Congenital limb deficiency in Japan: a cross-sectional nationwide survey on its epidemiology

The method used to estimate the number of patients is as follows [25, 26]:

Let n be the number of all departments, and n_i be the number of departments with a number of targeted patients i (i = 0, 1, …). Let N be the number of responding departments and N_i be the number of responding departments with a number of patients i (i = 0, 1, …). N and N_i were obtained from the survey, and {N_i} followed a multi-hypergeometric distribution under the assumption of random response and under the condition that N is fixed.

Let a be the total number of patients; note that a = ∑i∗n_i. The estimate of a was calculated as.

where s is an estimate of standard error of a^ and is given to be.

\( s=\sqrt{\frac{\sum {i}^2\ast \frac{N_i}{N}-{\left(\sum i\ast \frac{N_i}{N}\right)}^2}{n-1}\kern0.28em \ast \kern0.28em {n}^3\kern0.28em \left(\frac{1}{N}-\frac{1}{n}\right)\kern0.28em }. \)

The number of patients in some strata was estimated using the above method. Let k be the number of strata, a₁^, a₂^, …, a_k^ be the estimated numbers of patients in some strata, and s₁, s₂, …, s_k be their standard errors. The approximate confidence intervals for the sum of the number of patients in the strata were calculated as.

where a. = a₁ ^  + a₂ ^  + … + a_k^ and \( s=\sqrt{{s_1}^2+{s_2}^2+\dots +{s_k}^2} \).

Using the results of the first survey, the number of patients and 95% confidence intervals were estimated using the above procedure. Additionally, we corrected these using the ineligibility rate and duplication rate from the second survey. To obtain the final estimates and confidence intervals, we multiplied their values in the first survey by “1 − ineligibility rate” and “1 − duplication rate”, respectively.

Table 1 summarizes the results of the first survey and shows the corrected number of patients with the results of the second survey. Of 2283 departments selected from the 7825 departments in Japan, 1767 responded to the first questionnaire concerning the number of patients with initial visits who had congenital limb deficiency: the response rate for the first survey was 77.4%. Details of the number of all, surveyed, and responding departments are shown in Additional file 1. Among them, 161 departments reported one or more patients with an initial visit. We then conducted the second survey among these 161 departments. Ninety-six departments responded to the second questionnaire concerning demographic and clinical information; the response rate for the second survey was 59.6%. Of these 96 departments, whereas a total number of 534 patients had an initial visit in the first survey, 491 patients with initial visits were recorded in the second survey. This difference of 43 patients was considered to represent ineligible patients and those excluded by the target departments. Some departments reported the reasons for exclusion as follows: intermixing of patients whose initial visit did not fall within the target period or did not fit the diagnosis (e.g., patients with acquired limb defects) in the first survey. Of the 491 patients, we excluded 38 ineligible patients and 42 duplicated patients; finally, 411 patients were eligible for inclusion in the analysis of demographic and clinical information. Of the 38 ineligible patients, 27 did not fall within the target period and 11 did not fit the diagnosis (4 patients had deficits of only the middle and/or distal phalanx, 4 had brachydactyly without deficits, 2 had constriction band without deficits, and 1 patient had polydactyly). The ineligibility rate was 15.2% and the duplication rate was 9.3%.

We estimated that the number of initial visits of patients with congenital limb deficiency between 2014 and 2015 was 417 per year, (95% confidence interval 339–495). Considering that at the initial visit, most patients were aged 0 years, and that the number of live births in Japan was 1.004 million in 2014 and 1.006 in 2015, we estimated the prevalence of congenital limb deficiency with the assumption that the number of live births was 1.005 million (average of 2014 and 2015). The estimated prevalence was 4.15 (95% confidence interval 3.37–4.93) per 10,000 live births.

Among 411 patients reported in the second survey, there were 240 males and 171 females; the sex ratio was 1.40. Assuming an equal sex ratio (50% male, 50% female), a chi-square test yielded χ² = 11.58, and p = 0.0007. This result suggests that males have a significantly higher prevalence of congenital limb deficiency than females.

Table 2 summarizes the age of patients at their initial visit. Congenital limb deficiencies develop during the foetal stage, or before birth. The age reflects the patients’ access to medical care. It is necessary to consider that in cases of duplication, we included data for the date of the most recent initial visit to a department. A total 276 (67.2%) patients visited the hospital at age 0 years. The number of patients with initial visits decreased with advancing age.

