 2002; Gulbahar 2010; Kaiser 1998; Perttunen 1995; Richardson 1999). Three small studies with a total of 124 participants (De Cosmo 2002; Gulbahar 2010; Kaiser 1998) reported similar duration of hospital stay between the PVB and TEB groups (MD ‐0.41 days, 95% CI ‐1.54 to 0.72, P value = 0.48, Analysis 5.1). Their results concurred with three other included studies (Bimston 1999; Perttunen 1995; Richardson 1999), which reported median duration of stay (see Table 4). There was no statistically significant difference in duration of hospital stay between the PVB and TEB groups.

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Table 4. Duration of hospital stay

Study

Number of days PVB group (median, range)

Number of days TEB group (median, range)

Bimston 1999

5

6

Perttunen 1995

7.7 (6 ‐ 16)

7.3 (5 ‐ 11)

Richardson 1999

6.7 (4 ‐ 11)

6.7 (3 ‐ 16)

PVB: paravertebral blockade
TEB: thoracic epidural blockade

No included studies collected data on costs associated with each intervention.

Discussion

disponible en

Summary of main results

The limited evidence demonstrated no difference between PVB and TEB in 30‐day mortality, major complications and length of hospital stay following thoracotomy. In terms of analgesic efficacy, PVB was comparable to TEB, with a lower risk of failure of technique. PVB had a better minor complication profile with lower incidence of hypotension, nausea and vomiting, pruritis and urinary retention. Data were insufficient to compare PVB and TEB in chronic pain and health costs.

Overall completeness and applicability of evidence

The focus of many of the studies was the analgesia provided by PVB and TEB and minor complications in the peri‐operative period. There was limited evidence that suggests no difference in terms of 30‐day mortality, major complications and length of stay between the two techniques. The studies identified were insufficient to compare PVB and TEB in terms of chronic pain and costs.

In a number of studies, different volumes and concentration of local anaesthetic were used as loading dose and infusions for the two blockades, which made it difficult to compare the results meaningfully. These differences in study methodology mean that results from our review should be interpreted with caution (Agreements and disagreements with other studies or reviews).

Outcomes reported and compared in this review are only applicable to adults undergoing elective open thoracotomy and should not be extrapolated to minimally‐invasive surgery or cardiac surgery.

Quality of the evidence

We found the quality of evidence in terms of 30‐day mortality and major complications to be of low to very low quality due to risks of bias, imprecision with low number of studies, and inconsistency. All 14 trials included in this review recruited relatively small numbers of participants, with the smallest study covering 20 participants (Matthews 1989) and the largest recruiting 100 participants (Richardson 1999). All included studies were described as RCTs but a significant proportion of the studies did not give any information on the method of randomization (eight out of 14 studies), and little effort was made to ensure allocation concealment, or blinding of participants or outcome assessors. Whilst the authors recognized that participant safety meant that it would sometimes be necessary that staff caring for participants should know to which treatment group they were allocated, the review authors believe that assessors should be blinded to minimize reporting bias in measured outcomes. Only three studies (Casati 2006; Grider 2012; Ibrahim 2009) attempted to blind participants, and four studies blinded outcome assessors (Casati 2006; Grider 2012; Ibrahim 2009; Pintaric 2011). No studies performed formal assessment of effectiveness of allocation concealment and blinding.

We found the quality of evidence in terms of analgesic efficacy to be moderate, due to the risks of bias (performance and detection bias). Acute pain was the main focus of all the included studies but the timing of VAS assessments varied (see Table 2). Although VAS requires little training to administer and score, there is no consensus on what represents a clinically meaningful difference, with some researchers suggesting a minimum difference of 1.37 cm (Hawker 2011) or 2 cm to counter imprecision (DeLoach 1998). Unfortunately, the majority of studies did not report VAS in enough detail to be included in the meta‐analysis. In some studies, it was not clear whether VAS results were tested for normality. Kaiser 1998 also reported a categorical VAS of 0 to 4 as a continuous variable (mean and SD). The duration of participant follow‐up was variable in studies, ranging from only three hours, through 48 hours and up to five days. In studies of shorter duration, regional blockade was terminated and removed early, potentially missing any associated benefits or differences between the treatment groups. Supplementary analgesia and rescue analgesia given to participants could provide a second measure of quality of pain control, but this was not measured regularly in the included studies. Two studies included participant satisfaction as an additional measure of successful pain relief (Casati 2006; De Cosmo 2002) but this could be affected by factors unrelated to pain management.

