Reactive pectus carinatum in patients treated for pectus excavatum

Purpose

The Ravitch and minimally invasive Nuss procedures have brought widespread relief to children with pectus excavatum, chest wall deformities, over the last half century. Generally accepted long-term complications of pectus excavatum repair are typically limited to recurrence of the excavatum deformity or persistent pain. This study examines the authors' experience with patients who develop a subsequent carinatum deformity within 1 year of pectus excavatum repair.

Methods

The authors retrospectively assessed the charts of all patients diagnosed as having a carinatum deformity subsequent to treatment for pectus excavatum at a tertiary urban hospital. We noted age at original correction of pectus excavatum, time from original correction to diagnosis of carinatum deformity, age at correction of carinatum deformity, complaints before correction, methods of repair, postoperative complications, and we reviewed relevant radiography.

Results

Three patients who underwent pectus excavatum repair between January 2000 and August 2007 developed a subsequent carinatum deformity. Two patients initially underwent minimally invasive Nuss correction of pectus excavatum; 1 patient underwent the Ravitch procedure. Within 1 year of original correction and despite intraoperative achievement of neutral sternal position, a protruding anterior chest deformity resembling de novo pectus carinatum emerged in each patient; we term this condition reactive pectus carinatum. The mean age of patients undergoing initial pectus excavatum repair was 13 years (range, 11-16 years). The pathophysiology of this reactive lesion is not well understood but is thought to originate from reactive fibroblastic stimulation as a result of sternal manipulation and bar placement. Patients who underwent Nuss correction initially were managed with early bar removal. Two of the patients eventually required surgical resection of the carinatum deformity at a time interval of 3 to 6 years after initial excavatum repair. In one patient, the carinatum deformity resolved spontaneously. Neutral chest position and absence of dyspenic symptoms were achieved in all patients.

Conclusions

Reactive pectus carinatum is functionally encumbering and a poor cosmetic complication of either the Ravitch or minimally invasive Nuss procedures. Our experience with reactive pectus carinatum introduces the importance of postoperative vigilance even in patients without underlying fibroelastic disease. Examination of the chest with attention to the possibility of an emerging carinatum deformity, particularly in the first 6 postoperative months, is paramount. A telephone call to the patient at 3 months may be a useful adjunct to clinic visits. An optimal long-term result may be achieved through a combination of early Nuss bar removal or postpubertal pectus carinatum repair.     

Three-dimensional computed tomography for evaluation and management of children with complex chest wall anomalies: useful information or just pretty pictures?

Purpose

Shaded surface display (SSD) technology, with 3-dimensional computed tomography reconstruction, has been reported in a few small series of patients with congenital or acquired chest wall deformities. Shaded surface display images are visually attractive and educational, but many institutions are hesitant to use these secondary to cost and image data storage concerns. This study was designed to assess the true value of SSD to the patient, family, and operating surgeon, in the evaluation and management of these children.

Methods

After institutional review board approval, we performed a retrospective review of records of 82 patients with chest wall deformities, evaluated with SSD, from 2002 to 2009. Shaded surface display usefulness, when compared to routine 2-dimensional computed tomography, was graded on a strict numerical scale from 0 (added no value besides education for the patient/family) to 3 (critical for surgical planning and patient management).

Results

There were 56 males and 26 females. Median age was 15.3 years (range, 0.6-41.1 years). Deformities included 56 pectus excavatum, 19 pectus carinatum, and 8 other/mixed deformities. Six patients also had acquired asphyxiating thoracic dystrophy (AATD). Eleven (13%) had previous chest wall reconstructive surgery. In 25 (30%) patients, SSD was useful or critical. Findings underappreciated on 2-dimensional images included sternal abnormalities (29), rib abnormalities (28), and heterotopic calcifications (7). Shaded surface display changed or influenced operation choice (4), clarified bone vs soft tissue (3), helped clarify AATD (3), and aided in rib graft evaluation (2). Point biserial correlation coefficient analysis (R_pb) displayed significance for SSD usefulness in patients with previous chest repair surgery (R_pb = 0.48, P ≤ .001), AATD (R_pb = 0.34, P = .001), pectus carinatum (R_pb = 0.27, P = .008), and females (R_pb = 0.19, P = .044).

Conclusions

Shaded surface display, when used to evaluate children and young adults with congenital or acquired chest wall deformities, provides useful or critical information for surgical planning and patient management in almost one third of patients, especially in those requiring a second operation, with acquired asphyxiating thoracic dystrophy, pectus carinatum, and females.     

Management of pectus chest deformities in female patients

Background

There is sparse published information regarding surgical management of females with pectus excavatum (PE) or carinatum (PC) deformities.

Methods

During the past 33 years 104 females with PE, and 21 with PC underwent surgical repair using extensive modifications of the Ravitch technique. Seven had previous right breast implants, 3 had prostheses placed in the PE deformity. Nine PE patients underwent successful pregnancy before repair, but had severe third trimester dyspnea.

Results

Very good to excellent results were reported by 96% (mean follow-up, 6 years). Increased endurance, decreased dyspnea, reduced chest discomfort, and less tachycardia occurred in all within 6 months. No patients had significant breast asymmetry after repair. Complications included mildly hypertrophic scar (8), transient pleural effusion (3), bar displacement (1), and mild recurrence (3).

Conclusions

Females with symptomatic PE or PC, can be repaired with low morbidity, mild pain, low cost, and improvement in body image and symptoms. Prostheses are not beneficial in the treatment of physiologic symptoms caused by pectus deformities.     

Refinements in pectus carinatum correction: the pectoralis muscle split technique

Background

The standard approach for correction of pectus carinatum deformity includes elevation of the pectoralis major and rectus abdominis muscle from the sternum and adjacent ribs. A postoperative restriction of shoulder activity for several weeks is necessary to allow stable healing of the elevated muscles. To reduce postoperative immobilization, we present a modified approach to the parasternal ribs using a pectoralis muscle split technique.

Methods

At each level of rib cartilage resection, the pectoralis muscle is split along the direction of its fibers instead of elevating the entire muscle as performed with the standard technique. From July 2000 to May 2007, we successfully used this technique in 33 patients with pectus carinatum deformity.

Results

After the muscle split approach, patients returned to full unrestricted shoulder activity as early as 3 weeks postoperatively, compared to 6 weeks in patients treated with muscle flap elevation. Postoperative pain was reduced and the patients were discharged earlier from the hospital than following the conventional approach.

Conclusions

The muscle split technique is a modified surgical approach to the parasternal ribs in patients with pectus carinatum deformity. It helps to maintain pectoralis muscle vascularization and function and can reduce postoperative pain, hospitalization, and rehabilitation period.     

The Calgary protocol for bracing of pectus carinatum: a preliminary report

Background

The optimal treatment of pectus carinatum (PC) deformities is unclear. We propose a nonoperative approach using a lightweight, patient-controlled dynamic chest-bracing device.

Material and Methods

With ethical approval, 24 patients with PC were treated at the Alberta Children's Hospital between January 1998 and April 2005. There were 6 (25%) females and 18 (75%) males, with a mean age of 12.9 years at the onset of treatment. Treatment involved fitting of a lightweight, patient-controlled chest brace, worn for 23 hours per day (correction phase [CP]) until the convex deformity was corrected. Following correction of the deformity, bracing was reduced to 8 hours per day (maintenance phase) until axial skeletal maturation ceased. Monitoring was done by measurement of the external pectus carinatum protrusion as well as subjective patient and surgeon appraisal of appearance and exercise tolerance.

Results

Nineteen (79.2%) patients have completed initial treatment (mean CP time, 4.3 ± 2.1 months). There were 3 patients (12.5%) who were noncompliant, and 2 (8.3%) are still in the initial CP phase of therapy. Fourteen (58.3%) patients are presently in maintenance phase, nocturnally braced, and 2 (8.3%) have completed therapy. In patients completing initial treatment, the protrusion pectus carinatum protrusion (pre 22 ± 6 vs post 6.0 ± 6.2) and subjective appearance (change + 1.8±0.4) showed a significant improvement (P < .001 for both) with no change in exercise tolerance.

