Difference and ratio of the cross-sectional area of median nerve at the carpal tunnel and the pronator quadratus muscle in diagnosing carpal tunnel syndrome: a cross-sectional study

Introduction

Carpal tunnel syndrome (CTS) is the most common peripheral nerve compression neuropathy in the upper limb (1-3), affecting about 3% to 6% of the general population and up to 14.5% among specific occupational groups (4,5). CTS results from compression of the median nerve (MN) at the wrist as it passes through a narrow, osteofibrous canal (6). CTS can be primary or secondary to other conditions such as flexor tenosynovitis, ganglion cyst, gouty tophi, bone deformity, arthritis, or tumor (7). Age has a significant impact on incidence, with incidence in women increasing with age and reaching a peak between 50 and 59 years. For men, CTS peaks at ages 50 to 59 and 70 to 79 (8). CTS is associated with certain occupations, particularly those involving hand motions with high intensity and frequency of repetition. A systematic literature review (9) reported that regular and prolonged use of hand-held vibratory tools increases the risk of CTS >2-fold. In addition to work-related risks, suspected risk factors for CTS include but are not limited to diabetes, menopause, hypothyroidism, obesity, arthritis, and pregnancy (6,10). The classic presentation of CTS is radiating pain, numbness, and tingling sensations. Paresthesias is not limited to the MN innervation region, but can involve the whole hand in a glove-shaped distribution (11). Symptoms are worse at night, and nocturnal awakening is common. In advanced cases, patients can experience muscle atrophy or paralysis (12-14). Therefore, early diagnosis is essential to reduce permanent neurological injury and functional disability.

Currently, the typical CTS diagnostic process involves making a preliminary diagnosis based on clinical manifestations, which is then confirmed by other examinations. Electrodiagnostic testing (EDT), which assesses physiologic malfunctions of the MN, is the most important auxiliary examination for the diagnosis of CTS. EDT can indicate the severity of the MN injury, but cannot reveal histomorphological changes of the MN and its peripheral tissue. EDT has a false negative rate of 5–10% (6,15), and these false-negative cases may be due to the onset of symptoms preceding impaired nerve conduction of myelinated sensory fibers.

Ultrasound (US) is a diagnostic imaging modality that can depict structural abnormalities caused by nerve swelling (16). Compared with EDT, US can be used not only to confirm the diagnosis and evaluation of CTS but also to distinguish between primary and secondary CTS (17). US provides insight into the causes of lesions and can inform subsequent surgical methods. A meta-analysis comparing the sensitivity and specificity of US with clinical diagnosis or EDT concluded that although US may not replace EDT, it may be a feasible alternative to EDT as a first-line confirmatory test (18). This finding has been validated by other studies (19-22).

Ultrasonic diagnostic indexes for CTS include the following parameters (23,24): transverse carpal ligament (TCL), MN cross-sectional area (CSA), MN blood flow exploration, and flattening ratio (FR), as well as palmar retinacular bowing (BR), and carpal tunnel volume. Among these parameters, measurement of the MN CSA is the most discriminatory and frequently used criteria of CTS (7). However, the MN CSA is greatly affected by individual factors such as race, gender, occupation, and body mass index (BMI) (25), making it difficult to establish a universal cutoff threshold to distinguish between control subjects and patients with CTS. We need to find a way through the noninvasive US examination, and the result is not influenced by individual factors. To solve this problem, more US parameters have been introduced to compensate for individual differences, such as the difference and ratio between the MN CSA at the carpal tunnel and the forearm, the ratio between the MN CSA and the carpal tunnel cross-sectional area (CSAC), and the difference and ratio between the MN CSA at the entrance and outlet of the carpal tunnel bone marker. One study (26) suggested that the MN CSA should be measured at the proximal 1/3 of the anterior pronator muscle, as this measurement value had the best repeatability. The difference (ΔCSA) and ratio (R-CSA) between the proximal cross-sectional area (CSAP) and the CSAC can better make up for individual differences and thus offer more advantages than either CSAC or CSAP alone in diagnosis accuracy.

