Ignite Creation Date:
2025-12-25 @ 2:31 AM
Ignite Modification Date:
2025-12-29 @ 1:15 AM
Study NCT ID:
NCT07083934
Status:
NOT_YET_RECRUITING
Last Update Posted:
2025-07-24
First Post:
2025-06-13
Is Gene Therapy:
True
Has Adverse Events:
False
Brief Title:
Ultrasound-Guided Supraclavicular Block With vs Without PNS
Sponsor:
Aga Khan University
Organization:
Study Overview
Official Title:
Comparison of Ultrasound Guided Supraclavicular Brachial Plexus Block With and Without Peripheral Nerve Stimulation (PNS) Guidance: A Randomized Controlled Tria
Status:
NOT_YET_RECRUITING
Status Verified Date:
2025-07
Last Known Status:
None
Delayed Posting:
No
If Stopped, Why?:
Not Stopped
Has Expanded Access:
False
If Expanded Access, NCT#:
N/A
Has Expanded Access, NCT# Status:
N/A
Acronym:
None
Brief Summary:
Peripheral Nerve Blockade (PNB) became reliable with the advent of Ultrasound (US) and Peripheral Nerve Stimulation (PNS).
US offers real-time visualization but has limitations, especially with deep or obscured nerves.
PNS complements US by confirming nerve proximity through motor responses. Combining both may enhance safety and success of nerve blocks. This study compares US-guided blocks with and without PNS in a randomized trial.
US offers real-time visualization but has limitations, especially with deep or obscured nerves.
PNS complements US by confirming nerve proximity through motor responses. Combining both may enhance safety and success of nerve blocks. This study compares US-guided blocks with and without PNS in a randomized trial.
Detailed Description:
Peripheral Nerves Blockade (PNB) via local anaesthetics is a method of providing anesthesia and analgesia to the limbs and it was well established in the late 20th century. However, it did not come very well into practice because of unreliability, high rate of complications and failure due to lacking of accurate and reliable techniques of nerve localization at that point in time. It was only when newer nerve localization methods, such as Peripheral Nerve Stimulation (PNS) and Ultrasound (U/S) Imaging started becoming commercially available that the trend of Regional Anaesthesia started getting recognized among the physicians. PNB as a sole anaesthesia technique for limb surgery took further integration in practice and widespread acceptance among anaesthetist in the last decade, once ultrasound technology advanced to newer heights resulting in compact and more mobile units, higher resolution, needle recognition software etc.
When compared to PNS guided regional anaesthesia (PGRA), ultrasound guided regional anaesthesia (UGRA) offers a number of important practical advantages such as direct real-time visualization of the anatomy of interest, needle pathway and its passing through structures and spread of local anaesthetic, and the potential for instantaneous needle re-adjustments as per need. All this allows for safer and more effective distribution of local anaesthetic in the region of desired peripheral nerve. This superiority of Ultrasound Guidance led to fade in the use of PNS guidance in the Regional Anaesthesia practice over the recent years.
Regardless of the previously discussed superiority of U/S Guidance in Regional anaesthesia (RA), it has its own limitations. Such limitations include difficulty in visualization and identifying neural structures when they are lying far away from the skin either due to thick overlying subcutaneous adipose tissue in the obese patients or simply because of the presence of nerve bundle in the deeper tissue planes, and inability to confidently identify and exclude the placement of needle tip within the nerve, where if an injectate is injected will lead to nerve damage.
Such limitations of U/S Guidance in RA can be circumvented by using PNS Guidance in its conjunction. PNS works by delivering a small pulse of electric current through the needle tip which when in close proximity to a neural structure will lead to its stimulation and its respective muscle contraction, thereby helping us in identifying the neural structure of interest. Current density (with pulse duration at 1ms and frequency 2Hz) of around 1 mA for superficial nerves and 1.5-2mA for deeper nerves is enough to elicit a desired motor response. Eliciting a motor response at an even higher current density can be discomforting to the patient as well as misleading to the operator as neural structures can get stimulated through tissues and fascial planes. Similarly, Current density can also be used to predict the intra-fascicular or intraneural needle placement. One study showed that minimum stimulation (Median \[interquartile range\]) threshold outside was 0.60 mA \[0.40-1.0\] and inside 0.30 mA \[0.20-0.40\], where, the difference of 0.30 mA was statistically significant. Therefore, a lower limit for the current density can be used as a safety margin beyond which no muscle activity should be elicited by using PNS.
So, considering the additional benefits of PNS Guidance that it can potentially concur in facilitating UGRA in achieving effective and safer PNB, we propose and design a randomized control trial by comparing the UGRA with and without PNS Guidance in achieving PNB and its outcomes.
When compared to PNS guided regional anaesthesia (PGRA), ultrasound guided regional anaesthesia (UGRA) offers a number of important practical advantages such as direct real-time visualization of the anatomy of interest, needle pathway and its passing through structures and spread of local anaesthetic, and the potential for instantaneous needle re-adjustments as per need. All this allows for safer and more effective distribution of local anaesthetic in the region of desired peripheral nerve. This superiority of Ultrasound Guidance led to fade in the use of PNS guidance in the Regional Anaesthesia practice over the recent years.
Regardless of the previously discussed superiority of U/S Guidance in Regional anaesthesia (RA), it has its own limitations. Such limitations include difficulty in visualization and identifying neural structures when they are lying far away from the skin either due to thick overlying subcutaneous adipose tissue in the obese patients or simply because of the presence of nerve bundle in the deeper tissue planes, and inability to confidently identify and exclude the placement of needle tip within the nerve, where if an injectate is injected will lead to nerve damage.
Such limitations of U/S Guidance in RA can be circumvented by using PNS Guidance in its conjunction. PNS works by delivering a small pulse of electric current through the needle tip which when in close proximity to a neural structure will lead to its stimulation and its respective muscle contraction, thereby helping us in identifying the neural structure of interest. Current density (with pulse duration at 1ms and frequency 2Hz) of around 1 mA for superficial nerves and 1.5-2mA for deeper nerves is enough to elicit a desired motor response. Eliciting a motor response at an even higher current density can be discomforting to the patient as well as misleading to the operator as neural structures can get stimulated through tissues and fascial planes. Similarly, Current density can also be used to predict the intra-fascicular or intraneural needle placement. One study showed that minimum stimulation (Median \[interquartile range\]) threshold outside was 0.60 mA \[0.40-1.0\] and inside 0.30 mA \[0.20-0.40\], where, the difference of 0.30 mA was statistically significant. Therefore, a lower limit for the current density can be used as a safety margin beyond which no muscle activity should be elicited by using PNS.
So, considering the additional benefits of PNS Guidance that it can potentially concur in facilitating UGRA in achieving effective and safer PNB, we propose and design a randomized control trial by comparing the UGRA with and without PNS Guidance in achieving PNB and its outcomes.
Study Oversight
Has Oversight DMC:
False
Is a FDA Regulated Drug?:
False
Is a FDA Regulated Device?:
False
Is an Unapproved Device?:
None
Is a PPSD?:
None
Is a US Export?:
None
Is an FDA AA801 Violation?: