The Emerging Role of Continuous Glucose Monitoring in the Management of Diabetic Peripheral Neuropathy: A Narrative Review

For this narrative review, we searched relevant published articles in PubMed up to January 2022 using combinations of the key words “continuous glucose monitoring” and “diabetic peripheral neuropathy”. The electronic search yielded 68 articles (including 12 reviews). Those articles addressing an association or lack of association of CGM with DPN were included in this review, and ten articles were excluded. Searches were not restricted by study design, but only articles published in the English language were included.

This article is based on previously conducted studies and does not contain any new studies with human participants or animals performed by any of the authors.

The relationship between GV and DPN was evaluated in a study conducted among 90 well-controlled subjects with T2DM (HbA_1c < 7.0%). Of these subjects, 45 had DPN and were recruited from an inpatient department of the Second Affiliated Hospital of Nantong University (China) and 45 had no DPN and were recruited from outpatient as controls [7]. The two groups were matched for age and T2DM duration. The diagnosis of DPN was based on the criteria recommended by The Toronto Diabetic Neuropathy Expert Group, including the presence of a symptom/symptoms (decreased sensation, positive neuropathic sensory symptoms predominantly in the toes, feet or legs) or a sign/signs of neuropathy (symmetric decrease of distal sensation or unequivocally decreased or absent ankle reflexes) and presence of abnormality of nerve conduction (NC) test results [7]. Glucose was monitored with a CGM system (MiniMed system; Medtronic, Northridge, CA, USA) for 72 h [7]. GV was estimated with multiple parameters, such as glucose SD (SDgluc), mean of daily differences (MODD) and MAGE. Blood pressure, body mass index (BMI) and laboratory parameters were measured, included insulin sensitivity index (ISI; Matsuda index), total cholesterol, triglycerides, high-density lipoprotein cholesterol and low-density lipoprotein cholesterol [7]. Subjects with DPN had higher SDgluc, MODD and MAGE (p < 0.05). Multivariate logistic regression analysis revealed a significant correlation of DPN with MAGE (odds ratio [OR] 2.05, 95% confidence interval [CI] 1.36–3.09, p = 0.001) and BMI (OR 0.85, CI 0.73–0.99, p = 0.033) [7].

Similarly, another study of 982 subjects with T2DM (197 with DPN) from the inpatient department of the Affiliated Hospital of Nantong University and Second Affiliated Hospital of Nantong University (China) examined the association of GV and other conventional risk factors with DPN [17]. DPN was diagnosed based on both neuropathic symptoms/signs and abnormal NC test results. Using a CGM system (Gold system; Medtronic), multiple GV parameters were calculated, including MACE, MODD, SD and 24-h mean glucose (24-h MG). Those T2DM subjects with DPN exhibited higher MAGE, MODD, SD, and 24-h MG (p < 0.001) [10]. Regression analysis showed that MAGE, T2DM duration, Homeostasis model assessment for insulin resistance (HOMA-IR) and HbA_1c were independent risk factors for DPN (OR 4.57, 95% CI 3.48–6.01; OR 1.10, 95% CI 1.03–1.17; OR 1.24, 95% CI 1.09–1.41; OR 1.33, 95% CI 1.15–1.53, respectively). Moreover, 4.60 mmol/L was the optimal MAGE cutoff for DPN identification (sensitivity 64.47%, specificity 75.54%) [17].

The Continuous Glucose Monitoring to Assess Glycemia in Chronic Kidney Disease (CANDY) study enrolled 105 subjects with T2DM who were treated with insulin or sulfonylurea (81 with moderate-to-severe chronic kidney disease [CKD] and estimated glomerular filtration rate [eGFR] < 60 mL/min/1.73 m²) and 24 controls from the same centre (eGFR ≥ 60 mL/min/1.73 m²). Glucose was monitored using a CGM system for two 6-days periods [18]. Participants were enrolled from nephrology clinics, the Diabetes Care Centre and referring clinics associated with the University of Washington, Seattle (USA). TIR (glucose 70–180 mg/dL) and GMI were assessed. DPN was diagnosed by the Michigan Neuropathy Screening Instrument (MNSI) questionnaire. DPN was seen in 63% of participants with CKD and in 46% of controls. Lower TIR and higher GMI were associated with a higher risk of DPN symptoms (OR 1.25, 95% CI 1.02–1.52) per 10% lower TIR; OR 1.79, 95% CI 1.05–3.04 per 1% higher GMI). Interestingly, no significant association between laboratory HbA_1c values and DPN symptoms was observed [18]. The majority of participants in this study had CKD. As one explanation of these results, the authors commented that as CKD is a factor affecting HbA_1c (HbA_1c tends to be lower in individuals with end-stage-kidney disease), HbA_1c in the enrolled patients with CKD was a less precise parameter for estimating glucose management compared with CGM metrics (TIR and GMI). Other potential explanations for their findings could include the limitations acknowledged by the authors: the cross-sectional observational design of the study, the relatively small sample size, the diagnosis of DPN by subjective symptoms (MNSI questionnaire), as well as the CGM-data being obtained from two 6-day-periods [18]. In view of the association between lower TIR and DPN symptoms, the need for adequate glycaemic control to prevent DPN was implied [18].

In agreement with these findings, the authors of another study reported for the first time a link between TIR and peripheral nerve function among 740 patients with T2DM patients [19]. TIR was assessed by CGM (Medtronic). Participants were divided into tertiles according to TIR values (low TIR: ≤ 53%; medium TIR: 54–76%; high TIR: ≥ 77%), and composite Z-scores of nerve conduction velocity (NCV), latency and amplitude were calculated [12]. Higher TIR values were associated with elevated composite Z-scores of NCV and amplitude and lower composite Z-scores of latency (all p < 0.05) [19]. In addition, the risk of TIR tertiles and worsening NCV was independent of HbA_1c (medium TIR: OR 0.48, p = 0.001; high TIR: OR 0.41, p < 0.001) [19]. Specifically, the authors used linear regression analysis to explore whether HbA_1c or TIR was more strongly associated with peripheral nerve function. HbA_1c was more closely related to the composite Z-score of the nerve function parameters, but TIR had an additional role [19]. Moreover, the risk of reduced NCV decreased with higher TIR after controlling for HbA_1c and other parameters. Finally, according to ROC analysis, adding TIR to the models increased the predictive performance of the logistic models to decreased NCV and to amplitude, suggesting that TIR might assess peripheral nerve function independent of HbA_1c [19]. Of note, the study was conducted among hospitalised patients and, therefore, the results must be carefully interpreted when extrapolating to the general/outpatient population [19].

Guo et al. [20] investigated the relationship between TIR and sudomotor function among 466 in-patients at the Endocrinology Department of Jinling Hospital, Nanjing with T2DM. Sudomotor function was assessed using Sudoscan technology (SUDOSCAN Inc., San Diego, CA, USA). TIR was evaluated after 3 days of CGM (Meiqi Corp., Shenzhen, Guangdong, China) [20]. Overall, 135 participants exhibited sudomotor dysfunction (28.9%) and low TIR. A TIR value within the middle and the highest tertiles was associated with a lower prevalence of sudomotor dysfunction (20.51% and 21.94% vs. 44.52%, p < 0.001) [13]. Moreover, after adjustment for confounding factors, TIR appeared to be inversely and independently associated with the presence of sudomotor dysfunction (OR 0.979, 95% CI 0.971–0.987, p < 0.001) [20].

Interestingly, the association between subclinical diabetic polyneuropathy and GV has also been studied [21]. Among 509 subjects with T2DM (147 with DPN) admitted to the Endocrinology Department of Shanghai Jiao Tong University Affiliated Sixth People’s Hospital (Shanghai, China), a significant association was revealed between SDgluc and abnormal nerve function (OR 1.198, 95% CI 1.027–1.397). Moreover, the composite Z-score of NCV and response amplitude decreased witn increasing SDgluc (p < 0.05) [21]. Even after adjustment for potential confounders (age, sex, BMI, HbA_1c and diabetes duration), high SDgluc was independently associated with slower NCV (b = − 0.124, p = 0.021) [21].

Finally, in an study of 281 outpatients with T2DM, as part of a multi-centre prospective cohort study (Hyogo Diabetes Hypoglycemia Cognition Complications [HDHCC] study, Japan), glucose was monitored with FreeStyle Libre Pro (Abbott Japan, Tokyo, Japan) during a 10-day period [22]. DPN was diagnosed by a combination of symptoms, signs, vibration perception threshold and NC parameters [22]. Multiple regression analyses revealed that DPN was associated with TIR deterioration (standard partial regression coefficient β = − 0.106, p = 0.033) [22].

In conclusion, studies performed to date in subjects with T2DM have shown an association of GV with DPN and painful neuropathy. Of note, GV has been also associated with subclinical DPN. These findings are in accordance with data derived from other studies which showed that worsening glycaemic control and GV are associated with the development and progression of complications in diabetes [23, 24].

Oyibo et al. [25] have examined the relationship between blood glucose excursions and painful diabetic neuropathy among 20 patients with type 1 DM (T1DM) and DPN randomly selected (10 with painful DPN and 10 with pain-free DPN). A CGM system (MiniMed system; Medtronic) was used for 3 days and MAGEs subsequently evaluated. Both groups, with and without pain, were similar in terms of age, T1DM duration, duration of neuropathy and CGM performance [25]. Mean glucose levels (p = 0.02) and M-values (as a measure of GV) (p = 0.02) were higher among T1DM subjects with painful neuropathy and, similarly, glucose excursions were more frequent among those subjects with painful DPN (p < 0.01); however, MAGE was similar between the two groups [25]. The authors suggested that reduced GV could contribute to the treatment of painful diabetic neuropathy, but we should bear in mind that this was a small study and the results need confirmation [25].

