Changes in CRPS include a decrease in the gray matter volume in the right anterior insula, orbitofrontal cortex (OFC), right ventromedial prefrontal cortex (PFC), cingulate cortex, putamen, sensorimotor cortices, and parietal areas (40–43), and an increase in the gray matter volume in the two dorsal putamen, right hypothalamus, dorsomedial PFC, contralateral primary motor cortex, and choroid plexus (42, 44).

Except in one study (45), most magnetoencephalography (MEG), electroencephalography (EEG), or functional MRI (fMRI) data in CRPS confirmed a significant shrinking of S1 hand representation in the hemisphere contralateral to the painful side, as compared to the unaffected hand or pain-free subjects (18, 46–50). One study denoted that the center of gravity of the S1 hand area was shifted to the lip area (18). EEG-recorded amplitudes of somatosensory evoked potentials (SSEPs) following median/ulnar nerve stimulation on the CRPS side showed that the S1 hand area was more responsive to peripheral signal than on the unaffected side or in pain-free people (49), i.e., hyperexcitability but without any change of peak timing (18, 46, 48, 49). Some fMRI studies reported a smaller activation and weaker blood-oxygen level-dependent signal (BOLD) in the CRPS-related S1 area as compared with the other side (46, 79) or to pain-free subjects (80), but one study did not find any between-hemisphere difference (58). Somatosensory excitability was assessed by SSEP using the paired-pulse evoked suppression paradigm. This technique requires the application of two asynchronous stimulations of the median nerve at the level of the wrist, with the expectation that the amplitude of the second SSEP in S1 is significantly smaller than the first. Results showed a marked bilateral reduction of cortical disinhibition in specific tasks, as compared with that of pain-free subjects, thus supporting the dysfunction of somatosensory circuits (61, 62).

The activation of the primary motor cortex (M1) and supplementary motor area (SMA) recorded by fMRI during finger tapping with the CRPS-affected limb was shown to be increased bilaterally but more markedly on the ipsilateral side (60). The technique of arterial spin labeling was used to test the motor-resting neural activity and it was found that blood perfusion in M1 and the SMA was increased in people with chronic CRPS (41). Also, the technique of positron emission tomography with F-fluorodeoxyglucose (FDG-PET) tested that the metabolism of M1 and dorsal PFC contralateral to the CRPS-affected side was decreased as compared to that in pain-free people (55). Two MEG studies investigated the 20 Hz rebound of M1 in response to somatosensory stimulation, which reflects the increase of M1 excitability after a period of suppressed activity due to the somatosensory stimulation. In people with CRPS, 20-Hz oscillations did not adapt properly in response to tactile (49) and noxious (63) stimuli, thus suggesting the alteration of M1 inhibition processes.

fMRI recordings during painful stimulation in people with CRPS denoted an increase (either contralateral to the site of stimulation or bilateral) of the responses in the posterior cingulate cortex, in parallel with a decrease of the posterior opercular cortex (58). Several studies found a bilateral increase of the responses in somatosensory cortices, cingulate cortex, parietal cortex, cerebellum, as well as in the right insula and the right thalamus (55). Perfusion was also decreased in the part of the thalamus contralateral to the affected limb (56, 57).

Diffusion-tensor imaging (a technique using MRI-recorded direction of water within the myelinated fibers to reconstruct brain tractography) helped detect the increase of connectivity between the ventromedial PFC and insula, and between the putamen and pre-/post-central gyri (43) and the decrease of connectivity between the ventromedial PFC and basal ganglia (40) and between putamen and cerebellum (43). Precisely, the involvement of the basal ganglia in the physiopathology of CRPS was recently hypothesized (81). In support, it was shown that basal ganglia activation to nociceptive stimuli was increased in children (82, 83) and adults with CRPS (58) and that the functional linking between the intraparietal sulcus and caudate nuclei was bilaterally altered in people with CRPS (52). Resting-state fMRI studies also brought about evidence of the alteration of the default mode network in CRPS (52–54).

