Pectus excavatum: the effect of tricuspid valve compression on cardiac function.

BACKGROUND: Pectus excavatum (PE) is a common congenital chest wall deformity with various associated health concerns, including psychosocial impacts, academic challenges, and potential cardiopulmonary effects. OBJECTIVE: This study aimed to investigate the cardiac consequences of right atrioventricular groove compression in PE using cardiac magnetic resonance imaging. MATERIALS AND METHODS: A retrospective analysis was conducted on 661 patients with PE referred for evaluation. Patients were categorized into three groups based on the degree of right atrioventricular groove compression (no compression (NC), partial compression (PC), and complete compression(CC)). Chest wall indices were measured: pectus index (PI), depression index (DI), correction index (CI), and sternal torsion. RESULTS: The study revealed significant differences in chest wall indices between the groups: PE, NC=4.15 ± 0.94, PC=4.93 ± 1.24, and CC=7.2 ± 4.01 (P<0.0001). Left ventricle ejection fraction (LVEF) showed no significant differences: LVEF, NC=58.72% ± 3.94, PC=58.49% ± 4.02, and CC=57.95% ± 3.92 (P=0.0984). Right ventricular ejection fraction (RVEF) demonstrated significant differences: RVEF, NC=55.2% ± 5.3, PC=53.8% ± 4.4, and CC=53.1% ± 4.8 (P≥0.0001). Notably, the tricuspid valve (TV) measurement on the four-chamber view decreased in patients with greater compression: NC=29.52 ± 4.6; PC=28.26 ± 4.8; and CC=24.74 ± 5.73 (P<0.0001). CONCLUSION: This study provides valuable insights into the cardiac consequences of right atrioventricular groove compression in PE and lends further evidence of mild cardiac changes due to PE.

Evaluating Cardiac Lateralization by MRI to Simplify Estimation of Cardiopulmonary Impairment in Pectus Excavatum.

BACKGROUND: The severity of pectus excavatum is classified by the Haller Index (HI) and/or Correction Index (CI). These indices measure only the depth of the defect and, therefore, impede a precise estimation of the actual cardiopulmonary impairment. We aimed to evaluate the MRI-derived cardiac lateralization to improve the estimation of cardiopulmonary impairment in Pectus excavatum in connection with the Haller and Correction Indices. METHODS: This retrospective cohort study included a total of 113 patients (mean age = 19.03 ± 7.8) with pectus excavatum, whose diagnosis was verified on cross-sectional MRI images using the HI and CI. For the development of an improved HI and CI index, the patients underwent cardiopulmonary exercise testing to assess the influence of the right ventricle's position on cardiopulmonary impairment. The indexed lateral position of the pulmonary valve was utilized as a surrogate parameter for right ventricle localization. RESULTS: In patients with PE, the heart's lateralization significantly correlated with the severity of pectus excavatum (p ≤ 0.001). When modifying HI and CI for the individual's pulmonary valve position, those indices are present with greater sensitivity and specificity regarding the maximum oxygen-pulse as a pathophysiological correlate of reduced cardiac function (χ2 10.986 and 15.862, respectively). CONCLUSION: The indexed lateral deviation of the pulmonary valve seems to be a valuable cofactor for HI and CI, allowing for an improved description of cardiopulmonary impairment in PE patients.

Novel index to estimate the cephalocaudal extent of the excavation in pectus excavatum: The Titanic index.