Among 411 patients reported in the second survey, 275 (66.9%) had one affected limb, 83 (20.2%) had two, 23 (5.6%) had three, and 30 (7.3%) had four affected limbs. There were 275 patients (66.9%) with only the upper limbs affected, 75 (18.2%) with only lower limbs affected, and 61 (14.8%) with both upper and lower limbs affected.

The 411 patients had a total of 630 affected limbs among them. Four limbs had different classifications of deficiency (a total of 634 limb deficiencies) and all four affected limbs had coexisting proximal femoral focal deficiency and fibular dysplasia. Affected limbs were as follows: 218 (34.6%) were right upper limbs, 224 (35.6%) were left upper limbs, 105 (16.7%) were right lower limbs, and 83 (13.2%) were left lower limbs.

Table 3 summarizes the classification of limb deficiency. For upper limbs deficiencies, transverse deficiency was the most prevalent (45.5%), followed by longitudinal deficiency(31.2%). For lower limbs deficiency, longitudinal deficiency was the most prevalent (37.0%), followed by transverse deficiency(31.8%). For longitudinal deficiency, whereas there was not much difference between tibial deficiency (33 limbs) and fibular deficiency (37 limbs) in the lower limbs, radial deficiency (110 limbs) was more prevalent than ulnar deficiency (27 limbs) in the upper limbs. For transverse deficiency, both upper limbs and lower limbs had similar tendencies in that distal deficiency comprised a large proportion and proximal deficiency was less frequent. The prevalence rates of intercalary, central, and other finger column deficiency were similar for both upper and lower limbs.

Coexisting disorders with relatively high prevalence (over 1%), were cardiac anomaly, vertebral anomaly, renal anomaly, anal atresia, hypospadias, cleft lip/palate and developmental disorders (autism spectrum syndrome or attention deficit hyperactivity disorder) (10.2, 3.6, 2.4, 2.4, 2.2, 1.2, and 1.0% respectively). Eleven patients had chromosomal abnormality: 3 had 17p-related abnormalities (duplication, microduplication and deletion), 4 had trisomy 21, 1 had trisomy 18, 1 had 48 XXXX, and 2 patients unspecified chromosomal abnormalities. Seventeen patients were diagnosed with or suspected of having the following specific syndromes, associations or sequences: 5 patients had VATER association, 4 had Poland syndrome (1 patient concomitantly had Moebius syndrome), 2 had Cornelia de Lange syndrome, and 1 each, had Apert syndrome, CHARGE syndrome, FATCO syndrome, KOSAKI syndrome, Leri-Weill syndrome, Nager syndrome, Silver-Russell syndrome, facioauriculovertebral sequence, and autosomal dominant epidermolysis bullosa dystrophica (we excluded amniotic bands syndrome). Approximately 66.4% of patients had no coexisting disorders.

Seventeen (4.1%) patients had a family history of congenital limb deficiency, and 165 (40.1%) had no such history. The family histories of 229 (55.7%) patients were unknown. The extent of family history was left to the discretion of each department.

Table 4 shows the details of 17 patients with a positive family history of congenital limb deficiency. The breakdown of these 17 patients was as follows: 9 with split hand deformity; 3 with ulnar deficiency; 2 each with upper limb transverse deficiency, split foot, and tibial deficiency; and 1 each with radial deficiency, lower limb transverse deficiency, and other finger column deficiency. Four patients had multiple types of deficiencies: 1 each with split hand and foot, split hand and tibial deficiency, ulnar deficiency and split foot, and ulnar deficiency and tibial deficiency. Most columns in the questionnaire requiring information about the limb deficiency of family members were left blank; therefore, we could not identify whether the type of deficiencies were the same for these patients.

Although the response rate for the first survey was high (77.4%), the ineligibility rate (15.2%) in the second survey seemed somewhat high. The main reason for exclusion was that the time of the initial visit did not correspond with the target period. In addition, there were some patients who did not fit the appropriate definition of congenital limb deficiency used in this study (defined as partial or total absence of the limbs proximal to the proximal interphalangeal joint of fingers/lesser toes or interphalangeal joint of the thumb/great toe). The disease concept of congenital limb deficiency has not been established in Japan. The estimates number in the present study may have been overestimated or underestimated, or may have changed in accordance with the definition used for this disease.