Introduction
For years, regional anesthesia has been performed mainly with the help of nerve stimulation (NS) [
1]. Ultrasound (US) is now available in most centers practicing regional anesthesia and is a popular tool amongst trainees for performance of nerve blocks.
Many randomized controlled studies (RCS) have compared US-guided and NS-guided infraclavicular blocks in adults [
2-
4]. All studies reported a high success rate with either ultrasound- or with nerve stimulation-guidance, without being able to demonstrate a significant difference between the two modes of nerve identification.
We aimed to compare the overall success rate, procedure time and onset of sensory and motor block between the two techniques in infraclavicular brachial plexus (ICBP) block.
Materials and Methods
After local ethics committee approval and written informed consent, patients undergoing upper limb wrist/hand/elbow or distal arm surgery were recruited to this randomized, double-blind study. Inclusion criteria were age ≥ 18 and ≤ 80 years and American Society of Anesthesiologists Physical Status classification I-III. There were no exclusion criteria.
Patients were randomized by distributing sealed, opaque envelopes divided among two groups, each receiving an ICBP blok with bupivacaine 0.5%. No premedications were applied to the cases. An intravenous cannula was inserted into the contralateral arm, and continuous infusion (crystalloid solution) was started. For the whole procedure the patients were routinely monitored with electrocardiogram (ECG), non-invasive blood pressure (NIBP) measurement, and pulse oximetry (SpO2).
The patients were in supine position, with the head facing away from the side to be anesthetized, and the arm were adducted. The infraclavicular region was disinfected. All blocks were performed with 22 gauge needles and 15 ml bupivacaine 0.5%.
In the US Group-cases, a 10- to 12-MHz linear probe (Logiq 7 GE Health care, USA) covered with a sterile sheath with a liberal amount of sterile gel (Vygon, France) was placed in the deltopectoral groove. After subcutaneous infiltration, a 22 gauge insulated needle (Echoplex® D 50 mm, Vygon, France) was inserted and advanced using an in-plane needle-probe alignment. Injection of local anesthetic selectively surrounded each sonographically imaged brachial plexus cord with approximately 5 ml. The procedure time included the time required to perform an initial ultrasound exam and time puncture to block.
In the NS-Group cases, 15 ml of 0.5% bupivacaine was injected by using nerve-stimulator-specific, sterile, needles (22G insulated needle) in company with the available nerve stimulator (Stimuplex® Dig RC, B.Braun, Melsungen, Germany). Initial stimulating current was 1-1.5 mA. Brachial plexus was reached at a level of 6-8 cm. The current was then gradually decreased until the sought response was still present at 0.3 mA or less. Twiches of triceps, forearm and hand muscles were observed and accepted for successful block.
At the end of the ICBP block, an anesthetist blinded to the technique evaluated sensory and motor block every five minutes and for 30 minutes as follows. The innervated areas (each dermatome) was evaluated using a pinprick (
Table 1). When the needles were no longer felt, cutaneous anesthesia was considered to be present. The motor block was evaluated by bromage modified scale at 10 , 20 and at the end of the 30 minutes (
Table 2).
The succes of the block was defined by a complete sensory and motor block (bromage scale of 0) until 30 minutes after performing the block allowing for surgery, for all nerves.
All patients were awake during surgery, and a surgical tourniquet was used in all cases. Supplementary general anesthesia was at the discretion of the operating anesthesiologist and was based on sensory blockade of the intended operation area at 40 minutes. Anxious patients were administered additional midazolam. Subjects refusing awake surgery were administered a propofol infusion with supplemental oxygen as necessary.
Statistics
Prior to the study, a power analysis was performed to determine the necessary number of patients in each group. With a two-sided type I error of 5% and study power at 80%, it was estimated that 25 patients would be needed in each group in order to detect a difference of 10 mins at the onset of sensory and motor block between the two groups. Therefore 30 patients were included.
For statistical analysis, the program SPSS 13.0® for Windows (LEAD Technologies Inc, USA, 2004) was used. Categorical data was compared between the two groups using the Pearson Chi-2 test and described by count (percentages). The Kolmogorov-Smirnov test was used to evaluate the data distribution. We used the unpaired Student's t-test for normally distributed continuous variables and Mann-Whitney's U test for non-normally distributed continuous variables. Continuous variables were expressed as mean and standard deviation (SD) or median and interquartile range, depending on the normality distribution of the data. A P value of less than 0.05 was considered significant.