BACKGROUND/PURPOSE: Quantification of the severity of pectus excavatum deformities is currently performed using the Haller index (HI) and the Correction index (CI), amongst others. However, most indexes characterize the severity at the point of maximum excavation. We present a new index, the Titanic index (TI), aimed at the appraisal of the cephalocaudal extent of the excavation and its potential clinical use. MATERIALS AND METHODS: Retrospective analysis of a cohort of patients who underwent a minimally invasive repair of pectus excavatum (MIRPE) between July 2020 and April 2022 at a single center. We defined TI as the percentage of the sternum that lied behind the anterior costal line observed in the CT. Demographics, HI, CI, and TI calculated based on computed tomography images (CT) were analyzed. Also, we compared the severity indexes of two groups of patients divided by the number of implants introduced per patient (group A: two implants, and group B: more than two). RESULTS: Seventy-eight patients (92% male) were included, with a mean age of 17.2 ± 4.8 years. The mean TI was 37%. Albeit weak, we identified significant correlations between the TI and the HI and, more closely, to the CI. Two implants were introduced in 37 (47%) patients, and more than two in 41 (53%) patients. Compared to patients with two implants, the group of patients who received more than two implants were older and showed worse thoracic indexes. Using receiver operating characteristic curve analysis, we identified the TI as a better predictor of the need for more than two implants than HI and CI. In this regard, a TI larger than 66.5% had a sensitivity of 93% and a specificity of 92%. CONCLUSION: We propose a novel index for the categorization of the severity of pectus excavatum. This index might be useful in planning the number of implants required for complete thoracic remodeling during MIRPE. LEVEL OF EVIDENCE: Level III. TYPE OF STUDY: Retrospective Comparative Study.

Influence of implant density and flexibility index on curve correction after scoliosis surgery.

BACKGROUND: Numerous studies proved that all pedicle screw constructs produce the best outcome in the surgical treatment of patients with scoliosis. However, the optimal amount and distribution of screws has not yet been defined. In recent studies on idiopathic scoliosis, the correlation between curve correction and implant density has been discussed with diversifying results. PURPOSE: The aim of this study was to detect a possible correlation of sagittal and coronal curve correction in dependence of metal load and flexibility index. MATERIALS AND METHODS: Twenty-six patients were included in this study with surgical correction by one surgeon between January 2014 and December 2017. Clinical data and radiographic images (preoperative, postoperative and one-year follow-up) were retrospectively analyzed and metal load, flexibility index, correction rate and correction index were consequently calculated. The Pearson correlation analysis was used for metal load-correction index and metal load-correction rate, correction of kyphosis-metal load and correction of lordosis-metal load. According to the mean metal load of 88%, patients were divided into two subgroups-a low-density group of 12 patients and a high-density group of 14 patients. Clinical and radiographic features were examined by an independent two-sided t-test. RESULTS: Eight patients were male, 18 patients female. Ten suffered from neuromuscular and 16 from idiopathic scoliosis. Mean age was 17.1 years. Correction rate directly postoperative was 70.43%, at the follow-up 67.90%. Mean correction index directly postoperative was 3.40 and at the follow-up 3.23. Pearson correlation of metal load-correction index directly postoperative was - 0.188 and one year postoperative - 0.189. The correlation between metal load-correction rate immediately after the surgery was 0.324 and at the follow-up 0.285. Correlation for correction of kyphosis-metal load postoperative was - 0.120 and one year later - 0.178. Pearson coefficient of lordosis-metal load directly after the surgical intervention was - 0.214 and at the follow-up - 0.220. Dependency of flexibility index and correction rate showed a positive trend (Pearson flexibility-correction rate direct 0.616; flexibility index-correction rate follow-up 0.516). A statistically significant difference between the high- and the low-density group was detected in the correction rate directly postoperative (p = 0.047). CONCLUSION: With an implant density over 70%, satisfactory surgical treatment can be achieved in idiopathic and neuromuscular scoliosis. No statistical significance between the high-density (88-100%) and the low-density (73-87%) group could be verified in curve correction, ICU stay and complications.

An assessment of association of thyroid volume with growth indicators and comparison of different thyroid volume indexes in children aged 8 - 10 years in Sichuan Province / 中华地方病学杂志