Mapping of M1 representation by single-pulse TMS in people with type-1 CRPS showed that the affected hand had a smaller M1 representation than the unaffected with a center of gravity more variable but not significantly different between sides or compared with that in pain-free people (51).

TMS paradigms enable investigation of the different mechanisms of M1 inhibition, and CRPS studies showed that some inhibitory processes could be altered and others not. Paired-pulse TMS of M1 at inter-stimulus intervals below 4 ms showed that the short-interval intracortical motor inhibition (SICI, depending on GABA_A receptors activity) (85) was reduced either in both the hemispheres as compared to that in pain-free individuals (64, 68) or only in M1 contralateral to CRSP side (23, 50, 86). Of note, the cortical silent period following a motor-evoked potential (MEP) (superimposed on background isometric contraction) is a different mechanism of M1 inhibition that depends on the GABA_B-receptors, and which was shown to be comparable between sides in CRPS and to pain-free subjects (65, 67). Also, the long-afferent inhibition (LAI), which investigates sensorimotor integration, i.e., the inhibition of TMS-MEP by sensory afferents volley triggered by electrical stimulation of a peripheral nerve (85), was shown to be reduced in M1 contralateral to the affected hand (65). However, at shorter inter-stimulus intervals aiming at testing the short-afferent inhibition (SAI), the MEP reduction by median nerve stimulation was unchanged as compared to that in pain-free subjects (65, 66). In addition, the paired associative stimulation (PAS), e.g., 180 pairs of nerve electric stimulation and TMS of M1, induced the same sensorimotor plasticity (MEP increase) in CRPS as in pain-free subjects (65). Thus, circuits connecting S1 and M1 seem to work properly in CRPS and may not explain the differences in M1 inhibitory function and plasticity.

TMS studies showed controversial findings in CRPS for M1 facilitation. Indeed, paired-pulse TMS of M1 at inter-stimulus intervals over 10 ms showed that the intracortical motor facilitation (ICF, depending on NMDA glutamatergic receptors) could be comparable between sides and to that in pain-free subjects (64) and significantly increased in the hemisphere contralateral to the CRPS side (65).

Among other TMS outcomes in CRPS that were unchanged between hemispheres or as compared to pain-free people are the resting motor threshold (RMT) and the amplitude of the MEP tested at 120% RMT (64, 65, 68, 69). RMT is the minimal TMS intensity required to evoke five MEP ≥50 μV out of 10 successive trials in the target muscle at rest and it informs on the basic transsynaptic M1 excitability. The MEP amplitude informs on the corticospinal excitability and it depends on the volume of M1 tissue responding to TMS and on the synchronicity of descending volleys to excite the alpha-motoneurons in the spinal cord. Of note, the same authors showed that MEP amplitudes were either unchanged in CRPS (68) and bilaterally decreased (67) as compared to those in pain-free subjects (refer to Table 2).

Repetitive magnetic stimulation consists of the administration of painless magnetic pulse trains above the brain, e.g., M1 or dorsal PFC (rTMS, T for transcranial), or at the periphery, e.g., over nerve or muscle (rPMS, P for peripheral). The manipulation of the stimulation parameters, such as the frequency (from 0.1 up to 50 Hz), train duration, inter-train interval, coil positioning over a cortical or peripheral target, enables modifying of the actual net after-effects in the neural tissues beneath the coil, i.e., depolarization or hyperpolarization/depression [for details, refer to Pell et al. (73), Beaulieu and Schneider (108)]. In clinical pain studies, rTMS is usually applied over M1 at subthreshold intensity (below the intensity eliciting a muscle response via the corticospinal pathway). The after-effects (LTP-like excitation or LTD-like inhibition) can last from minutes to several hours, depending on the protocol and the task tested and can induce changes of excitability and function in remote areas. Long-lasting rTMS-induced analgesic effects likely rely on LTP/LTD-like mechanisms (refer to the previous section on central sensitization) via an influence on glutamatergic networks (109).

