The course of the palatine arteries during secondary palate development in the rat

An in vitro mouse model of cleft palate: defining a critical intershelf distance necessary for palatal clefting

It is unclear whether cleft palate formation is attributable to intrinsic biomolecular defects in the embryonic elevating palatal shelves or to an inability of the shelves to overcome a mechanical obstruction (such as the tongue in Pierre Robin sequence) to normal fusion. Regardless of the specific mechanism, presumably embryonic palatal shelves are ultimately unable to bridge a critical distance and remain unapproximated, resulting in a clefting defect at birth. We propose to use a palate organ culture system to determine the critical distance beyond which embryonic palatal shelves fail to fuse (i.e., the minimal critical intershelf distance). In doing so, we hope to establish an in vitro cleft palate model that could then be used to investigate the contributions of various signaling pathways to cleft formation and to study novel in utero treatment strategies. Palatal shelves from CD-1 mouse embryos were microdissected on day 13.5 of gestation (E13.5; term = 19.5 days), before fusion. Using a standardized microscope ocular grid, paired palatal shelves were placed on a filter insert at precisely graded distances ranging from 0 (in contact) to 1.9 mm (0, 0.095, 0.19, 0.26, 0.38, 0.48, 0.57, 0.76, 0.95, and 1.9 mm). A total of 68 paired palatal shelves were placed in serum-free organ culture for 96 hours (n = 68). Sample sizes of 10 were used for each intershelf distance up to and including 0.48 mm (n = 60). For intershelf distances of 0.57 mm and greater, two-paired palatal shelves were cultured (n = 8). All specimens were assessed grossly and histologically for palatal fusion. Palatal fusion occurred in our model only when intershelf distances were 0.38 mm or less. At 0.38 mm, eight of 10 palates appeared grossly adherent, whereas six of 10 demonstrated clear fusion histologically with resolution of the medial epithelial seam and continuity of the palatal mesenchyme. None of the 18 palates fused when placed at intershelf distances of 0.48 mm or greater. Using our selected intershelf distances as a guideline, we have established an approximate minimal critical intershelf distance (0.48 mm) at which we can reliably expect no palatal fusion. Culturing palatal shelves at intershelf distances of 0.48 mm or greater results in nonfusion or clefting in vitro. This model will allow us to study biomolecular characteristics of unfused or cleft palatal shelves in comparison with fused shelves. Furthermore, we plan to study the efficacy of grafting with exogenous embryonic mesenchyme or candidate factors to overcome clefting in vitro as a first step toward future in utero treatment strategies.

Hypervitaminosis A induced teratogenesis

In the past decade, the toxicology of reproduction has become increasingly important. This branch of toxicology focuses on mutagenic and embryotoxic effects. The study of embryotoxicity requires an extensive knowledge of the interaction of drugs and embryonic tissues, normal and abnormal developmental processes, and the susceptible stages during prenatal development. Hypervitaminosis A is one of the most extensively studied teratogens. It produces defects in almost all organ systems. Therefore, this article will first of all review the vitamin A-induced malformations in several organ systems. Moreover, it will discuss their morphogenesis and the susceptible developmental stages. Thus, the first ten chapters will cover the following subjects: malformations of the nervous system, ocular malformations, malformations of the ear, craniofacial malformations, cleft palate, defects of the circulatory system, defects of the respiratory systems, defects of the digestive tract, urogenital defects, skeletal malformations, and abnormal postnatal development. Since in general little is known about the mechanisms involved in the induction of congenital defects, we think it is of great value to review the knowledge and experience that have been gathered by the experimental work with hypervitaminosis A. Therefore, the next chapters will discuss the following subjects: teratogenic effects in different species, minimum effective dose, interaction with other agents, influence of chemical form, solvent, and route of administration, pathophysiology of vitamin A embryotoxicity, and hypervitaminosis A and human pregnancy.

Graphic reconstructions of craniofacial structures during secondary palate development in rats

Lateral and ventral graphic reconstructions of coronally sectioned rat fetuses at four stages of secondary palate development were made to illustrate the size, form, and spatial relations of craniofacial structures at each stage, and to indicate changes between stages. The results illustrated extensive changes in the nasomaxillary and tongue-mandibular complexes and spatial relations in the oronasal cavity during this 2-day period. During closure of the palate the palatine processes and molar dental laminae moved medially, the vertical dimension between the cranial base and Meckel's cartilage increased, and the Meckel's cartilage changed in shape from a "U" to a "V". During the 2-day period extensive increases in anteroposterior and vertical dimensions and limited changes in lateral dimensions resulted in a change in shape of the complete orofacial region. More extensive investigations, preferably quantitative, of the changes shown are indicated to identify the relative contribution of various craniofacial components and to establish the role of differential growth in secondary palate closure.