The purpose of our study was to assess the accuracy of US in CTS diagnosis by analyzing differences in CSAC, CSAP, ΔCSA, and R-CSA between patients with CTS and healthy control subjects. The results of the CSA cutoff analysis using receiver operating characteristic (ROC) curves may be helpful in the diagnosis of CTS. We present the following article in accordance with the STARD reporting checklist (available at https://atm.amegroups.com/article/view/10.21037/atm-22-1128/rc).

Methods

Study design

This study is a cross-sectional study, which collects the distribution of factors related to CTS in a specific population at a specific time point and within a specific range, so as to provide clues for further research on the etiology.

Participants

Thirty-five patients (43 wrists) with CTS who were presented to the Affiliated Hospital of Nantong University between 2020 and 2021 underwent US evaluation, and 18 healthy subjects without CTS underwent an identical US evaluation as a control group. The project was approved by the Ethics Committee of Affiliated Hospital of Nantong University (No. 2019-L002) and was conducted in accordance with the Declaration of Helsinki (as revised in 2013). All patients signed informed consent prior to participation.

Inclusion criteria

The inclusion criteria which was based on the clinical diagnostic criteria of the American Academy of Neurology were as follows: (I) numbness or pain on the radial side of the thumb, index finger, middle finger, or ring finger of the affected limb, which was aggravated by certain activities and relieved after resting or swinging the hands; (II) sensory disturbance or weakness in three-and-a-half fingers on the radial side; (III) atrophy of the thenar muscle to varying degrees; (IV) Tinel test and/or Phalen test is positive; and (V) the MN sensory conduction velocity (SCV) slows down or the latency is prolonged. CTS can be diagnosed in patients who meet 2 or more of diagnostic criteria 1–4 and criteria 5.

Elimination criteria

Patients with MN diseases outside the wrist such as cervical spondylosis, brachial plexus injury, Struthers’ ligament compression, pronator teres syndrome, neuritis, MN injury, or neuroma were excluded.

General clinical parameters

Electrophysiological diagnosis of abnormal criteria

A difference of >0.4 ms between the median and ulnar sensory peak latencies or a prolonged median distal motor latency of >4 ms was taken as confirmatory electrophysiological evidence of CTS (27).

MN normal sonographic findings

In the two-dimensional US image, the nerve fibers were hypoechoic, the endoneurium and epineurium were linear hyperechoic, and the cross section of the MN was sieve-like with short-streak blood stream signals detected by the color Doppler. Nine medium hyperechoic tendons could be seen around and behind the nerve, and the hyperechoic TCL covered the surface of the carpal tunnel.

US technique

Patients with CTS received cross-section examinations of the affected wrist, while healthy controls were randomly assigned a unilateral or bilateral wrist examination. Patients in both groups were examined by the same examiner, who had over 15 years of US experience and was blinded to the patients’ clinical information or reference standard results. A GE Logiq E9 color Doppler US instrument (GE Healthcare, Chicago, IL, USA) was used in the study, and the frequency of the superficial line array probe was set at 12–15 MHz to examinate the patient’s musculoskeletal tissue.

Examination method

The patient sat by the examination bed with the arm in a neutral position (the palm flat on the bed, the forearm relaxed, and the wrist slightly extended). During the examination, the scanning area was coated with a thick coupling agent, and the probe was lightly attached to the skin surface to avoid the deformation and displacement of the MN caused by the probe pressure. The technician first performed longitudinal scanning along the long axis of the MN with a US probe to observe the position, route, and anteroposterior diameter of the patient’s carpal tunnel MN and to further determine the compressed and swollen areas. The probe then transected across the MN and remained perpendicular to it so that the MN was in the middle of the probe. The image was then observed and the MN CSA is measured by trajectory method. The examiner next moved the probe along the forearm to the distal third of the pronator quadratus muscle and measured the MN CSA with the same method. All measurements were taken three times for a median value (28,29). At last, the difference (ΔCSA) and ratio (R-CSA) between CSAC and CSAP was calculated in both patients and controls.