Conclusion

Compressive bracing results in a significant subjective and objective improvement in PC appearance in skeletally immature patients. However, patient compliance and diligent follow up appear to be paramount for the success of this method of treatment. Further studies are required to show the durability of this method of treatment.     

The etiology of pectus carinatum involves overgrowth of costal cartilage and undergrowth of ribs

Purpose

We compared the length of costal cartilage and rib between patients with symmetric pectus carinatum and controls without anterior chest wall protrusion, using a 3-dimensional (3D) computed tomography (CT) to evaluate whether the overgrowth of costal cartilage exists in patients with pectus carinatum.

Subjects and methods

Twenty-six patients with symmetric pectus carinatum and matched twenty-six controls without chest wall protrusion were enrolled. We measured the full lengths of the 4th–6th ribs and costal cartilages using 3-D volume rendering CT images and the curved multiplanar reformatted (MPR) techniques. The lengths of ribs and costal cartilages, the summation of rib and costal cartilage lengths, and the costal index [length of cartilage/length of rib * 100 (%)] were compared between the patients group and the control group at 4th–6th levels.

Results

The lengths of costal cartilage in patient group were significantly longer than those of control group at 4th, 5th and 6th rib level. The lengths of ribs in patient group were significantly shorter than those of control group at 4th, 5th and 6th rib level. The summations of rib and costal cartilage lengths were not longer in patients group than in control group. The costal indices were significantly larger in patients group than in control groups at 4th, 5th and 6th rib level.

Conclusion

In patients with symmetric pectus carinatum, the lengths of costal cartilage were longer but the lengths of rib were shorter than those of controls. These findings may supports that the overgrowth of costal cartilage was not the only factor responsible for pectus carinatum.     

Force required for correcting the deformity of pectus carinatum and related multivariate analysis

Objective

To measure the force required for correcting pectus carinatum to the desired position and investigate the correlations of the required force with patients’ gender, age, deformity type, severity and body mass index (BMI).

Chest x-ray as a primary modality for preoperative imaging of pectus excavatum

Background

Adolescents with a pectus excavatum mostly present with cosmetic complaints and rarely have significant physical limitations. The preoperative evaluation includes pulmonary functions tests, echocardiography, and chest computed tomography (CT) scan to measure the Haller index. In most patients, the chest CT is performed only to measure the Haller index. The purpose of this study was to evaluate whether indices measured on chest radiograph (CXR) and CT scan are comparable.

Methods

Cases of pectus excavatum treated with the minimally invasive approach in the last year were prospectively collected. In patients for whom a preoperative CXR and CT scan were available, an index was measured using both imaging modalities and compared.

Results

Both preoperative imaging studies were available in 12 patients. The mean Haller indices on CT scan and CXR were 3.97 and 4.08, respectively. The Pearson correlation score between the 2 groups was 0.984.

Conclusions

We propose that the Haller index measured on CT scan be replaced by CXR measurement in asymptomatic patients in whom a chest CT scan is otherwise not necessary. This will limit radiation exposure to children. When in doubt, a CT scan of the chest can be used for the preoperative evaluation.     

X-ray-free protocol for pectus deformities based on magnetic resonance imaging and a low-cost portable three-dimensional scanning device: a preliminary study

