An Automated Technique for Double Staining Rat and Rabbit Fetal Skeletal Specimens to Differentiate Bone and Cartilage

Assessment of chemicals for their potential to cause developmental toxicity must include evaluation of the development of the fetal skeleton. The method described here is an improved and fully automated double staining method using alizarin red S to stain bone and alcian blue to stain cartilage. The method was developed on the enclosed Shandon PathcentreTM, and the quality of specimens reported here will be reproduced only if carried out on a similar processor under the same environmental conditions. The staining, maceration and clearing process takes approximately 6 days. The personnel time, however, is minimal since solutions are changed automatically and the fetuses are not examined or removed from the processor until the procedure is completed. Upon completion of processing, the bone and cartilage assessment of the specimens can be carried out immediately if required. Full evaluation of skeletal development in both the rat and the rabbit is necessary to meet the requirements of safety assessment studies. This method allows this to be accomplished on a large scale with consistently clear specimens and in a realistic time.     

An automated technique for double staining mouse fetal and neonatal skeletal specimens to differentiate bone and cartilage

Historically, some fetuses for regulatory developmental toxicity studies have been stained with alizarin red S and cleared with glycerol to visualize the ossified portion of their skeletons. Interest in examining cartilage arose owing to its inclusion in some regulatory guidelines. Methods for double staining rat skeletons have been published previously. The method described here for staining mouse skeletons is fully automated and uses alizarin red S to stain bone and Alcian blue to stain cartilage. Pregnant mice (Crl:CD1) were euthanized on gestation day 18 to obtain fetal specimens. Day 0 post-partum mouse pups also were stained. Our method was developed using the Shandon Pathcentre , which is a fully enclosed automated staining system that allows staining to be carried out at 30° C with a final clearing at 35° C. Our method uses the same solutions as for fetal rat processing, but with reduced time periods for the smaller size of mice vs. rat specimens. Staining, maceration and clearing of the specimens requires approximately 2 days. The time required of laboratory personnel, however, is minimal, because all solutions are changed automatically and the specimens do not require examination or removal from the processor until processing is complete. After processing, the specimens are suitable for immediate assessment of bone and cartilage. A mouse developmental toxicity study using 20 animals/group and approximately 10 fetuses/animal could be processed in only three runs using one machine.     

Double Staining of Skeleton Using Microwave Irradiation

The fetal skeleton double staining method is used to reveal developmental abnormalities in the skeletal system. We used alizarin red S and al-cian blue successfully with microwave irradiation for skeletal double staining. The fixation time was reduced from 4-7 days to 2-2.5 min and the staining time was reduced from 4 days to 23 min.     

Atlas of rat fetal skeleton double stained for bone and cartilage

BACKGROUND: The double staining of fetal skeleton for bone and cartilage is a very useful method to evidence skeletal abnormalities in laboratory animals. However, this method has been rarely used in routine developmental toxicity tests. One reason could be the difficulty of comparing the single skeletal pieces and of having reference points. In this paper the fetal rat skeleton double stained with Alizarin red S and Alcyan Blue is described in detail to produce an atlas for developmental toxicity laboratories.     

Teratogenicity of zinc deficiency in the rat: study of the fetal skeleton

Zinc deficiency (ZD) is teratogenic in rats, and fetal skeletal defects are prominent. This study identifies fetal skeletal malformations that affect calcified and non-calcified bone tissue as a result of gestational zinc deficiency in rats, and it assesses the effect of maternal ZD in fetal bone calcification. Pregnant Sprague-Dawley rats (180-250 g) were fed 1) a control diet (76.4 micrograms Zn/g diet) ad libitum (group C), 2) a zinc-deficient diet (0 microgram/g) ad libitum (group ZD), or 3) the control diet pair-fed to the ZD rats (group PF). On day 21 of gestation, laparotomies were performed. Fetuses were weighed, examined for external malformations, and stained in toto with a double-staining technique for the study of skeletal malformations. Maternal and fetal tissues were used for Zn, Mg, Ca, and P determinations. Gross external malformations were present in 97% of the ZD fetuses. No external malformations were found in fetuses from groups C and PF. Ninety-one percent of cleared ZD fetuses had multiple skeletal malformations, whereas only 3% of the fetuses of group PF had skeletal defects; no skeletal malformations were found in fetuses from group C. Some of the skeletal malformations described in the ZD fetuses, mainly affecting non-calcified bone, were not mentioned in previous reports, thus stressing the importance of using double-staining techniques. Examination of stained fetuses and counting of ossification centers revealed important calcification defects in ZD fetuses. These effects were confirmed by lower Ca and P concentrations in fetal bone with alteration of the Ca:P ratio.     