Potential biases in the review process

We strictly followed the review process recommended by Cochrane. Two review authors independently assessed for inclusion all the candidate studies we identified as a result of the search strategy. Two review authors independently extracted the data from the included studies using the agreed form. Two review authors independently assessed risks of bias for each study using the criteria outlined in the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2011). There should be no or minimal biases in the review process.

Agreements and disagreements with other studies or reviews

We identified three systematic reviews which addressed our research question and compared only PVB and TEB (Baidya 2014; Davies 2006; Norum 2010). Our findings that PVB and TEB provided comparable pain relief concurred with two of the reviews and the majority of published studies (Table 2; Baidya 2014; Davies 2006).

Davies 2006 included 10 RCTs with 520 participants undergoing thoracic surgery. They found no significant difference in VAS scores (at rest) at four to eight, 24 and 48 hours, or in morphine consumption. Similarly, Baidya 2014 reported comparable analgesia at four to eight, 24 and 48 hours, both at rest and on coughing or during movement.

Our review found that at certain time points PVB appeared to provide better analgesia, which was not the case in other reviews. This may be due to the paucity of good‐quality data and eligibility of only a few studies for meta‐analysis. We elected not to calculate the mean and SD if only median and interquartile range were reported, which was the case in Baidya 2014, due to the high level of statistical assumptions. In contrast, Norum 2010 provided a systematic narrative review, because of the heterogeneity and poor quality of the studies that were available. The authors did not feel that conclusions could be drawn from the available data on analgesia or side‐effect profile. They felt strongly that the method of insertion (level of insertion too low) and regimen (no opiate or adrenaline) employed with TEB in some published studies were suboptimal, potentially introducing prejudice against TEB. They further argued that measurement of pain at rest was not the best indicator of pain control and pain during deep inspiration was a more meaningful measure to distinguish effective from less effective analgesia. The authors also issued a warning about the apparent lack of complications in the PVB group, citing their own experience that PVB complications, although infrequent, could still be serious. Based on their findings, they could only recommend the use of PVB if TEB was not technically feasible.

Kotze 2009 carried out a systematic review into the effectiveness and safety of different techniques of paravertebral block for analgesia after thoracotomy. The authors found a trend towards improved pain relief if PVB was established prior to skin incision. This potential bias was worsened in some studies by the insertion and use of TEB pre‐operatively and during operation, thereby favouring the effects of TEB.Their review concluded that continuous infusion techniques were superior to bolus techniques for maintaining analgesia, and higher doses of local anaesthetic produced better analgesia and pulmonary function. The only reported complications from PVB were related to local anaesthetic toxicity (convulsions and cardiac arrhythmias) which resolved on termination of local anaesthetic infusion. Our review identified similar variations in PVB techniques, including timing and method of insertion, the use of bolus and infusions and different concentrations of local anaesthetic. In our review only one study (Richardson 1999) reported one participant from the PVB group and three participant from the TEB group who developed cardiac arrhythmias with unknown cause.

Joshi 2008 provided a systematic review of all regional techniques for post‐thoracotomy analgesia and included other regional blockade (intrathecal, intercostal, intrapleural) and systemic analgesia. The authors concluded that paravertebral block (local anaesthetic only) and thoracic epidural (local anaesthetic and opiate) provided the best analgesia, and that either technique could be recommended.

Overall, complications were not reported regularly. Our review found a more favourable side‐effect profile of PVB compared with TEB, which concurred with similar findings in Baidya 2014, Davies 2006 and Joshi 2008. All three reviews agreed that the incidence of major complications such as pneumonia, delirium and minor complications such as urinary retention, hypotension, pruritis and nausea and vomiting in participants, were reduced with PVB. It is important to note that all of the studies included in all of the reviews were designed to examine analgesia provided by PVB and TEB, and that complications could be underreported as a result.

1 Study flow diagram (Search dates October 2013, reran January 2015)
Figuras y tablas -
Figure 1

1 Study flow diagram (Search dates October 2013, reran January 2015)

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.
Figuras y tablas -
Figure 2

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.
Figuras y tablas -
Figure 3

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

Forest plot of comparison: 2 Major complications, outcome: 2.1 Cardiovascular complications.
Figuras y tablas -
Figure 4

Forest plot of comparison: 2 Major complications, outcome: 2.1 Cardiovascular complications.