Objective:To explore the effect of physical development on thyroid volume of children aged 8 - 10 years in Sichuan Province, and explore the thyroid volume correction method suitable for school-age children, so as to accurately prevent and control iodine deficiency disorders.Methods:From June to July 2020, Shuangliu District of Chengdu City, Pengshan District of Meishan City, Miyi County of Panzhihua City and Qingchuan County of Guangyuan City were selected as the survey counties (districts). One township (town and street) was selected from each county (district) according to the five directions of East, West, South, North and Middle, one primary school was selected from each township (town and street), and 40 children aged 8 - 10 years (gender and age balanced) were selected as the survey subjects from each primary school, height and weight were measured, the body mass index (BMI) and body surface area (BSA) were calculated. Thyroid volume was measured by B-ultrasound, and the different thyroid volume indexes [height volume index 1 (HVI1), height volume index 2 (HVI2), body mass volume index (BMIV), weight and height volume index (WHVI), body surface volume index (BSAV)] were calculated, respectively. Urine samples of all children were collected, the iodine concentration in urine was measured, and the correlation between different measurement indexes and children's growth and development indexes was analyzed.Results:A total of 805 children aged 8 - 10 years were investigated, including 403 boys and 402 girls. There were 312, 288 and 205 children in the 8-, 9- and 10-year-old groups, respectively. A total of 805 urine samples were collected, and the median urinary iodine was 251.4 μg/L. There was no statistically significant difference in thyroid volume between boys and girls ( Z = - 0.44, P = 0.661), but was statistically significant difference between ages ( H = 64.95, P < 0.001). In all age groups, thyroid volume was positively correlated with height and weight (8-year-old group: r = 0.29, 0.42, P < 0.001; 9-year-old group: r = 0.29, 0.41, P < 0.001; 10-year-old group: r = 0.34, 0.47, P < 0.001). In all age groups, after HVI1 correction, thyroid volume was positively correlated with height and weight (8-year-old group: r = 0.13, 0.32, P < 0.05; 9-year-old group: r = 0.12, 0.30, P < 0.05; 10-year-old group: r = 0.18, 0.37, P < 0.05). In all age groups, there was a positive correlation between thyroid volume and weight after HVI2 correction (8-year-old group: r = 0.20, P < 0.001; 9-year-old group: r = 0.17, P = 0.004; 10-year-old group: r = 0.26, P < 0.001). In the 8- and 10-year-old groups, there was a positive correlation between thyroid volume and height after BMIV correction ( r = 0.20, P < 0.001; r = 0.21, P = 0.003). In all age groups, there was a negative correlation between thyroid volume and height and weight after WHVI correction (8-year-old group: r = - 0.35, - 0.37, P < 0.001; 9-year-old group: r = - 0.38, - 0.39, P < 0.001; 10-year-old group: r = - 0.31, - 0.38, P < 0.001). In the 8-year-old group, there was a positive correlation between thyroid volume and weight after BSAV correction ( r = 0.11, P = 0.045). Conclusions:Thyroid volume is closely related to height and weight. It may be inappropriate to judge goiter in children only based on age. After the preliminary comparison of five correction methods, it is found that BSAV is better.

The effect of in vitro digestion, food matrix, and hydrothermal treatment on the potential bioaccessibility of selected phenolic compounds.

The effects of in vitro digestion, hydrothermal treatment, and food matrices (wheat flour, durum wheat flour, wholemeal wheat flour, corn flour, rice flour) on the bioaccessibility of phenolic compounds (gallic acid, p-coumaric acid, ferulic acid, chlorogenic acid, catechin) were investigated. The influence of experimental factors and their combinations was estimated based on the "Dose Correction Index" (DCI) concept. Generally, the applied conditions had a negative effect on the bioaccessibility of polyphenols; however, the effect depended on the type of compound and food matrix, which was reflected in different DCI values. A less unfavorable effect on the bioaccessibility was exerted by the rice flour (the lowest DCI values), but the most negative impact was found in the case of the wholemeal wheat flour. The DCI concept provides basic knowledge of the magnitude of factors affecting the bioaccessibility of polyphenols, which can be useful for designing fortified products with desirable bioactivity.

Validating 3D indexes in the non-surgical pectus excavatum patient.

BACKGROUND/PURPOSE: In recent years there has been an increased interest in three-dimensional (3D) imaging for the assessment of chest wall deformities. Some studies have proven a correlation between 3D and traditional cross-sectional images but only for patients who already had an indication for a computed tomography (CT) scan prior to surgery; mainly due to their severity. Our aim is to determine the accuracy and reliability of the measures obtained by a portable 3D scanner in a cohort of pectus excavatum (PE) patients with different severity grades, as well as in controls. METHODS: We conducted a study comparing radiological and optical indexes on magnetic resonance imaging (MRI) and 3D surface images. We used a hand-held 3D scanner to obtain the optical Haller Index (3DHI) and Correction Index (3DCI) and a limited MRI scan to obtain the traditional indexes. A statistical analysis was carried out to determine the correlation between optical and radiological measures, plus a subjective severity evaluation. RESULTS: Twenty-eight patients and controls were enrolled in the study. In both the control and PE groups, there was a significant positive correlation between the indexes, especially for the CI. There were no differences in correlation regarding gender, age or severity. CI appears to better discriminate amongst the different severity groups and controls. CONCLUSION: 3D surface imaging is feasible and appropriate to use to assess PE, regardless of the severity or characteristics of the individual patient. Even with a small hand-held device, we can obtain accurate images and measures which are especially useful for the assessment of the nonsurgical pectus patient.