Statistical analysis

Prism 6 (GraphPad Software Inc., San Diego, CA, USA) and SPSS version 26 (IBM Corp., Armonk, NY, USA) statistical software were used for data analysis. The quantitative data were expressed as mean ± standard deviation (SD), while enumeration data were expressed as constituent ratio or rate (%). The CTS group and the healthy control group were compared using a t-test for the CSAC, CSAP, ΔCSA, and R-CSA measurements, and a chi-squared test was used to assess the occurrence of chronic disease and prior surgery among the study groups. A ROC curve was plotted for the CSAC, ΔCSA, and R-CSA measurements and used to calculate the cutoff values which provided the highest sensitivity, specificity, and accuracy for predicting CTS. In all analyses, P<0.05 indicated a statistically significant difference.

Results

Baseline characteristics of the subjects

CTS group

This group comprised 43 wrists of 35 patients, including 7 men (mean age, 52.8 years; range, 34–61 years) and 28 women (mean age, 53.3 years; range, 34–82 years), with an overall mean age of 53.3 years and an overall range of 34–82 years. There were 27 right wrists and 16 left wrists in the group. Eight patients had bilateral CTS, and 15 patients had received surgical treatment.

Control group

This group comprised 23 wrists of 18 healthy volunteers with no clinical signs or symptoms of CTS, including 5 males (mean age, 42.0 years; range, 26–63 years) and 13 females (mean age, 50.0 years; range, 28–78 years), with an overall mean age of 42.0 years and an overall range of 26–78 years. The demographic data of the CTS and control groups are outlined in Table 1.

Clinicopathological parameter correlation

Three patients in the CTS group had chronic diseases (complicated diabetes mellitus, hypertension, and chronic pneumonia), while no participants in the control group had chronic diseases. These data were statistically processed with a chi-squared test using SPSS version 26 (Table 2). There was no statistical significance (P>0.05). However, a previous meta-analysis (30) found that both type 1 and type 2 diabetes are associated with the occurrence of CTS. In our CTS group, 1 case was a diabetic, and the chi-squared test showed no statistical significance. Considering the small sample size of this study, the effect was small.

Seven patients in the CTS group had an operative history (complicated rib fractures, caesarean section, appendix resection, lumbar spine surgery, contralateral CTS incision decompression, gynecological operation, and radical mastectomy), while no participants in the control group had a history of surgery or trauma. These data were statistically processed with a chi-squared test using SPSS version 26 (Table 3). There was no significant difference (P>0.05).

Comparison of US results

In the control group, there was little change in the CSA and anteroposterior diameter of the MN, as shown in Figure 1. In the CTS group, obvious compression of the MN at the carpal tunnel was observed at the hook of the hamate bone, the MN was significantly thickened at the carpal tunnel inlet, and the transverse area was enlarged. On the longitudinal section, the MN was uneven in thickness and had a notch at the lamping position, the echo of the internal nerve bundle membrane was decreased, and the nerve was grid-form blurred (Figure 2).

Figure 1 Control group. The arrow indicates the cross-sectional area to be measured. (A) CSAC was 11.02 mm²; (B) a more CSAP obtained in the distal forearm at the level of the proximal third of the pronator quadratus muscle was 9.62 mm²; ΔCSA and R-CSA were 1.40 and 1.14 mm², respectively. ΔCSA, the difference of CSAC and CSAP; R-CSA, the ratio of CSAC and CSAP; CTS, carpal tunnel syndrome; CSAC, carpal tunnel cross-sectional area; CSAP, proximal cross-sectional area.

Figure 2 CTS group. The arrow indicates the cross-sectional area to be measured. (A) CSAC was 22.58 mm²; (B) CSAP was 10.39 mm²; ΔCSA and R-CSA were 12.19 and 2.17 mm², respectively. ΔCSA, the difference of CSAC and CSAP; R-CSA, the ratio of CSAC and CSAP; CTS, carpal tunnel syndrome; CSAC, carpal tunnel cross-sectional area; CSAP, proximal cross-sectional area.