Forest plot of comparison: 2 Major complications, outcome: 2.2 Respiratory complications.
Figuras y tablas -
Figure 5

Forest plot of comparison: 2 Major complications, outcome: 2.2 Respiratory complications.

Comparison 1 30‐day mortality, Outcome 1 30‐day mortality.
Figuras y tablas -
Analysis 1.1

Comparison 1 30‐day mortality, Outcome 1 30‐day mortality.

Comparison 2 Major complications, Outcome 1 Cardiovascular complications.
Figuras y tablas -
Analysis 2.1

Comparison 2 Major complications, Outcome 1 Cardiovascular complications.

Comparison 2 Major complications, Outcome 2 Respiratory complications.
Figuras y tablas -
Analysis 2.2

Comparison 2 Major complications, Outcome 2 Respiratory complications.

Comparison 2 Major complications, Outcome 3 Neurological complication (Delirium).
Figuras y tablas -
Analysis 2.3

Comparison 2 Major complications, Outcome 3 Neurological complication (Delirium).

Comparison 2 Major complications, Outcome 4 Unexpected ITU admission.
Figuras y tablas -
Analysis 2.4

Comparison 2 Major complications, Outcome 4 Unexpected ITU admission.

Comparison 3 Acute pain, Outcome 1 VAS scores 2 to 6 hours.
Figuras y tablas -
Analysis 3.1

Comparison 3 Acute pain, Outcome 1 VAS scores 2 to 6 hours.

Comparison 3 Acute pain, Outcome 2 VAS scores at 24 hours.
Figuras y tablas -
Analysis 3.2

Comparison 3 Acute pain, Outcome 2 VAS scores at 24 hours.

Comparison 3 Acute pain, Outcome 3 VAS scores at 48 hours.
Figuras y tablas -
Analysis 3.3

Comparison 3 Acute pain, Outcome 3 VAS scores at 48 hours.

Comparison 3 Acute pain, Outcome 4 Failure of technique.
Figuras y tablas -
Analysis 3.4

Comparison 3 Acute pain, Outcome 4 Failure of technique.

Comparison 4 Minor complications, Outcome 1 Hypotension.
Figuras y tablas -
Analysis 4.1

Comparison 4 Minor complications, Outcome 1 Hypotension.

Comparison 4 Minor complications, Outcome 2 Nausea and vomiting.
Figuras y tablas -
Analysis 4.2

Comparison 4 Minor complications, Outcome 2 Nausea and vomiting.

Comparison 4 Minor complications, Outcome 3 Excessive sedation.
Figuras y tablas -
Analysis 4.3

Comparison 4 Minor complications, Outcome 3 Excessive sedation.

Comparison 4 Minor complications, Outcome 4 Pruritis.
Figuras y tablas -
Analysis 4.4

Comparison 4 Minor complications, Outcome 4 Pruritis.

Comparison 4 Minor complications, Outcome 5 Urinary retention.
Figuras y tablas -
Analysis 4.5

Comparison 4 Minor complications, Outcome 5 Urinary retention.

Comparison 5 Hospital stay, Outcome 1 Duration of hospital stay.
Figuras y tablas -
Analysis 5.1

Comparison 5 Hospital stay, Outcome 1 Duration of hospital stay.

Summary of findings for the main comparison. Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (30‐day mortality and major complications)

Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (30‐day mortality and major complications)

Patient or population: Patients undergoing thoracotomy
Setting: In hospitals, worldwide
Intervention: Paravertebral blockade
Comparison: Thoracic epidural blockade

Outcomes

Anticipated absolute effects* (95% CI)

Relative effect
(95% CI)

№ of participants
(studies)

Quality of the evidence
(GRADE)

Comments

Risk with PVB

Risk with TEB

30‐day mortality

Study population

RR 1.28
(0.39 to 4.24)

125
(2 RCTs)

⨁⨁◯◯
LOW 1

Only 2 studies reported number of participants that died within 30 days

63 per 1000

80 per 1000
(24 to 265)

Low

64 per 1000

82 per 1000
(25 to 271)

Cardiovascular complications

Study population

Hypotension requiring inotropes RR 0.30
(0.01 to 6.62)

Arrhythmias

RR 0.36 (0.04, 3.29)

Myocardial Infarction

RR 3.19 (0.13, 76.42)