External caliper-based measurements of the modified percent depth as an alternative to cross-sectional imaging for assessing the severity of pectus excavatum.

BACKGROUND: Cross-sectional imaging (CSI) may be clinically unnecessary in the evaluation of pectus excavatum (PE). The purpose of our study was to prospectively evaluate the accuracy and reliability of the modified percent depth (MPD), derived from caliper-based external measurements, in identifying PE. METHODS: Children 11-21 years old presenting for evaluation of PE or to obtain thoracic cross-sectional imaging for other indications were measured to derive the Modified Percent Depth. The Haller Index (HI) and Correction Index (CI) were calculated from CSI. Receiver-Operator Characteristic (ROC) analysis was used to compare the sensitivity and specificity of MPD, HI, and CI. Interrater reliability was assessed using Spearman's correlation coefficient and Cohen's Kappa coefficient. RESULTS: Of 199 patients, 76 (38%) had severe PE. Median age was 16 years (range = 11-21). The median Modified Percent Depth was 21.4% (IQR = 16.2-26.3) among those with PE versus 4.1% (IQR = 1.7-6.4) in those without (p < 0.001). MPD ≥ 11% exhibited similar sensitivity and specificity to HI ≥ 3.25 and CI ≥ 10 for identifying PE (ROC 0.98 vs. 0.97 vs. 0.98, respectively, p = 0.41). With respect to interrater reliability, independent clinicians' caliper measurements exhibited 87% agreement when identifying MPD ≥ 11% (p < 0.001) with excellent correlation (Spearman's ρ > 0.71, p < 0.001). CONCLUSION: Caliper-based, physical examination measurements of the Modified Percent Depth reliably identify pectus excavatum and represent an alternative to CSI-based measurements for the assessment of PE. TYPE OF STUDY: Diagnostic test. LEVEL OF EVIDENCE: Level II.

Measuring the impact of surgical intervention on pediatric pectus excavatum using white light scanning.

BACKGROUND: Objective preoperative assessment of pectus excavatum (PE) deformity in patients is limited to preoperative measurement of severity using computed tomography (CT) or magnetic resonance imaging (MRI). Postoperative assessment is currently subjective as postoperative CT scans are not recommended in light of radiation exposure and high cost to families. White Light Scanning (WLS) is a novel 3D imaging modality that offers an alternative that is a quick, nonionizing, inexpensive, and safe strategy for measurement both pre- and postsurgery. Our prior investigation demonstrated the feasibility of using WLS to measure PE deformity and showed very strong correlation of a new WLS-derived PE severity index, the Hebal-Malas Index (HMI), with CT-derived HI. The purpose of this study was to demonstrate use of WLS to assess extent of correction of PE deformities after the Nuss procedure. METHODS: WLS scan data were gathered prospectively in pediatric patients with PE from 2015 to 2018. HMI was obtained from the preoperative and postoperative WLS scans. Analysis assessed the differences of preoperative and postoperative HMI. Preoperative CT-derived HI was collected from the medical record and estimated postoperative Haller Index was calculated from HMI and correlation of HMI and HI using historical data. RESULTS: A total of 71 patients received a preoperative CT scan and underwent surgery for PE. Of those, 63 (89%) received WLS preoperatively and 51 (72%) had complete preoperative and postoperative WLS data. The average postoperative decrease in the WLS-derived HMI was 0.35 (SD: 0.15) and 1.73 (SD: 1.03) in WLS-estimated HI. CONCLUSIONS: WLS is highly effective in objectively quantifying the extent of surgical correction in PE patients. LEVEL OF EVIDENCE: IV TYPE OF STUDY: Diagnostic Study.

