Hierarchical Rule-based Monitoring and Fuzzy Logic Control for Neuromuscular Block

Objective. The important task for anaesthetists is to provide an adequate degree of neuromuscular block during surgical operations, so that it should not be difficult to antagonize at the end of surgery. Therefore, this study examined the application of a simple technique (i.e., fuzzy logic) to an almost ideal muscle relaxant (i.e., rocuronium) at general anaesthesia in order to control the system more easily, efficiently, intelligently and safely during an operation. Methods. The characteristics of neuromuscular blockade induced by rocuronium were studied in 10 ASA I or II adult patients anaesthetized with inhalational (i.e., isoflurane) anaesthesia. A Datex Relaxograph was used to monitor neuromuscular block. And, ulnar nerve was stimulated supramaximally with repeated train-of-four via surface electrodes at the wrist. Initially a notebook personal computer was linked to a Datex Relaxograph to monitor electromyogram (EMG) signals which had been pruned by a three-level hierarchical structure of filters in order to design a controller for administering muscle relaxants. Furthermore, a four-level hierarchical fuzzy logic controller using the fuzzy logic and rule of thumb concept has been incorporated into the system. TheStudent’s t test was used to compare the variance between the groups. p < 0.05 was considered significant. Results. The system achieved stable control of muscle relaxation with a mean T1% error of −0.19 (SD 0.66) % accommodating a range in mean infusion rate (MIR) of 0.21–0.49 mg· kg−1 · h−1. When these results were compared with our previous ones using the same hierarchical structure applied to mivacurium, less variation in the T1% error (p < 0.05) but the same variation in infusion rate were observed. The controller activity of these two drugs showed no significant difference (p> 0.5). However, the consistent medium coefficient variance (CV) of the MIR of both rocuronium (i.e., 36.13 (SD 9.35) %) and mivacurium (i.e., 34.03 (SD 10.76)%) indicated a good controller activity. Conclusions. The results showed that a hierarchical rule-based monitoring and fuzzy logic control architecture can provide stable control of neuromuscular block despite the considerable individual variation in neuromuscular block required among patients. Also, there was less variation in T1% error compared with that of previous study on mivacurium. Meanwhile, the consistent medium CV of the MIR of both rocuronium and mivacurium indicated a good controller activity which is able to withstand noise, diathermy effect, artifacts and surgical disturbances.

[1]  J. D. de Vries,et al.  Infusion of vecuronium controlled by a closed-loop system. , 1986, British journal of anaesthesia.

[2]  H. Schwilden,et al.  Use of a pharmacokinetic-dynamic model for the automatic feedback control of atracurium , 2004, European Journal of Clinical Pharmacology.

[3]  D. Linkens,et al.  Self-learning fuzzy logic control of neuromuscular block. , 1997, British journal of anaesthesia.

[4]  D. A. Linkens,et al.  Self-learning fuzzy control of atracurium-induced neuromuscular block during surgery , 1997, Medical and Biological Engineering and Computing.

[5]  P C Uys,et al.  Self-tuning, microprocessor-based closed-loop control of atracurium-induced neuromuscular blockade. , 1988, British journal of anaesthesia.

[6]  L. B. Rametti,et al.  On-line control of atracurium induced muscle relaxation. , 1986, Journal of biomedical engineering.

[7]  Mouloud Denai,et al.  Self-Tuning PID Control of Atracurium Induced Muscle Relaxation in Surgical Patients , 1990 .

[8]  H. H. Ali,et al.  The cardiovascular effects of mivacurium chloride (BW B1090U) in patients receiving nitrous oxide-opiate-barbiturate anesthesia. , 1989, Anesthesiology.

[9]  T. Taivainen,et al.  Frequency of train-of-four stimulation influences neuromuscular response. , 1994, British journal of anaesthesia.

[10]  Mahdi Mahfouf,et al.  Generalised predictive control (GPC) in the operating theatre , 1992 .

[11]  Y. Ohta,et al.  The neuromuscular effects of ORG9426 in patients receiving balanced anesthesia. , 1991, Anesthesiology.

[12]  B H Brown,et al.  Closed-loop control of muscle relaxation during surgery , 1980 .

[13]  F J Overdyk,et al.  Closed-loop infusion of atracurium with four different anesthetic techniques. , 1991, Anesthesiology.

[14]  A J Asbury,et al.  Fuzzy logic: new ways of thinking for anaesthesia. , 1995, British journal of anaesthesia.

[15]  J. Kelly,et al.  Atracurium infusions in major ophthalmic surgery. , 1987, European Journal of Anaesthesiology.

[16]  N R Webster,et al.  Closed‐loop administration of atracurium , 1987, Anaesthesia.

[17]  D A Linkens,et al.  Development of a portable closed-loop atracurium infusion system: systems methodology and safety issues , 1996, International journal of clinical monitoring and computing.

[18]  D. Linkens,et al.  Performance assessment of a fuzzy controller for atracurium-induced neuromuscular block. , 1996, British journal of anaesthesia.

[19]  D. R. Cook,et al.  A877 ORG 9426SINGLE-DOSE RESPONSE, ONSET, AND DURATION WITH HALOTHANE ANESTHESIA , 1990 .

[20]  M. Rk,et al.  Muscle relaxation with an infusion of vecuronium. , 1984 .

[21]  C E Blogg,et al.  Feedback control of neuromuscular blockade , 1987, Anaesthesia.

[22]  D A Linkens,et al.  Automatic control of neuromuscular block with atracurium. , 1989, British journal of anaesthesia.