114
(2 RCTs)

⨁⨁◯◯
LOW 1

Only 2 studies reported number of participants with major cardiovascular complications

37 per 1000

22 per 1000
(4 to 105)

Moderate

111 per 1000

64 per 1000
(13 to 311)

Respiratory complications

Study population

RR 0.62
(0.26 to 1.52)

280
(5 RCTs)

⨁⨁◯◯
LOW 3

All respiratory outcomes combined

134 per 1000

83 per 1000
(35 to 204)

Moderate

163 per 1000

101 per 1000
(42 to 248)

Neurological complication (Delirium)

Study population

RR 0.30
(0.09 to 0.99)

125
(2 RCTs)

⨁⨁⨁◯
MODERATE 1 3

Definition of delirium unclear

156 per 1000

47 per 1000
(14 to 155)

Moderate

264 per 1000

79 per 1000
(24 to 261)

*The risk in the intervention group (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).

CI: Confidence interval; RR: Risk ratio

GRADE Working Group grades of evidence
High quality: We are very confident that the true effect lies close to that of the estimate of the effect
Moderate quality: We are moderately confident in the effect estimate: The true effect is likely to be close to the estimate of the effect, but there is a possibility that it is substantially different
Low quality: Our confidence in the effect estimate is limited: The true effect may be substantially different from the estimate of the effect
Very low quality: We have very little confidence in the effect estimate: The true effect is likely to be substantially different from the estimate of effect

1Only two studies reported outcome. Downgraded for small number of events, insufficient data available and for imprecision.

2Only one study reported outcome. Downgraded for small numbers of events, insufficient data available and for imprecision.

3Downgraded for lack of definition of delirium

Figuras y tablas -
Summary of findings for the main comparison. Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (30‐day mortality and major complications)
Summary of findings 2. Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (acute pain)

Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (acute pain)

Patient or population: Patients undergoing thoracotomy
Settings: In hospitals, worldwide
Intervention: Paravertebral blockade
Comparison: thoracic epidural blockade

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

No of Participants
(studies)

Quality of the evidence
(GRADE)

Comments

Assumed risk

Corresponding risk

Thoracic epidural blockade (TEB)

Paravertebral blockade (PVB)

VAS score at 2 ‐ 6 hours (at rest)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 1.0 to 3.4

The SMD VAS score at 2 ‐ 6 hours (at rest) in the PVB groups was
0.32 higher

0.30 lower to 0.94 higher

239
(6 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represents less pain and better pain control

VAS score at 2 ‐ 6 hours (on coughing/after physiotherapy)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 2.2 to 3.4

The SMD VAS score at 2 ‐ 6 hours (on coughing/after physiotherapy) in the PVB groups was
0.41 higher

0.20 lower to 1.03 higher

126
(3 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represent less pain and better pain control

VAS score at 24 hours (at rest)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 1.0 to 3.0

The SMD VAS score at 24hours (at rest) in the PVB groups was
0.16 higher

0.17 lower to 0.48 higher

239
(6 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represent less pain and better pain control

VAS score at 24 hours (on coughing/after physiotherapy)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 2.6 to 3.7

The SMD VAS score at 24 hours (on coughing/after physiotherapy) in the PVB groups was
0.23 lower

0.58 lower to 0.12 higher

126
(3 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represent less pain and better pain control

VAS scores at 48 hours (at rest)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 1.3 to 3.5

The SMD VAS scores at 48 hours (at rest) in the PVB groups was
0.12 lower

0.46 lower to 0.22 higher

220
(5 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represent less pain and better pain control

VAS scores at 48 hours (on coughing/after physiotherapy)

Score from 0 ‐ 10

The mean VAS score ranged across TEB groups from 2.1 to 3.6

The SMD VAS scores at 48 hours (on coughing/after physiotherapy) in the PVB groups was
0.25 higher

0.16 lower to 0.66 higher

126
(3 studies)

⊕⊕⊕⊝
moderate1

Lower VAS score represent less pain and better pain control

Failure of technique

(Number of participants)

Study population

RR 0.27
(0.09 to 0.86)

199
(4 studies)

⊕⊕⊕⊝
moderate1

Lower failure technique indicates more blocks inserted successfully.