[Reliability of the correction index in the surgical indication for pectus excavatum]. / Valor del índice de corrección en la indicación quirúrgica del pectus excavatum: correlación con el gold-standard.

OBJECTIVE: The Haller index (HI) is widely used to indicate surgical intervention in patients with pectus excavatum (PE). However, in patients with an atypical thoracic morphology, the severity of the defect can be incorrectly estimated. We propose comparing this index with the correction index (CI). MATERIAL AND METHODS: We analyzed clinical data and CT scans of 50 patients who consulted for PE in our center between 2010 and 2017. Haller index (HI), Correction index (CI) and ideal thoracic index (ITI) were calculated for each patient. The ITI allowed dividing the sample into two groups based on the thoracic morphology by excluding the PE component, therefore separating those with thorax too wide or too narrow from the standard patients. A standard group (36 patients) and a non-standard group (14 patients) were generated, among which the HI and the CI were correlated. RESULTS: The mean HI and CI of all patients were 3.99 and 27%, respectively. 31 of the 50 patients (62%) underwent intervention, 8 of them with an HI below 3.25. When comparing both groups, there was a moderate correlation between HI and CI in the standard group (Spearman r 0.799, p <0.01) and a greater correlation in the non-standard group (Spearman r 0.858, p <0.01).ween the scale and the presence of foreign body, except for SCORE 1, which was 57% what we attribute to an information bias. If the foreign body were not nuts, inorganic or bone, its aspiration was very unlikely, that is why we included it in the SCORE with -1. CONCLUSION: In our cohort, correlation of HI and CI was not different between both groups of patients. The CI did not prove its superiority when compared to HI in the surgical indication of patients with PE.

OBJETIVO: El índice de Haller (IH) se utiliza ampliamente para indicar la intervención quirúrgica en pacientes con pectus excavatum (PE). Sin embargo, en pacientes con una morfología torácica atípica, puede estimarse erróneamente la severidad del defecto. Planteamos comparar este índice con el índice de corrección (IC). MATERIAL Y METODOS: Analizamos datos clínicos y TC torácicos de 50 pacientes que consultan por PE en nuestro centro entre 2010 y 2017. Para cada paciente, se recalcula el índice de Haller (IH), el índice de corrección (IC) y el índice torácico ideal (ITI). El ITI permite formar dos grupos en base a la morfología torácica excluyendo el componente del PE, separando aquellos con tórax demasiado anchos o estrechos, de los pacientes estándar. Se genera un grupo estándar (36 pacientes) y un grupo no-estándar (14 pacientes), entre los que se correlacionan el IH y el IC. RESULTADOS: El IH y el IC medio de todos los pacientes fue de 3,99 y 27%, respectivamente. Se intervinieron 31 de los 50 pacientes (62%), 8 de ellos con un IH inferior a 3,25. Al comparar ambos grupos, existe una correlación moderada entre IH e IC en el grupo estándar (r Spearman 0,789; p<0,01) y una correlación mayor en el grupo no-estándar (r Spearman 0,858; p<0,01). CONCLUSION: En nuestra cohorte, no se ha probado que la correlación del IH y el IC sea diferente entre ambos grupos de pacientes. El IC no ha demostrado tener mayor validez que el IH en la indicación quirúrgica del PE.

Prediction of Scoliosis Curve Correction Using Pedicle Screw Constructs in AIS: A Comparison of Fulcrum Bend Radiographs and Traction Radiographs Under General Anesthesia.