The primary end point in this study was onset time. The secondary end points were success rate and procedure time.
Results
We included 60 patients into the study (30 patients in each group). Patient's demographics were similar in the two groups. The duration of surgery was comparable between the groups (
Table 3).
There were no significant differences between groups in block procedure time (220 ± 130 sec in US group versus 281 ± 134 sec in NS group; P = 0.74).
The success rate of all the nerve blocks in the US group was 100%. The success rate in the NS group was 73.3%, 76.7%, 76.7% and 100% for radial, ulnar, median, and musculocutaneous nerve, respectively. The success rate was significantly higher in the US group for radial, ulnar, median, and the four nerves considered together (
Table 4,
Fig. 1 and
2).
We observed a significantly faster onset of sensory block for the radial, ulnar, median, musculocutaneous, and the four nerves considered together (
Table 4,
Fig. 3). The onset of motor block for the radial, ulnar, and medial nerves was faster in the US group. However, the onset of motor block for the musculocutaneous nerve and the four nerves considered together was comparable between the two groups (
Table 4,
Fig. 4).
Discussion
We found that the success rate of all the nerve blocks in the US group was 100%. The success rate in the NS group was 73.3%, 76.7%, 76.7% and 100% for radial, ulnar, medial, and musculocutaneous nerve, respectively. This success rate was significantly higher in the US group. We also found a significant faster onset of sensory and motor block in favor of US. However, US does not shorten procedure time.
Wu et al. [
5], in one of the first studies, reported eight successful blocks in nine patients. We can infer that their weaknesses in perfoming the study included not identifying the cords and for depositing the LA at the lateral border of the subclavian artery. In addition, the use of a thin (23-gauge) spinal needle can compromise the success and the safety of the procedure. So, the needle was directed to each of the cords individually. The entire length of the needle (bevel up) was seen at all times. In addition, the echogenicity of our needles (specially manufectured to this goal) provides better visibility and better control of its tip during manipulations This simple measure was probably a major factor in obtaining the higher success rate in our study (
Fig. 5 and
6).
Several studies have reported the importance of depositing LA around each nerve in the brachial plexus as a factor in improving the success rate [
6,
7].
Ootaki et al. [
8] reported no failed ultrasound-guided infraclavicular block in 60 patients performed by a unique person. Of them, 57 did not require any additional local anaesthetic or opioid supplementation. Two patients were given additional LA infiltration and one received analgesia with fentanyl. However the time to perform the block was not mentioned. While they claimed an overall success rate of 100%, the ulnar, radial and median nerves were spared in 10%, 6.7% and 3.3% of patients, respectively, 30 min after injection. In addition, the onset in their study [
8] was 30 min; it was 10 min (for sensory) and 20 min (for motor) in our series despite our using bupivacaine which is known to have a delayed action. This delay can be attributed to making no attempt to see the nerve cords. Consequently, the anaesthetic was deposited on all sides of the subclavian artery with the expectation that it would spread around the nerves. Sandhu and colleagues [
9], using the same technique that we used, found that sensory onset (6.7 ± 3.2 min) was shorter than ours probably because they used lidocaine as LA.
We believe that the rapid onset of the block depends on perineural rather than perivascular spread. Another reason for the slow onset in the study of Ootaki et al. [
8] may be related to the use of a slightly lower concentration of lidocaine (1.5%; 7.3 mg/kg) without adjuvants. The rapid onset in the study of Sandhu and Capan [
9] can be explained by the use of lidocaine 1.5% with sodium bicarbonate and by the larger volume (9.3 mg/kg) compared to what we used (approximately 1 mg/kg). However our study would be theoretically safer than that of Sandhu and Capan by decreasing the dosage of anesthetic resulting in lowering systemic and local neurologic toxicity.
In medical literature, five randomized controlled trials compared US-guided and NS-guided ICB in adult patients [
2-
4,
10,
11]. All of them showed a high success rate with either US- or with NS-guidance (
Table 5).
The vast majority of studies [
3,
4] suggest that the time required to perform peripheral nerve blocks is shortened with the use of ultrasound (which we did not find), however the time required to perform an initial ultrasound exam is not included in the total time reported in any of these investigations.
In summary, the significance of ultrasound guidance in the armamentarium of regional anesthesia is indisputable in terms of its success rate, speed of onset and duration of action.