Electrophysiological analysis

In the control group (Figure 3A), SCV, motor nerve conduction velocity (MCV), and F waves were within the normal range. In the CTS group (Figure 3B), there was no spontaneous potential in resting state, and the motor unit potential (MUP) time and potential of light contraction were normal. MCV was slowed down in the palmar carpal segment of the MN on the affected side, and compound muscle action potential (CMAP) wave amplitude was normal. Latency of wrist of the affected side was prolonged. The MCV of all segments of the ulnar nerve was normal, and CMAP wave amplitude was normal. MN sensory nerve action potential (SNAP) was not elicited, ulnar nerve SCV was normal, and SNAP amplitude was normal. MN and ulnar nerve F wave latency and occurrence rate were normal.

Figure 3 Electrophysiological manifestation in the 2 groups. (A) Control group; (B) CTS group. Ab Elb, above elbow; AMP, amplitude; Bel Elb, below elbow; CTS, carpal tunnel syndrome; CV, conduction velocity; dist, distance; dLAT, latent period; DUR, duration.

Data analysis results

As shown in Table 4 and Figures 4-7, there was a highly significant difference between the 2 groups regarding mean ± SD of CSAC, ΔCSA, and R-CSA (P<0.001). In comparison, the diagnostic value of CSAP was not obvious (P>0.001). To determine the accurate cutoff value and the most sensitive and specific threshold values, a ROC curve was produced and the area under the curve (AUC) was calculated. The AUC of CSAC was 0.9778, with a threshold value of 12.14 mm²; the AUC of R-CSA was 0.9949, with a threshold value of 1.235 mm²; and the AUC of ΔCSA was 1.000, with a threshold value of 2.035 mm² (Figure 8). The best diagnostic values were achieved by using a ΔCSA threshold of 2.04 mm².

Figure 4 Analysis of CSAC data in the 2 groups. The dotted line denotes the optimal cutoff value. GraphPad was used to calculate P values. ****, P<0.0001. CSAC, carpal tunnel cross-sectional area; CTS, carpal tunnel syndrome.

Figure 5 Analysis of CSAP data in the 2 groups. The dotted line denotes the optimal cutoff value. GraphPad was used to calculate P values. **, P<0.001. CTS, carpal tunnel syndrome; CSAP, proximal cross-sectional area.

Figure 6 Analysis of ΔCSA data in the 2 groups. The dotted line denotes the optimal cutoff value. GraphPad was used to calculate P values. ****, P<0.0001. ΔCSA, the difference of CSAC and CSAP; CTS, carpal tunnel syndrome; CSAC, carpal tunnel cross-sectional area; CSAP, proximal cross-sectional area.

Figure 7 Analysis of R-CSA data in the 2 groups. The dotted line denotes the optimal cutoff value. GraphPad was used to calculate P values. ****, P<0.0001. R-CSA, the ratio of CSAC and CSAP; CTS, carpal tunnel syndrome; CSAC, carpal tunnel cross-sectional area; CSAP, proximal cross-sectional area.

Figure 8 Analysis and comparison of ROC curve data of three values. (A) ROC analysis of all patients showed that the AUC of CSAC was 0.9778, and the optimal cutoff point was 12.14 mm² (sensitivity 90.7%, specificity 100%). (B) The AUC of R-CSA was 0.9949, and the optimal cutoff point was 1.235 mm² (sensitivity 97.67%, specificity 95.65%). (C) The AUC of ΔCSA was 1.000, and the optimal cutoff point was 2.035 mm² (sensitivity 100%, specificity 100%). D-value: ΔCSA. (D) A combination of the above 3 pictures for comparison, showing that the AUC of ΔCSA is obviously greater. ROC, receiver operating characteristic; CSAC, carpal tunnel cross-sectional area; CSAP, proximal cross-sectional area; R-CSA, the ratio of CSAC and CSAP; ΔCSA, the difference of CSAC and CSAP.