STUDY DESIGN: Retrospective radiographic review. OBJECTIVES: Our objectives were to (1) compare the ability of fulcrum bend radiographs and traction radiographs under general anesthesia to predict correction of adolescent idiopathic scoliosis (AIS) using pedicle screw only constructs and (2) compare the fulcrum bend correction index (FBCI) with a new measurement: the traction correction index (TCI). METHODS: This is a retrospective radiographic review of 80 AIS patients (62 female and 18 male), who underwent scoliosis correction with pedicle screw only constructs. The mean age at surgery was 14 years (range 9-20 years). Radiographic analysis was carried out on the preoperative and immediate postoperative posteroanterior standing radiographs and the preoperative fulcrum bend radiographs and traction radiographs under general anesthesia. FBCI is calculated by dividing the correction rate by the fulcrum flexibility and TCI is calculated by dividing the correction rate by the traction flexibility. RESULTS: Preoperative mean Cobb angle of 63.9° was corrected to 25.8° postoperatively. The mean fulcrum bending Cobb angle was 37.6° and traction Cobb angle was 26.6°. The mean fulcrum flexibility was 41.1%, traction flexibility 58.4%, and correction rate 59.6%. The median FBCI was 137% and TCI was 104.3%. CONCLUSIONS: When comparing fulcrum bend and traction radiographs, we found the traction radiographs to be more predictive of curve correction in AIS using pedicle screw constructs. TCI takes into account the curve flexibility better than FBCI.

AstigMATIC: an automatic tool for standard astigmatism vector analysis.

BACKGROUND: Standardization for reporting medical outcomes facilitates clinical study comparisons and has a fundamental role on research reproducibility. In this context, we present AstigMATIC, a free standalone application for automated standardized astigmatism vector analyses in corneal and intraocular refractive surgeries. AstigMATIC uses a simple graphical user interface (GUI) and allows the simultaneous display and analysis of astigmatism magnitude and axis. RESULTS: The software produces the four following standard graphs according to the standards of the Alpins Method; 1-Target-Induced Astigmatism Vector, 2- Surgically-Induced Astigmatism Vector, 3-Difference Vector and 4-Correction Index. Vector means with X and Y standard deviations are automatically calculated and displayed on the corresponding single-angle vector plots (0 to 180°). Data points are entered into a simplified GUI with no need for command line input. The standard graphs can be easily exported as high-resolution TIFF images for figures to use in production and presentations. CONCLUSIONS: AstigMATIC enables the user to easily and efficiently analyze vectorial astigmatism outcomes using the standardized Alpins Method for post-surgical astigmatism.

Quantification of pectus excavatum: Anatomic indices.

Pectus excavatum is the most common chest wall deformity in children. The central portion of the chest is displaced posteriorly relative to the remainder of the anterior chest wall. Quantification of defect severity can be performed with multiple imaging modalities or external thoracic measures, but is most commonly quantified by the Haller Index (HI) or Pectus Correction Index (PCI). These two measures provide a measure of the chest based on cross sectional imaging, most commonly CT scans, allowing for standard comparison and definitions of pectus defects. The purpose of this article is to describe the creation, calculation, and limitations of the methods quantifying pectus defects.

Fulcrum flexibility of the main curve predicts postoperative shoulder imbalance in selective thoracic fusion of adolescent idiopathic scoliosis.

PURPOSE: To identify preoperative predictors for postoperative shoulder imbalance (PSI) after corrective surgery of adolescent idiopathic scoliosis (AIS) and using the fulcrum-bending radiograph to assess flexibility. METHODS: A consecutive surgical cohort of AIS patients undergoing selective thoracic fusion with alternate-level pedicle screw fixation was prospectively studied. Preoperative anteroposterior, lateral and fulcrum-bending radiographs were analysed. Postoperatively, a minimum of 2 years clinical and imaging follow-up was performed of all patients. PSI was defined as a radiographic shoulder height difference of more than 20 mm. RESULTS: A total of 80 patients were included, and 14 patients (18%) were confirmed with PSI at final follow-up. The flexibility of MT curve was an independent risk factor for PSI (odds ratio (OR) = 3.3 per 10% decrease, 95% confidence interval (CI) 1.6-8.2). Twenty-seven patients had a preoperative MT flexibility of < 55% (OR = 11.5, 95% CI 2.8-46.2). Postoperative T1 tilt was significantly higher in the PSI group (p < 0.001), and a T1 tilt of more than 9° resulted in 7.2 times higher odds of developing PSI (95% CI 2.0-26.0). Fulcrum-bending correction index (FBCI) was significantly higher in the PSI group at final follow-up, and 25 patients had a final postoperative MT FBCI above 120% (OR = 8.5 (95% CI 2.3-31.0). CONCLUSIONS: A low preoperative curve flexibility is a significant predictor for PSI. The surgical strategy should consider proximal fusion in presence of low-flexibility MT curves and consider less aggressive MT curve correction. Achieving a level T1 should be a main priority during intraoperative correction and may require fusion of the PT curve. LEVEL OF EVIDENCE: III. These slides can be retrieved under Electronic Supplementary Material.

