Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT03497923 |
| Other study ID # |
CCER 2016-00018 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
Phase 4
|
| First received |
|
| Last updated |
|
| Start date |
February 11, 2019 |
| Est. completion date |
April 13, 2023 |
Study information
| Verified date |
April 2023 |
| Source |
University Hospital, Geneva |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Magnesium sulphate is regularly used in perioperative medicine. During and after general
anesthesia, it enhances the effect of muscle relaxants because it reduces the liberation of
acetylcholine at the neuromuscular junction. When administered immediately after spontaneous
recovery of a neuromuscular block (NMB), magnesium may cause a recurrence of NMB and
compromise patient safety.
Rocuronium is a neuromuscular blocking agent which is frequently used to facilitate
intubating and surgical conditions. At the end of the procedure, there are two ways to
accelerate the reversal of a neuromuscular block induced by rocuronium: 1. Administration of
neostigmine, an anticholinesterase agent and competitive antagonist; 2. Administration of
sugammadex, a γ-cyclodextrin compound and specific encapsulator of rocuronium.
The study is done in patients receiving rocuronium and either neostigmine or sugammadex for
reversal of NMB. It is hypothesized that when sugammadex is used as an antagonist of a
rocuronium-induced NMB, it prevents the reappearance of NMB when magnesium is injected,
because sugammadex should inactivate all remaining rocuronium molecules and restore
neuromuscular reserve of the neuromuscular junctions. Further more it is hypothesized that
reversal with neostigmine will not prevent a magnesium-induced recurrence of NMB to the same
extent. The primary objective of the study is to show that after reversal with sugammadex
there is no or only very little re-occurrence of neuromuscular block after a magnesium
perfusion. Furthermore we want to show that after reversal with neostigmine there is a
re-occurrence of neuromuscular block.
Description:
Magnesium sulphate (MgSO4) is regularly used in perioperative medicine. For instance,
pre-eclampsia and eclampsia have been successfully treated with intravenous magnesium. Also,
MgSO4 has been used for the control of life threatening cardiac arrhythmias, bronchial asthma
or as an anticonvulsant. Finally, magnesium has been found to alleviate postoperative pain
and to exert morphine sparing effect.
Magnesium plays a role in nearly every physiological system. In the nervous system, magnesium
has a depressant effect related to the inhibition of transmitter release from presynaptic
sites by competing with calcium and due to the antagonism at NMDA receptors. The presynaptic
inhibition of acetylcholine release at the neuromuscular junction by magnesium has been well
described. In addition, an excess of magnesium ions diminishes the depolarizing action of
acetylcholine at the end-plate, and depresses the excitability of the muscle fiber membrane.
Magnesium per se causes significant neuromuscular blockade (NMB) in high concentrations (≥ 5
mmol L-1). In the presence of curare-like agents, however, very low concentrations of
magnesium (≥1 mmol L-1) inhibit neuromuscular transmission since in this case much more
acetylcholine is needed to produce a magnitude of depolarization of the end-plate compared
with normal conditions. Consequently, magnesium enhances the effect of muscle relaxants
during and after general anesthesia. The prolongation of the duration of NMB by magnesium may
increase the incidence of a residual postoperative neuromuscular block, and consequently may
compromise patient safety. In addition, magnesium, when administered immediately after
spontaneous recovery of a NMB, may cause recurrence of the NMB ("recurarisation"). Under
clinical conditions this may happen whenever magnesium is used in the immediate postoperative
period, for instance, for postoperative pain alleviation or for treatment of postoperative
cardiac arrhythmia.
It is not known, however, whether pharmacological reversal of a NMB prior to magnesium
treatment prevents the recurrence of NMB. Recovery after neostigmine (an anticholinestherase
agent) administration was approximately 30% less in patients pretreated with MgSO4 compared
with those without MgSO4 pretreatment. Sugammadex, a γ-cyclodextrin compound, is a new
reversal agent. It is a specific encapsulator of steroidal muscle relaxants such as
rocuronium. We have demonstrated that magnesium pretreatment did not prolong the reversal of
deep or moderate rocuronium-induced neuromuscular blockade when standard doses of sugammadex
were used for reversal.
Sugammadex causes a rapid and complete reversal of the neuromuscular blockade by reducing the
action of rocuronium on the prejunctional and postjunctional nicotinic acetylcholine
receptors (nAChRs). Unlike neostigmine, sugammadex is efficacious in reversing moderate (2
twitches to train-of-four [TOF] stimulation, TOF-count two [TOFC-2]) and deep (post-tetanic
count [PTC] of 1 or 2) rocuronium-induced NMB in doses of 2.0 mg kg-1 and 4.0 mg kg-1,
respectively.
The suggested cause of return of NMB ("recurarisation") subsequent to magnesium
administration is the absence of a functional reserve of the neuromuscular junction (safety
margin, 70% of receptor capacity) despite a complete recovery of the TOF ratio and twitch
amplitude (T1) (main variables of neuromuscular monitoring). It is important to know that the
actually available neuromuscular monitoring methods are insensitive to measure the safety
margin of the neuromuscular transmission, thus they cannot provide information about the
likelihood of block recurrence. Theoretically, recurrence of a NMB due to clinical doses of
magnesium happens only in cases where the safety margin is reduced or abolished by a NMB
agent. Therefore, to prevent recurrent muscle weakness ideally all relaxant molecules should
be eliminated from the neuromuscular synapse before magnesium is administered.
Pharmacological reversal of NMB reduces neuromuscular receptor occupancy and thereby
increases the safety margin. Neostigmine augments the amount of acetylcholine at the
neuromuscular junction, which competitively antagonizes the NMB and liberates at least
partially the synaptic receptor reserves. However, neostigmine is not reliable to completely
re-establish neuromuscular function. When sugammadex is administered, the free rocuronium
plasma concentration rapidly declines near to zero (like a washout) and consequently the
safety margin isincreased. In this context, one can speculate that sugammadex is an ideal
antagonist when magnesium treatment is associated with the use of rocuronium.
However, it is still unknown whether the administration of magnesium sulphate immediately
after pharmacological reversal of the TOF ratio to a normalized 0.9 value (i.e. adequate
reversal) re-induces a clinically relevant NMB. If magnesium is used in the immediate
postoperative period, we need to know whether, and how, postoperative muscle paralysis as a
consequence of the magnesium treatment can be prevented.
The hypothesis of this study is that when sugammadex is used as an antagonist of a
rocuronium- induced NMB, the neuromuscular junction will be liberated from almost all
rocuronium molecules and no recurrent NMB will occur. Furthermore it is hypothesized that
reversal with neostigmine will not prevent to the same extent magnesium-induced recurrence of
NMB. In addition, the magnitude and time course of the magnesium induced neuromuscular block
will be measured.