Discussion

CTS is a MN compression neuropathy that affects the wrist. It is the most frequent entrapment neuropathy (31,32), with high prevalence in females (33). Different criteria have been proposed for the diagnosis of CTS, depending on the individual doctor’s expertise and clinical experience. Apart from clinical evaluation, EDT is the most commonly used method for CTS diagnosis worldwide. Jablecki et al. (34) and Werner and Andary (4) summarized the advantages of the electrophysiological diagnostic method, including its high sensitivity and specificity. However, they also found that this method had a certain rate of missed diagnosis and could not provide information about MN peripheral conditions. Therefore, it is not sufficient to rely solely on EDT results for the diagnosis of CTS.

With improvements in US resolution, observations and measurements of the peripheral nerves have increased in accuracy, and there is now a broad consensus about the value of US in providing complementary information regarding nerve anatomy and neighboring structures within the carpal tunnel (18,35). Buchberger et al. (36) first made use of US to measure changes in the carpal tunnel MN of patients with CTS to assist in diagnosis (35). The most reliable ultrasonographic indicator of peripheral nerve entrapment neuropathy is enlargement of the nerve CSA. Previous studies have attempted to ascertain a universal cutoff value of the CSA for the diagnosis of CTS (26,37-41). The carpal tunnel inlet has been used as the MN CSA measurement point with a range of 8.5–15.0 mm², and the sensitivity (62.0–97.9%) and specificity (63–100%) of CTS diagnosis were also significantly different. To date, there is no standard universal cutoff range for the CSA, as the MN CSA may be affected by demographic factors such as body height, body weight, age, sex, and ethnicity.

In this study, we used a comparison between 2 levels of the MN to avoid potential bias caused by the aforementioned individual variations. We investigated the use of MN CSA measurements by US in patients with CTS and in control subjects without CTS to determine the best method of diagnosing CTS with US. We evaluated the CSAC and CSAP at the level of the pronator quadratus muscle. Furthermore, we calculated the difference (ΔCSA) and the ratio (R-CSA) between CSAC and CSAP to omit individual variability rather than depending on the CSA at the level of the carpal tunnel only. We found a statistically significant difference in the US values of CSAC, CSAP, ΔCSA, and R-CSA between CTS patients and healthy controls, and the best diagnostic values were achieved by using a ΔCSA threshold of 2.04 mm². These findings are in agreement with Klauser et al. (29). Our results suggest that ΔCSA measurements can compensate for interindividual variability in the MN CSA and yield a more accurate diagnosis of CTS.

Increased MN CSA is an important diagnostic indicator of compressive neuropathy. Long-term nerve compression causes changes in nerve microcirculation, making nerves prone to ischemia and leading to abnormal vascular endothelial permeability, which ultimately manifests as intra-nerve edema and an increased CSA measurement. As compression increases, symptoms worsen, and this may manifest as a CSA increase on US. This suggests a certain relationship between the severity of CTS and the measurement of the CSA, which has been confirmed (42). With respect to CTS US classification criteria, an increasing number of studies have provided data on the relationship between the MN CSA and the grading of CTS severity. However, these standards are not uniform, for the following reasons. First, the studies use different standards for classification. Second, different US technologies, methods of measurement, and machine resolutions create bias in the results. Third, CSAC is closely linked to individual factors such as age, gender, body weight, and ethnicity.