112 per 1000

30 per 1000
(10 to 97)

Moderate

119 per 1000

32 per 1000
(11 to 102)

*The basis for the assumed risk (e.g. the median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
CI: Confidence interval; RR: Risk ratio; SMD: Standardized mean difference

GRADE Working Group grades of evidence
High quality: Further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: We are very uncertain about the estimate.

1Studies downgraded due to performance and detection bias.

Figuras y tablas -
Summary of findings 2. Paravertebral blockade compared to thoracic epidural blockade for patients undergoing thoracotomy (acute pain)
Table 1. Technical aspects of PVB and TEB catheters

PVB

TEB

STUDY

METHOD OF INSERTION

METHOD OF USE

POSTOPERATIVE MEDICATION

METHOD OF INSERTION

METHOD OF USE

POSTOPERATIVE MEDICATION

Bimston 1999

Inserted under direct vision by surgeon

18 ml 0.5% bupivacaine bolus followed by infusion of 0.1% bupivacaine with 10 μg/ml fentanyl, 10 ‐ 15 ml/hr

infusion of 0.1% bupivacaine with 10 μg/ml fentanyl, 10 ‐ 15ml/min

Percutaneously by landmark technique before induction of GA

Uncertain whether catheter was used during operation

Infusion of 0.1% bupivacaine with 10 μg/ml fentanyl, 10 ‐ 15 ml/hr

Casati 2006 I

Percutaneously by landmark technique before induction of GA

Pre‐op Injections by landmark technique before induction of GA

15 ml of 0.75% ropivacaine

infusion of 0.2% ropivacaine at 5 ‐ 10ml/hr

Percutaneously by landmark technique before induction of GA

5 ml bolus of 0.75% ropivacaine

infusion of 0.2% ropivacaine at 5 ‐ 10 ml/hr

De Cosmo 2002

Inserted under direct vision by surgeons

Used at the end of operation only

20 ml of 0.475% ropivacaine as loading dose, infusion of 0.3% ropivacaine at 5 ml/hr post‐surgery

Percutaneously by landmark technique before induction of GA

5 ml bolus of 0.2% ropivacaine and sufentanil 10 µg given as bolus. Catheter used during operation if required

Infusion of 0.2% ropivacaine with 0.75 µg/ml of sufentanil at 5 ml/hr

Grider 2012

Inserted under direct vision by surgeon

Used at the end of the operation only

0.25% bupivacaine at 8 ml/hr

Percutaneously by landmark technique before induction of GA

Used at the end of operation

0.25% bupivacaine 2 ml/hr with 1 ml every 10 min PCEA with or without hydromorphine

Gulbahar 2010

Inserted under direct vision by surgeon

Used at the end of operation only

0.25% bupivacaine infusion at 0.0 ml/kg/hr PCEA

Percutaneously by landmark technique before induction of GA

Used at the end of operation

5 ml of 0.25% bupivacaine bolus, followed by 0.0 ml/kg/hr PCEA

Ibrahim 2009

Percutaneously by landmark technique before induction of GA

15 ‐ 20 ml 0.5% ropivacaine bolus followed by 0.375% ropivacaine 0.1 ml/kg/hr infusion

0.375% ropivacaine 0.1 ml/kg/hr infusion

Percutaneously by landmark technique before induction of GA

5 ‐ 8 ml of 0.5% ropivacaine bolus followed by 0.375% ropivacaine 0.1 ml/kg.hr infusion

0.375% ropivacaine 0.1 ml/kg/hr infusion

Kaiser 1998

Inserted under direct vision by surgeon

Used at the end of operation only

20 ml 0.5% bupivacaine bolus followed by 0.1 ml/kg/hr of 0.5% bupivacaine

Percutaneously by landmark technique before induction of GA

0.5% bupivacaine at 4 ‐ 6 ml/hr infusion during operation

4 ‐ 8 ml/hr of 0.25 ‐ 0.375% bupivacaine with 2 μg/ml fentanyl

Kobayashi 2013

Inserted under direct vision by surgeon

Used at the end of operation only

10 ml 0.375% ropivacaine bolus followed by 0.2% ropivacaine with fentanyl 9.5 μg/ml at 5 ml/hr infusion

Percutaneously by landmark technique before induction of GA

Used at the end of operation

5 ml 0.2% ropivacaine bolus followed by 0.2% ropivacaine with fentanyl 9.5 μg/ml at 5 ml/hr infusion