Kwai et al. [26] investigated the role of GV on peripheral nerve function among 17 patients with T1DM using a CGM system (Enlite sensor; Medtronic) and nerve excitability techniques. Patients were recruited consecutively from the Prince of Wales Hospital in Sydney (Australia). MAGE was calculated to quantify GV [26]. There were significant correlations of MAGE with excitability markers of altered motor and sensory axonal function (superexcitability: r = 0.54; S2 accommodation: r = − 0.76; minimum current/voltage (I/V) slope (expressed as rate of change per unit): r = 0.71; strength duration time constant: r = 0.66; latency: r = 0.65) (p < 0.05). Interestingly, there was no association between acute glucose levels and markers of axonal function [26].

The authors of another study included 159 subjects with T1DM and examined whether optimised glycaemic control (measured by improved HbA_1c) could improve vibration perception thresholds (VPTs) [27]. The latter were measured at six frequencies (range: 4–125 Hz) at the heads of the first and fifth metatarsal bones using a VibroSense Meter (VibroSense Dynamics, Malmö, Sweden). Patients were being treated at the Department of Endocrinology, Skåne University Hospital, Malmö (Sweden) and were examined twice between 2015 and 2018. Among those participants whose HbA_1c improved by > 1 mmol/mol (95 subjects), the mean Z-score, reflecting the combined effect of all VPTs, also improved and was lower at the follow-up compared with that at the baseline (0.2 [− 0.3 to 1.2] vs. − 0.1 [− 0.7 to 0.8], p = 0.00002) [27]. In contrast, no difference in VPTs was observed among participants whose HbA_1c was unchanged or deteriorated. The 4-Hz frequency was identified as the more sensitive frequency to detect improvements [27]. Unfortunately, GV was not measured in this study [27].

In a large U.S. population study that included 5936 participants with T1DM (T1D Exchange Clinic Registry), DPN was diagnosed by the Michigan Neuropathy Screening Instrument Questionnaire [28]. A CGM system was used by 33% of the participants. The authors found no difference between the subjects with and without DPN [28].

More recently, Feng et al. [29] examined the association between TIR (including nocturnal TIR) and sudomotor dysfunction in 95 subjects with T1DM (74.41% male) hospitalised in the Endocrinology Department of the Jinling Hospital, the First School of Clinical Medicine, Southern Medical University (China) to improve glucose control. TIR was measured using a 72-h blind CGM system (Meiqi Corp.). Sudomotor dysfunction was assessed using Sudoscan technology (Impeto Medical, Paris, France). Patients with sudomotor dysfunction exhibited lower TIR and nocturnal TIR, as well as higher TAR and nocturnal TAR in comparison with those free from sudomotor dysfunction [29]. Multiple regression analysis showed an inverse association of both TIR and nocturnal TIR with the risk of sudomotor dysfunction after adjustment for confounding factors [29].

Akaza et al. [30] examined the relationship between GV (estimated MAGE) and DPN in 40 outpatients of Shuuwa General Hospital (Saitama, Japan) with T1DM and T2DM (23 males and 17 females; age range: 34–79 years). Glucose levels were monitored with CGM, and DPN was diagnosed by NC study. In the multivariate linear regression analysis, MAGE was independently associated with a higher risk of medial plantar neuropathy (β = − 0.49, p = 0.007) [30].

Yan et al. looked at the association between TIR and the prevalence and degree of painful diabetic neuropathy among 364 patients with this condition [31]. Individuals were recruited at the Department of Endocrinology and Metabolism of Henan Provincial People’s Hospital (Zhengzhou, China). Based on a pain score, subjects were categorised into three groups: those who were pain-free and those with mild pain and moderate/severe pain, respectively. TIR was found to be associated with painful diabetic neuropathy, and was significantly lower among subjects with mild or moderate/severe pain than in those who reported no pain (p < 0.05) [31]. Moreover, the prevalence of pain decreased with increasing TIR (p < 0.05). Logistic regression analysis showed that lower TIR levels were significantly associated with an increasing risk of painful neuropathy (p < 0.05) [31].

In summary, GV has been associated not only with DPN but also with painful neuropathy. The pathogenesis of DPN involves several mechanisms. Of these, oxidative stress (induced by hyperglycaemia and acute glucose fluctuations) is receiving considerable attention [32]. Moreover, data support the possibility that GV could activate oxidative stress in a more intensive way than chronic hyperglycaemia [17, 33].