 Open in a separate windowOBJECTIVESTo compare a standard protocol using chest computed tomography (CT) to a non-irradiant protocol involving a low-cost portable 3D scanner and magnetic resonance imaging (MRI) for all pectus deformities based on the Haller index (HI).METHODSFrom April 2019 to March 2020, all children treated for pectus excavatum or carinatum at our institution were evaluated by chest CT, 3D scanning (iPad with Structure Sensor and Captevia—Rodin4D) and MRI. The main objectives were to compare the HI determined by CT or MRI to a derived index evaluated with 3D scanning, the external Haller index (EHI). The secondary objectives were to assess the inter-rater variability and the concordance between CT and MRI for the HI and the correction index.RESULTSEleven patients were evaluated. We identified a strong correlation between the HI with MRI and the EHI (Pearson correlation coefficient = 0.900; P < 0.001), with a strong concordance between a radiologist and a non-radiologist using intra-class correlation for the HI with MRI (intra-class correlation coefficient = 0.995; [0.983; 0.999]) and the EHI (intra-class correlation coefficient = 0.978; [0.823; 0.995]). We also identified a marked correlation between the HI with CT and the EHI (Pearson coefficient = 0.855; P = 0.002), with a strong inter-rater concordance (intra-class correlation coefficient = 0.975; [0.901; 0.993]), a reliable concordance between CT and MRI for the HI and the correction index (Pearson coefficient = 0.886; P = 0.033).CONCLUSIONSNon-irradiant pectus deformity assessment is possible in clinical practice, replacing CT with MRI and 3D scanning as a possible readily-accessible monitoring tool.     

Scoliosis in children with pectus excavatum and pectus carinatum

Between 1974 and 1985, 461 patients with pectus excavatum and 135 patients with pectus carinatum underwent operative repair of their anterior chest wall deformities. Twenty-one percent of patients with anterior chest wall deformity had mild scoliosis by clinical and radiographic examination. The average lateral spinal deformity was 15 degrees (range 6-78 degrees) for pectus excavatum patients and 16 degrees (range 5-57 degrees) for pectus carinatum patients. Eighteen percent of the pectus excavatum patients with scoliosis and 14% of the pectus carinatum patients with scoliosis required therapeutic intervention of bracing and/or arthrodesis.     

Changes in chest compression indexes with breathing underestimate surgical candidacy in patients with pectus excavatum: A computed tomography pilot study

Background

Haller Index (HI) ≥ 3.25 by computed tomography (CT) at end-inspiration has been used to indicate surgical correction in patients with pectus excavatum. However, chest wall diameters vary with breathing and may modify HI values and surgical indications. The aim of our study was to report the changes in HI with breathing and their impact in the surgical indication rates.

Methods

Thirty six patients with pectus excavatum underwent chest CT evaluation at both end-inspiration and end-expiration. HI was derived by dividing the transverse diameter (TD) of the chest by the anteroposterior diameter (APD). Cardiac compression index (CCI) was then calculated by dividing the cardiac TD by the APD.

Results

Mean patient age was 19 ± 7 years old and 86.8% were males. From end-inspiration to end-expiration, large changes in APD values corresponded to large changes (29.6%) in HI values. CCI increased significantly during end-expiration, primarily driven by an increase on the cardiac TD. Surgical indication was found in 71% and 91% of patients during end-inspiration and end-expiration, respectively (p < 0.05).

Conclusions

This study showed that the severity indexes of the pectus excavatum were all significantly more severe at end-expiration than at end-inspiration, leading to an increase in surgical candidacy. We therefore recommend performing the CT at end-expiration.     

Etiology of chest wall deformities—a genetic review for the treating physician

Chest wall deformities such as pectus excavatum, pectus carinatum, and cleft sternum can be isolated malformations or dysmorphic features of genetic associations, monogenic disorders, and various numeric and structural chromosomal aberrations. In contrast to the most important syndromes such as Marfan syndrome or Noonan syndrome that can be associated with a chest wall deformity and for which the causative genes are known, etiology of isolated chest wall deformities is still a matter of research. Therefore, an interdisciplinary approach, particularly in patients with additional symptoms is strongly recommended to choose the best therapeutic approach for each patient and its family.     

Compressive orthotic bracing in the treatment of pectus carinatum: the use of radiographic markers to predict success

Purpose

The treatment of pectus carinatum (PC) has classically been operative, though compressive orthotic braces have been used with good success in recent years. The purpose of this article is to evaluate the use of radiologic measurements in a successful bracing protocol.