Matthews 1989

Percutaneously by landmark at the end of procedure

Used at the end of operation only

10 ml 0.25% bupivacaine bolus followed by infusion at 5 ml/hr

Percutaneously by landmark technique at the end of procedure

Used at the end of operation

10 ml 0.25% bupivacaine bolus followed by infusion at 5 ml/hr

Messina 2009

Percutaneously by landmark technique before induction of GA

Used at the end of operation only

0.125% levobupivacaine with fentanyl 2 μg/ml at 0.08 ml/kg/hr infusion

Percutaneously by landmark technique before induction of GA

Used at the end of operation

0.25% levobupivacaine with fentanyl 1.6 μg/ml at 0.1 ml/kg/hr infusion

Murkerjee 2010

Percutaneously by landmark technique before induction of GA

Used at the end of operation only

15 ml of 0.25% bupivacaine with 50μg of fentanyl bolus

Percutaneously by landmark technique before induction of GA

Used at the end of operation

7.5 ml of 0.25% bupivacaine with 50 μg of fentanyl bolus

Perttunen 1995

Inserted by surgeon under direct vision

Used at the end of operation only

0.25% bupivacaine bolus according to height, infusion of 4 ml/hr, 6 ml/hr, 8 ml/hr

Percutaneously by landmark technique before induction of GA

Used at the end of operation

0.25% bupivacaine bolus according to height, infusion of 4 ml/hr, 6 ml/hr, 8 ml/hr

Pintaric 2011

Percutaneously by landmark technique before induction of GA

0.5% levopubivacaine with 30 μg/kg morphine, dose depends on height

0.125% levobupivacaine with 20 μg/ml morphine infusion at 0.1 ml/kg/hr with PCEA

Percutaneously by landmark technique before induction of GA

0.25% levopubivacaine with 30 μg/kg morphine, dose depends on height

0.125% levobupivacaine with 20 μg/ml morphine infusion at 0.1 ml/kg/hr with PCEA

Richardson 1999

Inserted by surgeon under direct vision

Pre‐op Injections by landmark technique before induction of GA

20 ml of 0.5% bupivacaine

20 ml bolus of 0.5% bupivacaine, followed by infusion at 0.1 ml/kg/hr

Percutaneously by landmark technique before induction of GA

10 ‐ 15 ml bolus of 0.25% bupivacaine

10 ml bolus of 0.25% bupivacaine, followed by infusion at 0.1 ml/kg/hr

GA: general anaesthesia
hr: hour
kg: kilogram
ml: millilitres
PCEA: patient‐controlled epidural analgesia
PVB: paravertebral blockade
TEB: thoracic epidural blockade
µg: micrograms

Figuras y tablas -
Table 1. Technical aspects of PVB and TEB catheters
Table 2. VAS measurements by study

STUDY

VAS range

VAS reported

Timing of VAS

Time points VAS reported

Supplementary analgesia

CONCLUSION

Bimston 1999

0 ‐ 10

Mean

At rest

8, 16, 24, 32, 49, 48, 56, 64, 72, 80, 88, 96 hrs

Not reported

TEB superior to PVB for first 32 hrs

Casati 2006

0 ‐ 10

Mean (SD)

At rest

On coughing

Recovery, 12, 24, 48 hrs

Not reported

PVB as effective as TEB

De Cosmo 2002

0 ‐ 10

Mean (SD)

At rest

On movement

1, 4, 8, 12, 24, 36, 48 hrs

Overall mean consumption of ketolorac reported

PVB as effective as TEB

Lower VAS scores in TEB first 8 hrs

Grider 2012

0 ‐ 10

Mean (SD)

At rest

During physiotherapy

Recovery, day 1 am, day 2 am/pm, day 3 am/pm, day 4 am

Number of participants in whom technique failed and PCA prescribed

PVB as effective as TEB (plain LA) however TEB with opiate was superior

Gulbahar 2010

0 ‐ 10

Mean

At rest

Day 1, 2, 3

Daily number of PCEA request

PVB as effective as TEB

Ibrahim 2009

0 ‐ 5

Mean

At rest

4, 8, 12, 16, 20, 24 hrs

Rescue morphine recorded but not published

PVB as effective as TEB

Kaiser 1998

0 ‐ 4

Mean (SD)

At rest

Day 0, 1, 2, 3, 4, 5

Mean daily consumption of nicomorphine

PVB as effective as TEB

PVB superior at 72 and 96 hrs

Kobayashi 2013

0 ‐ 10

Mean (SD)

