Preterm birth does not increase the risk of developmental dysplasia of the Hip: a systematic review and meta-analysis

Studies were eligible for inclusion if they reported on the association between preterm birth and DDH. Prospective and retrospective cohort studies and cross-sectional studies were eligible. Studies with unavailable full text, incomplete data, systematic reviews, case series, case reports, pilot studies, letters, correspondents, and commentaries and non-English publications were excluded.

A systematic literature review was conducted on 1^st September 2022 on the following electronic databases: Medline, Embase, Scopus, and Web of Science without any restrictions on publication date. Derived from our research question, "Is there an association between preterm birth and DDH” an expanded search based on Medical Subject Headings (MeSH) and keywords with Boolean operators ("Developmental Dysplasia of the Hip" [Mesh]; "Developmental Hip Dysplasia*"; "Developmental Hip Dislocation*"; DDH; "Premature Birth" [Mesh]; "Preterm Birth*"; "Birth Preterm"; "Birth Premature"; "Preterm Neonate*"; "Preterm"; "Premature Infant*"; "Preterm Infant*"; "Premature") was performed and documented in Supplementary file 1. In addition, a manual search was performed on 10^th December 2022 to identify more studies trough a snowballing technique.

Two independent reviewers (P.Sh and Gh.R) screened the search results using Covidence systematic review management software and in cases of any disagreement, a third author (A.Gh) supervised the process and made the final decision.

Dual independent data extraction was conducted by two authors (P.Sh and Gh.R) and discrepancies were discussed and resolved by the third author (A.Gh). Basic data including: the first author, publication year, country of origin for the study, study design, study center and the number of centers/clinics/areas, sample size, sex (Girl: boy), delivery type (cesarian or normal vaginal delivery (NVD)), birth weight in grams, breech presentation, and family history of DDH were recorded. Preterm and term population data consist of: Number of terms and preterm cases, preterm and term definition, inclusion and exclusion criteria, and loss to follow-up. And the outcome data extraction involves the age of DDH diagnosis, screening methods, types of Graf classification, number of patients with DDH in term and preterm children, and number of hips with DDH in term and preterm children. If the studies include the number of hips with DDH except for the number of participants with DDH, we will contact the study authors to obtain data on the number of cases with DDH. Extracted data imported to an excel sheet for further analyses and synthesis.

Included studies were assessed independently by the same authors for possible reporting biases by Risk Of Bias In Non-randomized Studies—of Interventions (ROBINS-I), a 7-items checklist [13]. All disagreements were discussed and resolved by the third reviewer.

The publication bias was assessed by examining the degree of asymmetry of a funnel plot in RevMan 5.4 and Egger’s regression test in CMA.

Among a total of 738 references that were imported for screening, 192 duplicates were removed and 546 studies remained for screening against title and abstract. 26 studies assessed for full-text eligibility. Another 13 studies were excluded in the full-text review: ineligible study design (n = 4), wrong intervention (n = 5), wrong outcomes (n = 3), and not English (n = 1). Two studies were identified through manual research and finally, 15 studies were included in this systematic review (Fig. 1) [6, 8, 11, 12, 14‐24]. Risk of bias assessment is summarized in Table 1. One third of the included studies were prospectively designed [8, 12, 17, 20, 23]. Six, Seven, and two articles were deemed to have low, moderate, and high risk of bias, respectively. Risk of Selection bias and bias due to deviations from intended interventions were two major reasons that made us to classify two studies in the high-risk group [12, 16]. The total population comprised of 35,030 infants, of whom approximately 51.4% were girls and 20.0% were premature. Delivery types were discussed in 6 articles (21,372 infants), which was a Caesarean section in 46.8% [6, 15, 19, 21, 22, 24]. Based on 11 out of 15 studies, 14.6% had a breech presentation at the time of delivery. Main characteristics of the eligible articles are summarized in Table 2 [6, 12, 14, 15, 17‐19, 21‐24].