Methods

Sixty-three patients with PC have been evaluated for an 8-year span. The average age is 13.3 ± 2.5. Follow-up is from 4 to 60 months, with a median of 24 months. Seventeen patients with mild defects elected observation alone. The remaining 46 patients began the bracing protocol. Baseline chest computed tomography (CT) was obtained, and custom-fitted orthotic braces were constructed for each patient. Radiographic markers were evaluated to include the Haller index, angle of sternal rotation, and asymmetry index. Patient surveys and chart review were used to identify compliance and success rates. Pretreatment CTs were retrospectively reviewed by bracing outcomes and radiographic measurements were compared. Ten patients received posttreatment CTs after successful bracing.

Results

Of 63 patients with PC, 17 patients (27%) with mild defects elected observation alone. The remaining 46 patients began the bracing protocol as described above. Of these, 10 are excluded from analysis, with 6 patients currently in the early treatment phase and 4 who have been lost to follow-up. Of the remaining 36 patients, 8 failed bracing because of noncompliance. Of the 28, 24 patients who completed treatment report either good or excellent results after bracing. Eight patients have required surgical intervention, 4 as a result of noncompliance and 4 who were compliant but failed bracing.In patients who were compliant, significant differences were seen on initial CT between those with successful outcomes and those who required surgical repair. Haller index (2.85 vs 2.05; P < .05), angle of sternal rotation (27.3 vs 14.8; P < .05), and asymmetry index (1.23 vs 1.06; P < .01) were all higher in the group who failed bracing. In those who successfully completed treatment, there was no significant difference in the Haller or asymmetry indices, but the average improvement in sternal rotation was 53.8%.

Conclusion

Compressive orthotic bracing is a successful method of treatment of pectus carinatum. The associated sternal rotation can be significantly improved with appropriate bracing that results in a subjective improvement in the deformity. Asymmetry of chest diameter related to concomitant excavatum-type deformity is less likely to respond to bracing attempts. In this way, initial chest CT can be of value in treatment planning.     

Evaluation of the Nuss procedure using pre- and postoperative computed tomographic index

Background

Objective assessment of the chest in patients with pectus excavatum after the Nuss procedure has not been published. This study evaluated the results of the Nuss procedure using computed tomographic (CT) index (CTi).

Methods

We have performed the Nuss procedure in 382 patients since 1998, and 150 patients who underwent bar removal were included in this study. Computed tomographic scans were obtained before the Nuss procedure and after bar removal, and then preoperative CTi (pre-CTi) and postoperative CTi (post-CTi) were calculated. Computed tomographic scans of 62 age-matched patients without chest deformity were collected as controls. Patients were divided at 10 years of age into the younger and older groups, and groups with mild and severe deformity were defined using a pre-CTi value of 5 as border. These CT indices were compared and statistically analyzed.

Results

Mean pre-CTi in all cases was 5.97 ± 3.31 and improved to 3.08 ± 0.64. Postoperative CTi was not significantly different from that of the control (2.47 ± 0.32, P = .17). In the group with mild depression, pre-CTi was 4.15 ± 0.62, and post-CTi was 2.88 ± 0.50. Preoperative CTi in the group with severe deformity (7.44 ± 3.82) improved to 3.25 ± 0.69. Postoperative CTi values between the severe and mild groups were not significantly different (P = .75). Computed tomographic index of the young group improved from 6.20 ± 3.58 to 2.93 ± 0.49 and in older group from 5.50 ± 2.64 to 3.40 ± 0.79. These 2 post-CTi values were not significantly different (P = .73).

Conclusion

Postoperative CT scan could provide objective evaluation of sternal elevation. Mean CTi after the Nuss procedure was statically equivalent to that of the control cohort. Good sternal elevation can be achieved with the Nuss procedure regardless of the severity of chest depression or age.     

Surgical treatment of pectus excavatum: 30 years 398 patients of experiences

Purpose

The aim of the study is to review the surgical experiences with pectus excavatum (PE) chest deformities at the Department of Pediatric Surgery, West China Hospital of Sichuan University (Sichuan, PR China), during a 30-year period.

