Table 1.
Overview of pain and nociception monitors.
| Device | Score/unit | Measurement principle | Monitoring nociception | Monitoring pain | Comments | |
|---|---|---|---|---|---|---|
| Single-parameter scores | Analgesia nociception index | 0–100; dimensionless | Cardiac parasympathetic tone | Possibly negative predictive value (ANI <43 at end of surgery) for absence of significant postoperative pain33; value for pre-emption of haemodynamic events controversially discussed29, 30; may ‘react’ to noxious stimuli somewhat stronger than standard haemodynamics, but controversial17, 27, 28 | Possibly some negative predictive value for exclusion of significant pain, but controversially discussed19, 20, 21, 22, 26 | Well published; may be best for exclusion of significant nociception/pain |
| Skin conductance | Number of fluctuations in skin conductance per second (NFSC) (n) | Peripheral (skin) sympathetic tone | NFSC >0.2 may correlate with severe nociception and, at the end of surgery, significant postoperative pain7, 37 | Influence by many confounders (i.e. arousal) may limit its use in awake patients37, 38, 39, 40 | Easy to use, but NFSC tends to react predominantly with higher levels of stress/nociception (‘smoke detector’) | |
| Pupillometry | Absolute or changes in pupillar width (mm %−1) | Sympathetic tone (pupillar innervation) | Pupillometry-guided analgesia may reduce opioid consumption and persistent pain (but only n=55 included subjects)44; may predict responsiveness to postoperative opioids43; influenced by depth of anaesthesia52 | May predict response to noxious stimulus in the ICU50 | Promising results, but somewhat awkward method (requiring repeated access to open eye) | |
| Nociceptive flexion reflex threshold | mA | RIII reflex modification by level of analgesia | May aid the prediction of a response to a noxious stimulus54; limited predictive value for postoperative pain when measured at the end of surgery9 | Little published research in the postoperative setting | NFTS is a reasonably well-known instrument in pain research, but its perioperative use in clinical routine is not yet well researched | |
| Two-parameter scores | Surgical pleth index (SPI) | 0–100; dimensionless | Peripheral vascular and cardiac sympathetic tone | Meta-analysis (six publications and 463 patients) states that SPI-guided analgesia resulted in lower opioid consumption and shorter times to tracheal extubation61; conflicting evidence regarding the prediction of acute postoperative pain57, 63; ‘ideal’ score during surgery may be affected by age and might be closer to 30 (vs frequently quoted <50)57, 62 | Manufacturer does not recommend use in conscious patients; little or no use in awake subjects7 | Well researched, but guidelines for ideal range of SPI overall not well validated; only monitor which does not require consumables (but GE monitor) |
| qNOX | 0–99; dimensionless | Electromyographic/electroencephalographic patterns associated with nociception | May help to predict probability of sudden movement in response to stimulation8 | No published data to evaluate the score in this setting | To date, insufficient evidence to allow firm conclusions about perioperative use and its benefits | |
| Multi-parameter scores | Nociception level (NOL) index | 0–100; dimensionless | Four parameters: skin galvanic response (sympathetic tone), plethysmographic pulse wave (sympathetic vascular tone), temperature, and accelerometry (association with nociception unclear) | May discriminate noxious stimuli slightly better than standard haemodynamics65, 67; ‘ideal’ intraoperative NOL may be 10–2510 | No published data | Multiple parameters may increase accuracy, but, to date, little evidence for clinical relevance |