At rest

On coughing

On exercise

2, 5, 16, 20, 24, 48 hrs

Frequency of additional analgesic (non‐specified)

PVB as effective as TEB

Matthews 1989

0 ‐ 10

Mean (SD)

At rest

4, 12, 24 hrs

Not recorded

PVB as effective as TEB

Messina 2009

0 ‐ 10

Mean (SD)

At rest

On movement

Recovery, 6, 24, 48, 72 hrs

Median cumulative morphine daily (mg)

PVB as effective as TEB

Murkerjee 2010

NA

NA

NA

NA

NA

Single bolus PVB superior, lasted statistically significantly longer than TEB

PVB: 171.66 (77.31) vs TEB: 105.83 (33.28)

Perttunen 1995

0 ‐ 5

Mean (Range)

At rest

On coughing

1, 2, 4, 6, 20, 24, 30, 48 hrs

Mean cumulative PCA morphine consumption every 3 hrs

PVB as effective as TEB

Pintaric 2011

0 ‐ 10

Mean (SD)

At rest

After physiotherapy

6, 24, 48 hrs

Mean consumption of piritramide

PVB as effective as TEB

Richardson 1999

0 ‐ 10

Mean, median, IQR

At rest

On coughing

4, 8, 12, 16, 20, 24, 28, 32, 36, 40, 44, 48 hrs

Mean cumulative morphine consumption

PVB superior to TEB

am: ante meridiem
hr: hour
IQR: interquartile range
LA: local anaesthetic
mg: milligram
NA: not applicable
PCA: patient‐controlled analgesia
PCEA: patient‐controlled epidural analgesia
PVB: paravertebral blockade
TEB: thoracic epidural blockade
pm: post meridiem
SD: standard deviation
VAS: visual analogue scale;

Figuras y tablas -
Table 2. VAS measurements by study
Table 3. VAS measurements by time points

Visual Analogue Scales

Studies

Effect of intervention

2 ‐ 6 hrs at rest

De Cosmo 2002

Grider 2012

Kobayashi 2013

Matthews 1989

Messina 2009

Pintaric 2011

No difference

Standard mean difference 0.32, 95% CI ‐0.30 to 0.94

P value = 0.31

95% PI ‐2.35 to 3.15

2 ‐ 6 hrs during coughing/on movement

De Cosmo 2002

Grider 2012

Pintaric 2011

No difference

Standard mean difference 0.41, 95% CI ‐0.20 to 1.03

P value = 0.06

95% PI ‐10.66 to 11.64

24 hrs at rest

De Cosmo 2002

Grider 2012Grider 2012

Kobayashi 2013

Matthews 1989

Messina 2009

Pintaric 2011

No difference

Standard mean difference 0.16, 95% CI ‐0.17 to 0.48

P value = 0.34

95% PI ‐0.25 to 0.69

24 hrs during coughing/on movement

De Cosmo 2002

Grider 2012

Pintaric 2011

No difference

Standard mean difference ‐0.23, 95% CI ‐0.58 to 0.12

P value = 0.20

95% PI ‐3.73 to 3.33

48 hrs at rest

De Cosmo 2002

Grider 2012

Kobayashi 2013

Messina 2009

Pintaric 2011

No difference

Standard mean difference ‐0.12, 95% CI ‐0.46 to 0.22

P value = 0.49

95% PI ‐1.26 to 1.14

48 hrs during coughing/on movement

De Cosmo 2002

Grider 2012

Pintaric 2011

No difference

Standard mean difference 0.25, 95% CI ‐0.16 to 0.66

P value = 0.22

95% PI ‐1.54 to 2.10

CI: confidence interval
95% PI: 95% prediction interval. Analysed using random‐events model
VAS: visual analogue scale

Figuras y tablas -
Table 3. VAS measurements by time points
Table 4. Duration of hospital stay

Study

Number of days PVB group (median, range)

Number of days TEB group (median, range)

Bimston 1999

5

6

Perttunen 1995

7.7 (6 ‐ 16)

7.3 (5 ‐ 11)

Richardson 1999

6.7 (4 ‐ 11)

6.7 (3 ‐ 16)

PVB: paravertebral blockade
TEB: thoracic epidural blockade

Figuras y tablas -
Table 4. Duration of hospital stay
Comparison 1. 30‐day mortality