Method

Records of 398 PE patients (396 congenital, 2 acquired) who underwent surgical repair between 1975 and 2005 were reviewed. Modified sternal elevation was applied in all patients. Repair was performed with subperiosteal resection of the abnormal cartilages, transverse wedge osteotomy of the anterior sternum, and internal support with a metal strut for 1 year. Five technical details were strictly followed for each case. Three hundred twelve patients (78.39%) were followed up from 1 to 16 years.

Result

There were no deaths. Normal contour of the costal cage was constructed postoperatively in 98.74% (393/398) of the patients. Exercise tolerance was improved, and cardiac function recovered to the healthy level of same age. But pulmonary function recovered slowly after surgery.

Conclusions

The 5 technical details are key principles for sternal elevation. Normal appearance of chest wall can be recovered; normal cardiopulmonary function can be restored by the modified sternal elevation with excellent long-term physiologic, cosmetic results and low rate of complications.     

Thoracoscopic cartilage resection with partial perichondrium preservation in unilateral pectus carinatum: preliminary results

Background/Purpose

Although minimally invasive repair of pectus excavatum has gained worldwide acceptance, treatment of pectus carinatum is mostly performed with open procedures. Different minimally invasive alternatives have been proposed in the last few years, including subpectoral CO₂ dissection and intrathoracic compression (Abramson technique), or conservative procedures, as dynamic compression system. Recently, another surgical technique has been proposed for the treatment of unilateral pectus carinatum, consisting of a thoracoscopic approach and multiple cartilage incisions. The aim of this work is to present our modification to this approach.

Methods

We have modified this technique by introducing complete cartilage resection of all anomalous costal cartilages, performed thoracoscopically. Three thoracoscopic ports were used. Cartilage is removed progressively using a rongeur and preserving the anterior perichondrium.

Results

We have performed this technique in 4 patients during the last year. Follow-up ranged from 6 to 14 months. No intraoperative or postoperative complications were observed. The results, assessed by the patients themselves, were good in 2 cases, quite good in one, and fair in the first patient of our series, who was reoperated using a classical open approach. Pain was well controlled without the need of an epidural catheter.

Conclusion

Thoracoscopic cartilage resection with perichondrium preservation can be considered as feasible alternative for the treatment of unilateral pectus carinatum.     

A novel measure for pectus excavatum: the correction index

Objective

The Haller Index (HI), the standard metric for the severity of pectus excavatum, is dependent on width and does not assess the depth of the defect. Therefore, we performed a diagnostic analysis to assess the ability of HI to separate patients with pectus excavatum from healthy controls compared to a novel index.

Methods

After institutional review board approval, computed tomography scans were evaluated from patients who have undergone pectus excavatum repair and controls. The correction index (CI) used the minimum distance between posterior sternum and anterior spine and the maximum distance between anterior spine most anterior portion of the chest. The difference between the two is divided by the latter (×100) to give the percentage of chest depth the defect represents.

Results

There were 220 controls and 252 patients with pectus. Mean HI was 2.35, and the mean CI was 0.92 for the controls. The mean HI was 4.06, and the mean CI was 31.75 in the patients with pectus. In the patients with pectus, HI demonstrated a 47.8% overlap with the controls, while there was no overlap for CI.

Conclusions

The Haller index demonstrates 48% overlap between normal patients and those with pectus excavatum. However, the proposed correction index perfectly separates the normal and diseased populations.     

A 5-year experience with a minimally invasive technique for pectus carinatum repair

Purpose

This report describes a 5-year experience with a novel, minimally invasive surgical technique for treatment of pectus carinatum.

Methods

From June 2002 to August 2007, 40 patients underwent operation to correct pectus carinatum by pressure applied through a curved steel bar that was placed subcutaneously anterior to the sternum, via lateral thoracic incisions. The bar is inserted through a polyvinyl chloride tube with the convexity facing posteriorly. The polyvinyl chloride tube is positioned presternally by trocar.Subperiosteal wires attach small fixation plates to the ribs laterally, and the convex bar is secured to the small fixation plates with screws applying manual pressure to the anterior chest wall until the desired configuration is achieved. The compressive elongated bar is attached to the fixation plate with screws. The average age was 14.3 years (range, 10-21 years), and 90% were male. Both symmetric and asymmetric protrusions were treated. Patients whose chest was not malleable, and whose sternum could not be brought to a desirable position with pressure from the operator's hand, were treated by the open or “Ravitch” technique. After 2 or more years, the bar, wires stitches, screws, and fixation plates were removed.

