There can be little argument that embryo quality is one of the most critical factors in the success of assisted reproductive techniques. Yet the current methods of grading embryos are subjective at best. While a number of different groups have described more qualitative means of assessing embryo quality, the current standard remains morphology. Morphology has proven a good standard, but it does not allow for the detection of chromosomal abnormalities nor can it assess the biochemical status of the embryo prior to transfer. This laboratory recently described a method to estimate embryo weight and suggested weight might be a good indicator of biochemical status. The objective of the present study was to determine the relationship between maternal body composition and embryo weight and determine the influence maternal chemistry had on embryo development. The data continue to suggest that maternal body composition, especially body fat, influences the chemical nature of the embryo and may play a critical role in long-term survival.
It is well documented that most assisted reproductive techniques (ARTs) carry significant risk of multiple gestations [1-3]. A recent report has linked ART and its associated multigestational outcomes not only with increased infant risks, but with significantly increasing the cost of health care [
Currently most programs rely on a combined system of embryo morphology and development rates in culture to predict success in vivo [
Recently, a number of new approaches have been proposed to provide a non-invasive means of evaluating embryo quality. These would include, measure of various metabolites [8-10], glucose utilization [11,12], and a number of proteomic methodologies [
Previous research has suggested that embryo viability might be influenced by the chemical constituents of the embryo [14-16]. Work from this laboratory has suggested that embryo weight is at least in part a function of its chemical composition and that because of the routine shape and size of early stage embryos these differences can be determined using a simple modified specific gravity technique (SGT) [
Using IACUC approved protocols, three separate experiments were conducted to determine the influence of maternal body composition on embryo weight. In the first experiment, embryos were obtained from 6 - 8 weeks old mice from a wild-type CF6F1 mouse (control), a C57BL/6NCrl-Leprdb-lb/Crl mouse or “Pound Micetm” (Charles Rivers; Burlington, MA) or its progenitor the C57BL/6NCrl. The C57BL/6NCrl-Leprdb-lb/Crl, mice that are homozygous for the mutation lack receptors for leptin, and can become severely obese, particularly when fed a specific diet. However, mice with a single copy of the gene remain relatively lean under similar conditions, Therefore there were three embryo groups: the wild-type control, the heterozygous lean C57BL/ 6NCrl (lean), and the obese C57BL/6NCrl-Leprdb-lb/Crl (obese). In the second experiment, embryos were obtained from only the C57BL/6NCrl or C57BL/6NCrlLeprdb-lb/Crl animals. The mice were either lean or obese. In the final experiment, embryos were obtained from the obese mice with average body weights of 30, 40 or 50 g respective.
Prior to collection of embryos, all mice were injected with 5 mIU of pregnant mare serum gonadotropin (Sigma-Aldrich; St. Loius, MO), followed 24 h later by 5 mIU hCG (Merck, Whitehouse Station, NJ) and mating. As these experiments were to examine the maternal contribution to embryo chemical composition, all females were mated to wild-type males. This prevented physical issues with obese types mating and, according to the supplier, represents the first successful in vitro recover of embryos from the obese animals. The animals were weighed and euthanized approximately 24 h after mating in hopes of obtaining 1 or 2 cell embryos. Once euthanized the oviducts were excised and placed in sterile media in 65 mm culture dishes (Falcon; Becton Dickinson; Franklin Lakes, NJ). In the case of the obese animals this was a two-step process. Once the mouse peritoneum was opened, the ovary and uterine horn were identified and all tissue, including significant adipose tissue was removed. Working under a dissecting microscope (Nikon SMZ-2, Nikon Inc; NY), the adipose tissue was teased apart to expose the oviducts which were significantly distorted. The oviducts were then transferred to a second dish to excise the embryos. Once identified embryos were transferred to organ culture dishes with fresh Ham’s F-10 with 10% serum substitute supplement (Irvine Scientific; Santa Ana, CA).
In general specific gravity is a non-specific measurement of density; however, as weight is a function of mass and mass is a function of density, if shape is controlled (such as a shape of an embryo), specific gravity can be used to estimate weight as a function of mass. Therefore, a chamber was constructed that allowed the visualization of embryos and embryo shaped substances of known weight as they “dropped” a known distance. Prior to dropping embryos through the chamber, borosilicate and barium-titanate beads (MO-SCI Specialty Products, L.L.C.; Rolla, MO) of known weight and similar in size and shape to the mice embryos were dropped through the device and their drop time to weight ratios used to establish a standard curve.
In experiment #1 embryos were collected from 11 mice (4 control, 4 lean, and 3 obese-a fourth animal was attempted but had no embryos). The mice were weighted just prior to euthanasia and demonstrated average weights of 17.9, 22.9 and 49.9 g for the control, lean and obese mice respectively. One and two cell embryo weights were then estimated by passing embryos through the specific gravity chamber. In this initial experiment once embryos were weighed they were discarded.
