Study of Pain Management Techniques Following Anterior Cruciate Ligament Repair Surgery
|Anterior Cruciate Ligament Reconstruction||Procedure: Hamstrings block Procedure: Obturator block Procedure: Control group||Phase 2 Phase 3|
|Study Design:||Allocation: Randomized
Intervention Model: Parallel Assignment
Masking: Double Blind (Participant, Care Provider)
Primary Purpose: Treatment
|Official Title:||Comparison of Efficacy and Safety of Perihamstring Local Anesthetic Injection to Obturator Nerve Block When Combined With Subsartorial Saphenous Block for Anterior Cruciate Ligament Repair. A Randomized Double Blinded Study.|
- Post-operative pain scores at admission to PACU [ Time Frame: Baseline ]The primary outcome will be post-operative pain scores at I hour after arrival in PACU.
- Pain scores at 4 hours of arrival to PACU [ Time Frame: 4 hours ]patients will be assessed for pain scores at rest and movement after 4 hours of arrival to the recovery from the operating room
- first 24 pain scores [ Time Frame: Day1 ]Patients will be provided with a diary to document pain scores every 6 hourly thereafter until 24 hours after their time of arrival in PACU (time 0). Patients will be discharged home along with a data collection sheet for documenting pain scores, analgesic consumption and side effects at various time intervals.
|Study Start Date:||June 2013|
|Study Completion Date:||August 2015|
|Primary Completion Date:||August 2015 (Final data collection date for primary outcome measure)|
Experimental: Group 1
Procedure: Hamstrings block
patients enrolled in the study will receive subsartorial saphenous nerve block in all the three groups. Patients in group 1 will receive perimuscular injections around the gracilis and semi-tendinosus muscles. The needle is redirected to the fascial plane between Sartorius and gracilis muscle after the sub-sartorial canal block where 7.5 ml of 0.5% ropivacaine is injected around the muscle. The needle is further advanced to the fascial planes between semimembranosus and semitendinosus and an additional 7.5 ml of 0.5% ropivacaine will be injected around the semitendinosus muscle. Following this a sham injection of 10mL of saline for the anterior division of obturator nerve will also be performed as in group 2 to ensure blinding.
Other Name: perimuscular injections
Active Comparator: Group 2
Procedure: Obturator block
Patients in group 2 will receive anterior division of obturator nerve block along with subsartorial canal block. After ensuring aseptic precautions, the saphenous nerve block is performed similar to that as in group 1. The anterior branch of obturator nerve will be visualised in the proximal thigh medial to femoral vessels between adductor longus and adductor brevis. A 22 gauge 90 mm PNS block needle will be inserted under ultrasound guidance to reach the anterior division of obturator nerve confirmed with neurostimulation followed by injection of 10 ml of 0.5% ropivacaine around the nerve. This group will receive sham injection of 15mL of saline around semitendinosus and semimembranosus as in group 1
Other Name: anterior division obturator nerve block
Sham Comparator: Group 3
Procedure: Control group
The patients in group 3 will form the control group. After performance of the subsartorial saphenous nerve block, patients in group 3 will receive sham injections of saline for the obturator nerve block and the hamstrings block (perimuscular injections).
Other Name: saline group
Performance of arthroscopic knee repairs on day care basis necessitates adequate post-operative analgesia for successful home discharge since post-operative pain is known to be the commonest cause of unanticipated readmissions of day care patients. Early return to activity is also crucial to ensure adequate surgical outcomes. Anterior cruciate ligament (ACL) repair is commonly performed by arthroscopic approach with an ipsilateral hamstring-gracilis graft. This has shown to be superior to patellar tendon grafts with regards to pain and functional outcomes after surgery. Postoperative pain from the graft donor site and anterior knee pain form the surgery can lead to decreased range of motion and poor rehabilitation. A variety of regional anesthetic techniques are being tried for out-patient knee surgery like spinal adjuvants; intra and peri-articular injection, single injection and continuous blocks of the femoral and sciatic nerves, oral pills and cryoanalgesia. Opioid based analgesia with or without co-analgesics is not suited for dynamic pain relief since Aα and Aδ nerve fibres that carry pain are poorly inhibited by opioids while effectively inhibited by local anesthetics. Multimodal analgesic regimens work well for ambulatory surgeries especially when combined with regional analgesic techniques. Regional techniques decrease opioid consumption and hence opioid related side effects. Intra and peri-articular injections have a short duration of action compared to nerve blocks apart from the concerns of chondrotoxicity of intra-articular local anesthetics. Although femoral- and sciatic nerve blocks provide adequate analgesia, the weakness of the quadriceps and hamstrings can prevent early rehabilitative efforts and also pose a risk for patient falls following home discharge. Hence, novel regional techniques of analgesia like blocking the infrapatellar branch of saphenous nerve, graft site injections of local anesthetics through the arthroscopic sleeve and single injection adductor canal block have been tried. Isolated sensory block of the surgical and graft site without motor block is the Holy Grail in search for these ambulatory patients.
Saphenous nerve, the terminal branch of femoral nerve supplies the majority of the knee joint. The femoral nerve exits the adductor canal and gives the terminal branch of saphenous nerve which lies between the Sartorius muscle and femoral artery in the sub-sartorial canal. Subsartorial canal block has been successfully utilized for forefoot surgery and knee arthroplasty but this has not been evaluated for ACL repairs. Saphenous nerve can be successfully blocked in the subsartorial canal without the risks of leg weakness but this alone is insufficient to provide analgesia to the graft donor site which is usually the gracilis tendon and the hamstrings tendon. Depositions of local anesthetics around the harvested muscle or blockade of the nerve supplying it are attractive strategies to decrease donor site pain but have not been explored for this purpose in a randomized fashion. The investigators hypothesize that the combination of any of the above two techniques to decrease donor site pain along with subsartorial saphenous nerve block can provide adequate analgesia in these patients. The anterior branch of the obturator nerve needs to be blocked since it supplies the gracilis muscle. To decrease the donor site pain, the saphenous nerve block can be combined with block of the anterior branch of obturator nerve. Alternatively, the saphenous nerve block can be combined with deposition of local anesthetic around the graft donor muscles. The extent to which the two techniques benefit the patients in terms of overall analgesia and the graft site analgesia has not been evaluated. With this background, the investigators want to compare the analgesic efficacy of subsartorial saphenous nerve block with either perihamstrings infiltration or blockade of the anterior division of obturator nerve in patients undergoing ACL reconstruction with ipsilateral autograft from gracilis and hamstring muscles.
Please refer to this study by its ClinicalTrials.gov identifier: NCT01868282
|University Hospital, London Health Sciences Center,|
|London, Ontario, Canada, N6A 5A5|
|Principal Investigator:||Sugantha Ganapathy, FRCPC||London Health sciences Center, Western University, London, Ontario, Canada; N6A5A5|