Results

Of 40 patients treated with this procedure, 20 have undergone bar removal with the following results: 10 excellent, 4 good, 4 fair, and 2 poor. Average blood loss was 15 mL. Average length of hospital stay was as follows: implant, 3.8 days; removal, 1.4 days. Patients returned to routine activity 14 days after repair. Average follow-up since primary repair is 2.49 years. In those who have had bar removal, it is 1.53 years. Complications were pneumothorax in 1 patient, treated with chest tub e suction; skin adherence in 8 cases; seroma in 6; wire breakage in 3; persistence of pain in 1; and infection in 1. Technical modifications (selecting younger patients, excluding patients with a stiff thoracic wall, submuscular insertion of the bar, stronger pericostal wire) have been associated with no complications in the last 16 cases.

Conclusions

This experience with a new, minimally invasive technique for the treatment of pectus carinatum shows it to be safe and effective. The correction obtained was highly satisfactory with minimal complications. It should be considered in appropriate cases as an alternative to more invasive techniques.     

Evaluation of the treatment of pectus carinatum with compressive orthotic bracing using three dimensional body scans

Purpose

The purpose of this study is to measure the effectiveness of compressive orthotic brace therapy for the treatment of pectus carinatum using an adjusted Haller Index (HI) measurement calculated from 3D body scan (BS) images.

Methods

Pediatric patients with pectus carinatum were treated with either compressive orthotic bracing or observation. An adjusted BS Haller index (HI) was calculated from serial 3D BS images obtained on all patients. Medical records were evaluated to determine treatment with bracing and brace compliance more than 12 hours daily. Compliant patient measurements were compared to non-compliant and non-brace groups.

Results

Forty patients underwent compressive orthotic bracing, while ten were observed. Twenty-three patients were compliant with bracing, and seventeen patients were non-compliant. Compliant patients exhibited an 8.2% increase, non-compliant patients had a 1.5% increase, and non-brace patients exhibited a 2.5% increase in BS HI. The change in BS HI of compliant patients was significantly different compared to non-brace patients (p = 0.004) and non-compliant patients (p < 0.001).

Conclusions

Three dimensional BS is an effective, radiation free, and objective means to evaluate patients treated with compressive orthotic bracing.     

Further experience with the operative management of asphyxiating thoracic dystrophy after pectus repair

Background/Purpose

Asphyxiating thoracic dystrophy (ATD) can occur years after a Ravitch-type repair of pectus excavatum, resulting in debilitating alteration in pulmonary function (PFT). An operation was devised to attempt repair of this deformity.

Methods

After institutional review board approval, the records of 10 children (ages 9-18 years) with ATD that developed 4 to 12 years postpectus operation who underwent attempted repair of ATD were reviewed. Data obtained before ATD operation and at 6, 12, and 24 months afterward included chest computed tomography, pulmonary functions (PFT), and a quality of life questionnaire. The operation consisted of sternal split with rib graft placement to permanently hold the sternum apart.

Results

All children survived and the bone grafts healed solidly. Computed tomography showed a change from a flat to a round chest contour on cross section, with increased anteroposterior dimension. Two patients had no change in PFT at 24 months whereas the other 8 had 21% to 30% improvement in PFT parameters. All patients reported improved exercise tolerance, and 3 began sports activities who were previously unable to do so. Two patients on oxygen, essentially bedridden, are now active, breathing only room air. Seven of 10 patients continue to have cosmetic concerns.

Conclusions

A small population of patients who had postoperative pectus repair developed severe, debilitating ATD. The repair described improves most patients, some dramatically, but does not significantly improve cosmetic appearance. The operation is undergoing further refinement to address these issues.