Assessment of potential confounders when imaging pectus excavatum with chest radiography alone.

BACKGROUND: Chest radiography (CXR) has emerged as an attractive alternative imaging option for objective pre-operative assessment of pectus excavatum (PE) with comparable accuracy, reduced cost, and less radiation exposure when compared to computed tomography (CT). This study asked whether image quality, scoliosis, and asymmetry of the PE deformity would decrease the accuracy of CXR as compared to CT. METHODS: A database of PE patients receiving preoperative CXR and CT was created, and Haller-indices (HI) and correction-indices (CI) were calculated using each imaging modality. Each potential confounding variable were analyzed using Spearman correlations the Fisher r-to-z transformation test. RESULTS: The database was comprised of 77 patients. Image quality, scoliosis and the 'eccentric type' of asymmetry did not demonstrate any significant worsening of measurement accuracy. However, the correlation coefficients for CIs for those with and without the 'unbalanced type' of asymmetry were 0.593 and 0.890, respectively, with a Fisher r-to-z of 2.16 (p=.031). CONCLUSIONS: The accuracy of CXR-derived pectus indices remains quite favorable despite the heterogeneity from radiographic quality, scoliosis and chest wall asymmetry. Nonetheless, the unbalanced type of chest wall asymmetry did emerge as a significant confounder. As such, use of CXR alone in cases of gross chest wall asymmetry should be cautioned.

The case for using the correction index obtained from chest radiography for evaluation of pectus excavatum.

BACKGROUND: We previously reported the use of a computed tomography (CT)-based Correction Index (CI) as a more accurate assessment of pectus excavatum (PE) severity than the historically used Haller Index (HI). This study examines the diagnostic capabilities of the CI as assessed by lateral chest radiography (CXR). METHODS: A database of PE patients receiving preoperative CXR and CT was created. For each patient, a radiologist calculated a CT-based CI, while two pediatric surgeons independently calculated CXR CIs. RESULTS: The database was composed of 69 patients. Significant correlations were found between CXR CI estimates of the two observers and between the CXR and CT CI for each observer. Per our previous work, CT CIs were used in this study for identifying patients meeting surgical criteria (CT CI≥28%). Observed CXR CIs demonstrated good interrater reliability. The sensitivity (0.83) and specificity (0.77) of CXR in diagnosing severe PE (CT CI≥28%) was high. However, sensitivity (0.89) markedly improved when only considering measured CXR CIs≤26%, and combined specificity rose to 0.86 when only considering measured CXR CIs≥30%. CONCLUSIONS: We recommend the CI as measured by lateral CXR for the preoperative evaluation of PE, with CT used as a confirmatory test in patients measured to have a CXR CI between 26% and 30%.

The Depression Index: an objective measure of the severity of pectus excavatum based on vertebral diameter, a morphometric correlate to patient size.

BACKGROUND/PURPOSE: In patients with Pectus Excavatum (PEX), the proposed Depression Index (DI) is derived from the absolute measurement of sternal depression using the transverse vertebral body diameter as a surrogate for height. The previously described objective and useful Pectus Index (PI) and Correction Index (CI), utilize thoracic diameters and do not always reflect the severity of the deformity as observed by clinicians. METHODS: Data for age, weight, height and vertebral diameter of T9, 10 and 11 were collected on 60 patients, with normal skeletons, undergoing CT scanning. The DI, PI and CI were calculated from CT scans on 76 patients with PEX. Indices were also compared to subjective rankings of the deformity from visual inspection of photographs by 5 clinicians. RESULTS: All parameters of age, weight and height correlated with the vertebral diameter. The DI correlated with the severity of the PEX deformity as also measured by the PI and the CI. There was a better correlation of the observed deformity severity to the DI than the PI or CI. CONCLUSION: There is a strong correlation between transverse vertebral size and patient height. The DI is an objective measurement of the severity of a PEX deformity that is independent of the thoracic diameters.