There were 759 newborns diagnosed with DDH in the included studies (Table 3). Pooled incidence of DDH in preterm children was calculated utilizing data from 12 studies [6, 8, 14‐22, 24]. According to the meta-analysis, DDH was diagnosed in 2.0% [95% CI: 1.1—3.5%] of the premature newborns (Fig. 2). However, there was considerable data heterogeneity of the studies (Q = 94.55, I² = 88.36%, p < 0.001). Therefore, we performed subgroup analyses in order to detect significant differences between subgroups regarding the preterm definition, DDH Graf type, and study region. Eight studies set a limit of 37 weeks to define preterm birth [8, 14‐18, 21, 22], but lower than 37 weeks in three other studies [6, 19, 20]. However, there was no significant difference between groups in terms of preterm birth definition (2.5% [1.3%—4.6%] vs. 1.1% [0.1%—9.6%]; Q (subgroup difference) = 0.454, p = 0.500) (Supplementary file 2). Also, the definition of DDH was not identical in the studies. Graf types IIa and above, IIb and above, or IIc and above were considered DDH in three [18, 21, 24], two [16, 19], and five articles [8, 14, 15, 17, 20], respectively. Pooled incidence rate of DDH was not statistically different between those groups (2.5% [0.9%—6.8%] vs. 0.7% [0.2%—2.5%] vs. 1.7% [0.6%—5.3%]; Q (subgroup difference) = 2.363, p = 0.307) (Supplementary file 3). DDH incidence was reported higher in Australia (4.3% [1.9%—9.6%]), followed by East Asia (3.5% [1.1%—10.8%]), North America (1.6% [0.1%—21.1%]), and Europe (1.1% [0.4%—3.2%]). However, this difference was not significant (Q (subgroup difference) = 4.192, p = 0.241) (Supplementary file 4). Egger’s regression test indicated no publication bias in our main analysis (p = 0.07) (Supplementary file 5).

The major endpoint of our study was to determine whether preterm birth is a risk factor of DDH or not. A total of ten papers reported the proper comparative data. Eight studies reported the number of patients with DDH as their primary outcome [14‐17, 20‐22, 24]. On the other hand, two other studies considered each hip separately in their analysis [12, 23]. Due to this discrepancy, we decided to analyze these subgroups (patient – hip) separately. The pooled analysis demonstrated that there was no significant difference between preterm and term infants in terms of DDH incidence in either patient subgroup (OR = 0.87 [0.66 – 1.14], Z = 1.03, p = 0.30) or hip (OR = 0.64 [0.24 – 1.75], Z = 0.87, p = 0.39) (Fig. 3). Low to moderate heterogeneity was noted in patient subgroup (Chi² = 10.25, I² = 32%, p = 0.17) unlike the hip subgroup (Chi² = 11.98, I² = 92%, p < 0.001). Subgroup analysis based on the DDH definition (according to the Graf types) was also performed utilizing the available data from all eight studies reporting patient number. No meaningful association was observed between preterm birth and DDH in all various definitions (Graf type IIa and above: OR = 0.50 [0.08 – 3.32], Z = 0.72, p = 0.47; Graf type IIb and above: OR = 2.69 [0.49 – 14.78], Z = 1.14, p = 0.26; Graf type IIc and above: OR = 0.78 [0.49 – 1.24], Z = 1.07, p = 0.28; Graf type not mentioned: OR = 1.27 [0.25 – 6.40], Z = 0.29, p = 0.77) (Fig. 4). Three studies had sufficient data regarding the DDH risk in very preterm newborns (< 32^nd week) compared with those born in 32^nd to 37^th gestational week [15, 18, 22]. The meta-analysis revealed that very preterm birth was significantly associated with lower DDH incidence (OR = 0.44 [0.25 – 0.77], Z = 2.90, p = 0.004) with a low data heterogeneity (Chi² = 2.45, I² = 18%, p = 0.29) (Fig. 5).

Five studies had relevant data about the probable risk factors for DDH in premature infants [6, 11, 19, 22, 23]. Of those factors, only female sex and breech presentation could be quantitatively analyzed. Female sex did not have a significant association with DDH incidence in preterm newborns either in patient-reported (OR = 2.16 [0.65 – 7.23], Z = 1.25, p = 0.21) or hip-reported subgroups (OR = 2.06 [0.98 – 4.33], Z = 1.91, p = 0.06) (Fig. 6). Simic et al.’s investigation was the only one indicated a significant relationship between sex and DDH (OR = 2.83 [1.78 – 4.51]) [23]. Similarly, there was not a noteworthy association between breech presentation and DDH in patient-reported subgroup (OR = 1.89 [0.69 – 5.22], Z = 1.23, p = 0.22) (Fig. 7). However, Simic et al. (reporting hip number) found it statistically significant unlike the others (OR = 2.16 [1.24 – 3.77], Z = 2.73, p = 0.006) [23]. Lack of sufficient data concerning other variables did not allow us to perform the meta-analysis. Jeon et al. evaluated some other factors like gestational age and body weight in those treated due to DDH compared to the control group [6]. Nonetheless, none of them was significantly different between two groups (p = 0.583, p = 0.607, respectively).