Insights into Neonatal Oral Feeding through the Salivary Transcriptome.

Background. The development of safe and effective oral feeding skills in the newborn is complex and may be associated with significant morbidities. Our understanding of neonatal oral feeding maturation at the molecular level is limited, providing an opportunity to utilize emerging molecular techniques to accurately assess neonatal oral feeding skills.

From prenatal genomic diagnosis to fetal personalized medicine: progress and challenges.

Thus far, the focus of personalized medicine has been the prevention and treatment of conditions that affect adults. Although advances in genetic technology have been applied more frequently to prenatal diagnosis than to fetal treatment, genetic and genomic information is beginning to influence pregnancy management. Recent developments in sequencing the fetal genome combined with progress in understanding fetal physiology using gene expression arrays indicate that we could have the technical capabilities to apply an individualized medicine approach to the fetus.

Fetal cells in the murine maternal lung have well-defined characteristics and are preferentially located in alveolar septum.

The transfer of fetal cells to maternal organs occurs in mouse and human pregnancy. Techniques such as polymerase chain reaction and flow cytometry do not permit study of fetal cell morphology or anatomic location. Using a green fluorescent protein (GFP) transgenic mouse model, our objective was to determine whether GFP+ signal emanates from intact or degraded fetal cells, and whether they have a characteristic appearance and location within maternal lung.

Pregnancy-associated progenitor cells: an under-recognized potential source of stem cells in maternal lung.

Novel therapies are needed for the treatment of acute and chronic lung diseases, many of which are incurable. The use of exogenous stem cells has shown promise in both animal models and clinical trials. However, to date, the stem cell literature has under-recognized naturally acquired pregnancy-associated progenitor cells (PAPCs).

Cell-free fetal nucleic acids in amniotic fluid.

Background: Research into cell-free fetal (cff) nucleic acids has primarily focused on maternal plasma; however, cff DNA and RNA are also detectable in other body fluids such as amniotic fluid (AF). In AF, cff DNA is present in much greater concentrations than in maternal plasma and represents a pure fetal sample uncontaminated by maternal- and trophoblast-derived nucleic acids. The aim of this review was to summarize the current knowledge on cff nucleic acids in AF and to outline future research directions.

Insights into fetal and neonatal development through analysis of cell-free RNA in body fluids.

The use of cell-free nucleic acids in the circulation of pregnant women for noninvasive prenatal diagnosis is arguably one of the hottest current topics in prenatal medicine. Between 1997 and the present era this field has gone from basic research to clinical application for diagnosis of fetal gender and Rhesus D status. Over the next few years it is likely that noninvasive prenatal diagnosis for Down syndrome will also be possible.