Padua et al. (43) and Karadağ et al. (44) have shown that electrophysiological diagnosis and US are consistent when classifying CTS severity. Phongamwong et al. (45) conducted a characteristic analysis of 106 patients with moderate and severe CTS; their results showed that a CSA cutoff value measured at the carpal tunnel inlet of 14 mm² had a specificity of 91.4% and a sensitivity of 42.3% in diagnosing moderate to severe CTS. In 2019, Roomizadeh et al. (46) conducted a meta-analysis of 16 studies with a sample size of 2,292 wrists. Lesion severity was graded in accordance with the electrophysiological results, and the carpal tunnel inlet was selected as the measurement location to obtain the CSA thresholds of different levels. The pooled results showed a MN CSA of 11.64 mm² for mild CTS, 13.74 mm² (adjusted: 13.43 mm²) for moderate CTS, and 16.80 mm² (adjusted: 16.36 mm²) for severe CTS.

With respect to the ΔCSA index used for classification, Klauser et al. (47) conducted a US examination of 427 patients (643 wrists), and the results showed that the optimal critical values of ΔCSA for mild to moderate CTS and moderate to severe CTS were 6 and 9 mm², respectively. In a 2021 cross-sectional study, Ji (48) showed that the best cutoff values of CSA for mild to moderate CTS and moderate to severe CTS were 6.32 and 8.82 mm², respectively.

Despite the high value of US in the classification of CTS, Martikkala (49) and Mohammadi (24) have suggested that MN transsectional US has value in the diagnosis or exclusion of CTS but cannot be used to grade the severity. However, these studies only focused on CSAC and did not further compare ΔCSA with electrophysiology. Therefore, the authors of the present study maintain a neutral attitude towards this point of view, as more data are needed to compare the value of ΔCSA and electrophysiological diagnostic classification of CTS.

In conclusion, there is a correlation between ultrasonography and EDT in providing an objective basis for the clinical diagnosis and classification of CTS. These 2 diagnostic methods can complement each other and reduce missed diagnoses. Kamolz et al. (50) has suggested that patients suspected of CTS should be first diagnosed by experienced clinicians, and then the MN and its surrounding structures should be assessed by US to rule out anatomic variation or other etiology. Finally, patients who are negative on US but have some or all symptoms and do not respond to treatment may be referred for EDT. For patients with atypical symptoms or more extensive neuropathy, EDT should be the first choice, with US used as a supplementary test.

Conclusions

US examination is a noninvasive and simple method for CTS diagnosis. This method has good clinical application value, as it can be used to identify morphological abnormalities of the MN and its surrounding tissues and can thus inform the preparation of a surgical plan. MN activity combined with CSA measurements are valuable in US diagnosis of CTS, while CSAC, ΔCSA, and R-CSA measurements can help determine the severity of CTS. The ROC curve analysis showed that among these 3 measurements, ΔCSA was the most useful for the diagnosis, evaluation, and treatment of patients with CTS. As a correction index that excluded individual influencing factors, ΔCSA was more accurate and had a higher diagnostic value. Our results suggest that US examination, which is safe and noninvasive, can be used to guide clinical diagnosis and treatment of CTS.

Acknowledgments

Funding: This research received funding from the National Natural Science Foundation of China Youth Fund (81801893), the Nantong Clinical Medicine Research Center (HS2019005, HS2020001), Natural Science Research Project of Nantong Science and Technology Bureau (MS12021021, MS12020006, MS12020017, MS12021035), Jiangsu Planned Projects for Postdoctoral Research Fund (2021K031A), Deputy General Manager Project of Science and Technology of Jiangsu Province (FZ20210652), Jiangsu geriatric clinical technology application research project (LR2021047).

Footnote

Reporting Checklist: The authors have completed the STARD reporting checklist. Available at https://atm.amegroups.com/article/view/10.21037/atm-22-1128/rc

Data Sharing Statement: Available at https://atm.amegroups.com/article/view/10.21037/atm-22-1128/dss

Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://atm.amegroups.com/article/view/10.21037/atm-22-1128/coif). The authors have no conflicts of interest to declare.

Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. The project was approved by the Ethics Committee of Affiliated Hospital of Nantong University (No. 2019-L002) and was conducted in accordance with the Declaration of Helsinki (as revised in 2013). All patients signed informed consent prior to participation.

Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.

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(English Language Editor: C. Gourlay)