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 30‐day mortality Show forest plot

2

125

Risk Ratio (M‐H, Fixed, 95% CI)

1.28 [0.39, 4.24]

Figuras y tablas -
Comparison 1. 30‐day mortality
Comparison 2. Major complications

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Cardiovascular complications Show forest plot

2

Risk Ratio (M‐H, Random, 95% CI)

Subtotals only

1.1 Hypotension requiring inotropic support

1

19

Risk Ratio (M‐H, Random, 95% CI)

0.30 [0.01, 6.62]

1.2 Arrhythmia

1

95

Risk Ratio (M‐H, Random, 95% CI)

0.36 [0.04, 3.29]

1.3 Myocardial infarction

1

95

Risk Ratio (M‐H, Random, 95% CI)

3.19 [0.13, 76.42]

2 Respiratory complications Show forest plot

5

280

Risk Ratio (M‐H, Random, 95% CI)

0.62 [0.26, 1.52]

2.1 Postoperative ventilatory support

1

75

Risk Ratio (M‐H, Random, 95% CI)

0.39 [0.02, 7.88]

2.2 Acute carbon dioxide retention

1

30

Risk Ratio (M‐H, Random, 95% CI)

1.2 [0.47, 3.09]

2.3 Pneumonia

3

175

Risk Ratio (M‐H, Random, 95% CI)

0.38 [0.10, 1.45]

3 Neurological complication (Delirium) Show forest plot

2

125

Risk Ratio (M‐H, Fixed, 95% CI)

0.31 [0.09, 1.00]

4 Unexpected ITU admission Show forest plot

2

139

Risk Ratio (M‐H, Fixed, 95% CI)

0.63 [0.19, 2.07]

Figuras y tablas -
Comparison 2. Major complications
Comparison 3. Acute pain

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 VAS scores 2 to 6 hours Show forest plot

6

Std. Mean Difference (IV, Random, 95% CI)

Subtotals only

1.1 VAS at rest

6

239

Std. Mean Difference (IV, Random, 95% CI)

0.32 [‐0.30, 0.94]

1.2 VAS on coughing/after physiotherapy

3

126

Std. Mean Difference (IV, Random, 95% CI)

0.41 [‐0.20, 1.03]

2 VAS scores at 24 hours Show forest plot

6

Std. Mean Difference (IV, Random, 95% CI)

Subtotals only

2.1 VAS at rest

6

239

Std. Mean Difference (IV, Random, 95% CI)

0.16 [‐0.17, 0.48]

2.2 VAS on coughing/after physiology

3

126

Std. Mean Difference (IV, Random, 95% CI)

‐0.23 [‐0.58, 0.12]

3 VAS scores at 48 hours Show forest plot

5

Std. Mean Difference (IV, Random, 95% CI)

Subtotals only

3.1 VAS at rest

5

220

Std. Mean Difference (IV, Random, 95% CI)

‐0.12 [‐0.46, 0.22]

3.2 VAS on coughing/after physiotherapy

3

126

Std. Mean Difference (IV, Random, 95% CI)

0.25 [‐0.16, 0.66]

4 Failure of technique Show forest plot

4

199

Risk Ratio (M‐H, Fixed, 95% CI)

0.27 [0.09, 0.86]

Figuras y tablas -
Comparison 3. Acute pain
Comparison 4. Minor complications

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Hypotension Show forest plot

8

445

Risk Ratio (M‐H, Fixed, 95% CI)

0.16 [0.07, 0.38]

2 Nausea and vomiting Show forest plot

6

345

Risk Ratio (M‐H, Fixed, 95% CI)

0.48 [0.30, 0.75]

3 Excessive sedation Show forest plot

3

175

Risk Ratio (M‐H, Fixed, 95% CI)

0.84 [0.57, 1.24]

4 Pruritis Show forest plot

5

249

Risk Ratio (M‐H, Fixed, 95% CI)

0.29 [0.14, 0.59]

5 Urinary retention Show forest plot

5

258

Risk Ratio (M‐H, Fixed, 95% CI)

0.22 [0.11, 0.46]

Figuras y tablas -
Comparison 4. Minor complications
Comparison 5. Hospital stay

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Duration of hospital stay Show forest plot

3

124

Mean Difference (IV, Fixed, 95% CI)

‐0.41 [‐1.54, 0.72]

Figuras y tablas -
Comparison 5. Hospital stay