As experiment #1 demonstrated similar estimated weights for the control and lean mice, experiment #2 compared weights for mice of similar genetics (C57BL/ 6NCrl and C57BL/6NCrl-Leprdb-lb/Crl) over time. Embryos were obtained from 7 mice, (3 lean and 4 obese). Once collected the embryos were measured using the SGT to estimate their weight and then returned to culture. The embryos were reweighed and assessed for cell number on days 2, 4 and 6 to determine changes in weigh due to increases in cell numbers.
In the final experiment, embryo weights were estimated in animals of similar genetics across the weight range established in earlier experiments. The C57BL/6NCrlLeprdb-lb/Crl mice were mated as they had average weights of 30, 40 or 50 grams (5 mice per weight group). Day one embryo weights were then estimated using the SGT.
Initial estimated embryo weights were compared to material weights using analysis of variance and Tukey’s mean separation test using the Statistical Package for the Social Sciences (Version 12; Chicago, IL). To remove variability due to operator error of the timer, all data underwent negative logarithmic transformation prior to analysis. Data for continued culture in experiment #2 were compared using a two way analysis of variance by embryo source and time.
One-hundred of each of the various weights of borosilicate and barium-titanate beads where dropped through the system to establish the standard curve. Descent times were amazingly similar between beads of the same weight and size with an overall inner-assay C.V. of 4.1%. As the borosilicate beads were closer in size to the actual mice embryos, their data were then used to calculate the final curve. Using the points established by the beads, the curve was completed by extrapolating points for zero time and zero weight mathematically and resulted in the formula:
where x represented the descent time of the bead/embryo and y the resultant estimated weight. As expected, the relationship between weight (density) and time of descent was not linear but curvilinear on a logarithmic scale (
As designed, there were significant differences in the average weights of the mice due to either strain or feed status (P < 0.001). The control mice in experiment #1 averaged 17.9 g ± 1.2 g STD, significantly lower than the obese mice (49.9 g ± 5.8 g) but similar in weight to the lean animals (22.9 g ± 2.2 g). Visual observation of the peritoneal cavity at the time of embryo retrieval confirmed the increased weight in the obese mice was due to lipid storage in the form of adipose tissue; in many cases requiring the modified technique described in the materials and methods to locate the oviduct. As suggested from a previous study using the SGT and confirmed by transmission electron microscopy in that study [
In experiment #2 it was found that while the embryos of the lean animals continue to grow and develop in a
normal pattern, the embryos of the obese animals demonstrated significant developmental delays if not stalling out completely (
Finally, the relationship between increasing maternal weight due to the addition of adipose tissue verses decreasing estimated embryo weight appears almost linear (
There can be little doubt that the oocyte serves as the major source of cellular components for early stage embryos. Further, it is also well established that changes in cellular chemistry can have significant impact on cellu assume that maternal body composition could have an influence on the membrane and cytoplasmic constituents of the oocyte and embryo and therefore their function.
Previous research has described the influence of growth environment on embryo development. It is well documented that abnormal levels of certain nutrients influence growth patterns [14-16,18,19] and therefore might be an important means of assessing embryo quality in the field of assisted reproductive technologies [8-13].
The present study describes a novel approach to assess membrane constituents, specific gravity. Because oocytes and early stage embryos are generally of a consistent size and shape within any give specie; specific gravity, which is truly a measure of mass, should also provide a reasonable estimation of weight.
Using this estimation, it was possible to demonstrate a relationship between maternal body composition and its influence on the weight of early (one and two cell) embryos. Given previous work from this lab which confirmed that embryos conceived from cattle breeds with high body lipid content had large deposits of free lipid droplets in the embryo cellular cytoplasm [
procedures. This reasoning is supported in part by the poor development seen in the embryos derived from the obese animals.
The new SGT appears to be a potential tool for noninvasive assessment of embryo quality. It is important to note that if the technique is adopted each media used would need to be evaluated and a mathematical equation establish as each of these media has its own specific gravity which will influence the descent time of the embryos being tested. However, if an estimation of weight can be used as a judgment of embryo energy reserves or embryo developmental potential it might allow a more quantitative assessment of embryo quality and increase the chance of success from SET. Alternatively, being able to determine an embryo’s constituent makeup might allow adjustment to cryoprotectants, lessening the stresses being put on embryos during cryopreservation and increasing embryo survival rates.
Studies are currently underway with a redesigned SGT chamber which ensures embryo recovery, to assess influence of the chamber on embryo development and to determine if there is a relationship between the estimated weight of one-cell embryo (most consistent shape) within a single collected pool of embryos and their eventual ability to develop to the blastocyst stage and establish pregnancy.
The authors wish to acknowledge and thank the American Jersey Cattle Association and the Laura Bush Women’s Health Research Institute for grant support of these studies.