rPMS is commonly applied over a spinal root, nerve, or muscle belly at a suprathreshold intensity to trigger muscle contraction (72). It is hypothesized that it may recruit proprioceptive afferents directly by the depolarization of sensory fibers terminals and indirectly via the induction of repeated contractions and joint movements (108). Also, due to minimal recruitment of nociceptive receptors (the magnetic pulse bypasses skin without resistance), it is painless and the proprioceptive message mediated to the brain is not contaminated by cutaneous information. Thus, rPMS mimics the contraction/relaxation process of one muscle or a group of muscles, and the pure proprioceptive information generated is coherent with the appropriate motor control to influence sensorimotor plasticity at the origin of motor improvement or pain reduction (108). In support, it is shown in motor disorders or in chronic pain that rPMS influences the cortical markers with clinical significance (110).

tDCS is administrated by means of two electrodes (the anode and the cathode) fixed on the scalp. Many studies have shown a greater reduction of pain when the anode is positioned above M1, as compared to S1 or the dorsolateral PFC (111, 112). The cathode is always on the forehead, supraorbital area, contralateral to M1 stimulated. M1 stimulation by tDCS may activate corticospinal and corticothalamic projections which in turn influence the activity of regions of the diencephalon, brain stem, and spinal cord involved in pain modulation mechanisms (113, 114). Specifically, studies show that the effectiveness of tDCS in relieving chronic pain and maintaining effects depends on key stimulation parameters, such as electrode position (anodal M1 montage), stimulation intensity (2 mA), duration (20 min), and the number of weekly sessions (111, 112).

TENS can be applied at a high frequency (HF > 50 Hz) with subthreshold intensity (no muscle contraction) or at a low frequency (LF < 10 Hz) with suprathreshold intensity (producing muscle contraction) (115). In humans, both protocols can reduce chronic pain by the generation of somatosensory inputs but their respective mechanisms of action seem different owing to different after-effects due to different frequencies used (116). Also, low-intensity conventional TENS can have maximal analgesic effects homotopically, i.e., on the stimulated side, whereas high-intensity TENS can induce spatially diffused analgesic effects. It has also been shown that only high-intensity TENS produced long-lasting changes in S1 and M1 areas and in their connectivity to vmPFC, which is part of the pain inhibition descending system (116). This activation of the pain inhibition systems promotes the release of endogenous opioids, thus explaining the diffuse analgesic effects (117–119).

Three studies tested the after-effects of rTMS in people with CRPS: two studies focused on type I (128) and the third on mixed types I and II CRPS (122). All the three administrated rTMS over M1 were contralateral to the CRPS hand. The first two studies used 10 Hz rTMS in a single session with 10 patients or 10 sessions with 12 patients, one time a day for 10 days in a row (46, 128). Precisely, Pleger et al. (128) reported that pain intensity could be reduced after one rTMS session (as measured on the visual analog scale or VAS), as compared to sham stimulation, with the VAS scores being the lowest at 15 min after the end stimulation, but back to baseline at 45 min. One study (127) applied rTMS as an add-on intervention of a standard pharmacological and rehabilitation treatment for 10 consecutive sessions (10 days in a row). Of note, the pharmacological and rehabilitation treatment was first administrated over a month before adding on rTMS. The authors reported a reduction of pain (scores of VAS and McGill Pain Questionnaire or MPQ) and improvements of affective and emotional scores (SF-36 and Hamilton Depression Scale) during the period of rTMS treatment, but the effects had vanished at follow-ups of 1 week and 3 months. The third study (122) was conducted in a mixed cohort (CRPS types I and II). The authors used an open-label and non-randomized design to investigate the after-effects of the priming of 10 Hz rTMS by intermittent theta burst stimulation (iTBS). The protocol of iTBS (5 Hz bursts of three pulses delivered at 50 Hz) was delivered at an intensity of 70% of the RMT and was followed immediately by the 10 Hz rTMS (10 s trains with 30 s inter-train interval) delivered at 80% RMT with the coil guided by real-time neuronavigation. A decrease in the pain, VAS scores were reported immediately after the end of the stimulation and 2 weeks after. Of note, the magnitude of pain reduction was similar between patients having undergone a single session (n = 6) and those having been enrolled in five sessions one time a day (n = 15).

