Evaluation of Explanted CorMatrix Tyke Extracardiac Patches in Infants With Congenital Heart Disease.

BACKGROUND: Animal data demonstrate that intracardiac patches of decellularized porcine small intestine submucosa (CorMatrix; CorMatrix Cardiovascular, Atlanta, GA) become repopulated with native cells, suggesting the possibility of a substrate for regenerative tissue in humans. Although human studies have not demonstrated this regenerative property with intracardiac patches, it is possible that other environments may better promote native cell repopulation. We report a prospective series of explanted CorMatrix extracardiac patches placed in infants with congenital heart disease. METHODS: CorMatrix Tyke patches were used in pulmonary artery patch closure during the Norwood procedure. The patch material was explanted as part of the hemi-Fontan procedure. Specimens were analyzed with the use of hematoxylin and eosin, Movat pentachrome, and trichrome stains. RESULTS: Of the 11 implantations, 9 specimens were explanted. One patient did not survive to hemi-Fontan procedure. One patient's patch was removed, but not analyzed. Acellular material, chronic inflammation, fibrosis, and foreign body giant cell reaction was seen in all explanted patches. No explanted CorMatrix Tyke material demonstrated evidence of ingrowth of native endothelial tissue at a median of 4.9 months in vivo. CONCLUSIONS: CorMatrix Tyke patch material, placed as a pulmonary artery patch in an extracardiac position, remained pliable and mostly free of calcification. However, these patches did not show evidence of native endothelial tissue at a median of 4.9 months in vivo.

Treatment of congenital epulis (granular cell tumour) with excision and gingivoperiosteoplasty.

Congenital epulis, or granular cell tumour, is a rare, benign intraoral tumour present on the mucosa of the alveolar ridge, with the potential to interfere with respiration and feeding. Treatment involves surgical excision, and recurrences are rare. The management of the alveolar deficiency associated with this tumour has not previously been addressed. In the present report, a patient with a typical epulis, treated surgically with excision and extrapolation of Millard's gingivoperiosteoplasty technique to reconstruct the associated alveolar defect with restoration of alveolar ridge continuity, is presented. The differential diagnosis and complications of this tumour are discussed.

Robot-enhanced fetoscopic surgery.

BACKGROUND: Fetoscopic surgery carries with it less maternal morbidity than open fetal surgery. Robotic surgery facilitates endoscopic surgery through tremor filtration, motion scaling, indexed movement, articulation, and improved ergonomics. The goal of the authors was to explore using a robotic surgery platform in a fetal animal model. METHODS: Using the Zeus Robotic Surgery System (Computer Motion, Santa Barbara, CA), fetoscopic surgery in pregnant sheep was performed using a variety of techniques: uterus exteriorized or totally percutaneous and with liquid or gas insufflation. Using the percutaneous technique and gas insufflation, the authors created and sutured fetal skin and fascial defects. The ewes were recovered and killed 2 weeks postoperatively, and autopsies were performed on them and their fetuses. RESULTS: In the exteriorized uterus model, instrument movement was unpredictable and fluid leaked. In the fluid environment, clouding of the visual field and difficulty in immobilizing the fetus were major difficulties. In the survival model, 4 of the 6 fetuses survived to autopsy at 2 weeks and showed good healing grossly and histologically. CONCLUSIONS: The Zeus Robotic Surgery System can be used for fetoscopic surgery in a sheep model. The percutaneous approach with a nitrous oxide environment is the most effective. Advantages of robotic surgery may be applicable in fetoscopic surgery, but further work in a primate model is required.

Raman spectroscopy for neoplastic tissue differentiation: a pilot study.

BACKGROUND: Several changes occur during the transformation of normal tissue to neoplastic tissue. Such changes in molecular composition can be detected by Raman spectroscopy. Raman spectroscopy is a nondestructive method of measuring these changes, which suggests the possibility of real-time diagnosis during medical procedures. METHODS: This study seeks to evaluate the ability of Raman spectra to distinguish tissues. The Raman signatures of normal kidney, lung, and liver tissue samples from pigs and rats were characterized in vitro. Further, a human neuroblastoma and a hepatoblastoma, obtained at resection were also studied. RESULTS: The Raman spectra of the animal samples of kidney, liver, and lung are distinctly different in the intensity distribution of the Raman peaks. Further, the spectra of a given organ from pigs and rats, although similar, were different enough to distinguish between the 2 animals. In the patient tissues, the Raman spectra of normal liver, viable tumor, and fibrotic hepatoblastoma were very different. Fibrotic tissue showed a greater concentration of carotenoids, whereas viable tissue was rich in proteins and nucleic acids. The normal tissue showed both components. Similar differences were also seen in the neuroblastoma tissue. CONCLUSIONS: The results of this study show the potential use of Raman spectroscopy in clinical diagnosis.