One study used rPMS in CRPS (67). Ten series of 10 s of 20 Hz rPMS at 120% of spinal RMT were applied over the cervical nerve roots innervating muscles of the painful area. The authors reported that the amplitudes of MEP to TMS of M1 were smaller on both sides in CRPS than in pain-free participants. The after-effects of rPMS in this study were limited to the lengthening, in pain-free participants only, of the duration of the contralateral and ipsilateral cortical silent periods, which informs on the level of M1 and interhemispheric inhibition, respectively. Unfortunately, this study did not collect any clinical outcomes.

Three studies investigated the after-effects of anodal tDCS applied over M1 contralateral to the CRPS hand, two case studies (131), and one randomized parallel single-blind study (125). Of note, these studies used tDCS as an add-on of sensorimotor training (131), TENS over the painful area (123), and graded motor imagery (125). Schmid et al. reported that anodal tDCS + sensorimotor training reduced pain intensity and improved the pattern identification during ST, as compared to sham tDCS + sensorimotor training (131). The second study (123) reported that anodal tDCS + TENS one time a day a day for 5 consecutive days slightly reduced pain intensity and unpleasantness, as compared to tDCS alone. Lagueux et al. tested tDCS + graded motor imagery in 11 people with CRPS type I (125). Precisely, the participants underwent 6 weeks of graded motor imagery, and anodal tDCS of M1 was added one time a day for 5 days in a row in the first 2 weeks of graded motor imagery, then, one time a week for the remaining 4 weeks of graded motor imagery. The authors reported that this did not reduce pain more than in the control group of 11 other patients having undergone sham tDCS + graded motor imagery with the same parameters (125). Of note, it has never been reported either that protocols of tDCS alone could improve pain management in CRPS (112).

TENS after-effects in CRPS pain management have been described in numerous interesting case reports and case series since the late 1970s, both in children and adults. However, robust data-evidence-based studies are missing and the efficacy of TENS has not yet been established. Current evidence is limited by the case report designs, the large variety of protocols employed or the missing details in the protocol, the heterogeneous cohorts of patients, and the lack of appropriate control conditions in most cases. However, given the high acceptance and safety of this device, it is almost always worthwhile to consider TENS as part of a multidisciplinary approach (133). For example, three case studies in children aged 10, 6, and 3.5 years old, respectively (126), and one case report in a 43-year-old woman (121) reported that TENS applied over acupuncture points or painful areas, at low or high frequencies and for one or several sessions, decreased pain, hyperesthesia, hyperalgesia, edema, cyanosis if any, and, in parallel, improved the range of motion (ROM) at the painful joint. Two other series of cases used various stimulation protocols between children and with limited details provided in the articles: TENS coupled with home-based physical therapy reduced pain symptoms in 9/10 cases with complete remission within 2 months in 7/10 cases (124) and TENS alone reduced pain in 20/29 cases (130). More recently, a randomized clinical trial tested 100 Hz TENS as an add-on to a standard physical therapy program (contrast bath, whirlpool bath, and physical exercise) in 15 people with type-1 CRPS. The authors showed that 15 sessions of TENS + standard physical therapy program reduced pain scores and edema and increased the second-to-third fingers ROM more than in a group of 15 other patients who underwent sham TENS + standard physical therapy program. It was concluded that the addition of TENS to standard physical therapy programs significantly contributed to clinical recovery in CRPS (120).