Large-scale double-staining of rat fetal skeletons using Alizarin Red S and alcian blue

A critical component in the conduct of a prenatal developmental toxicity study is the evaluation of fetal skeletal development. As the developing rodent fetus is typically evaluated at gestation day 20, at a time when ossification of the skeleton is incomplete, a thorough assessment of skeletal development would include both ossified and cartilaginous structures. Current methods to double-stain the fetal skeleton using Alizarin Red S and Alcian Blue are typically described for small sample sizes or using time allotments for each processing step that are unsuitable for industry. In an industrial setting, there is a need for an effective means to double-stain fetal skeletons on a large scale (i.e., hundreds of fetuses simultaneously). This article describes a method used in our laboratory to stain both fetal bone and cartilage using solutions and procedures on an industrial scale.     

Differential staining of cartilage and bone in whole mouse fetuses by alcian blue and alizarin red S

The procedure described by Inouye ('76) for the staining of full-term mouse fetal skeletons has been adapted for use with mouse embryos and fetuses of days 14-18 of gestation. The main adaptations for younger specimens involve a longer time in acetone, in lieu of skinning, and omission of the aqueous KOH step. These adaptations require more time but result in consistently good staining of intact specimens.     

Identification of the target cells and sequence of infection during experimental infection of ovine fetuses with Cache Valley virus

Cache Valley virus-induced malformations have been previously reproduced in ovine fetuses; however, no studies have established the course of infection of cells and tissues with Cache Valley virus. To address these questions, ovine fetuses at 35 days of gestation were inoculated in utero with Cache Valley virus and euthanized at 7, 10, 14, 21, and 28 days postinfection. On postmortem examination, arthrogryposis and oligohydramnios were observed in some infected fetuses. Morphological studies showed necrosis in the central nervous system and skeletal muscle of infected fetuses evaluated after 7 to 14 days postinfection, and hydrocephalus, micromyelia, and muscular loss were observed in infected fetuses after 21 to 28 days postinfection. Using immunohistochemistry and in situ hybridization, intense Cache Valley virus antigen and RNA staining was detected in the brain, spinal cord, skeletal muscle, and, to a lesser degree, in fetal membranes and other tissues of infected fetuses. Viral antigen and RNA staining decreased in targeted and infected tissues with the progression of the infection.     

Micro‐CT evaluation of murine fetal skeletal development yields greater morphometric precision over traditional clear‐staining methods

Traditional techniques for quantification of murine fetal skeletal development (gross measurements, clear‐staining) are severely limited by specimen processing, soft tissue presence, diffuse staining, and unclear landmarks between which to make measurements. Nondestructive microcomputed tomography (micro‐CT) imaging is a versatile, well‐documented tool traditionally used to generate high‐resolution 3‐D images and quantify microarchitectural parameters of trabecular bone. Although previously described as a tool for phenotyping fetal murine specimens, micro‐CT has not previously been used to directly measure individual fetal skeletal structures. Imaging murine fetal skeletons using micro‐CT enables the researcher to nondestructively quantify fetal skeletal development parameters including limb length, total bone volume, and average bone mineral density, as well as identify skeletal malformations. Micro‐CT measurement of fetal limb lengths correlates well with traditional clear‐staining methods (83.98% agreement), decreases variability in measurements (average standard errors: 6.28% for micro‐CT and 10.82% for clear‐staining), decreases data acquisition time by eliminating the need for tissue processing, and preserves the intact fixed fetus for further analysis. Use of the rigorous micro‐CT technique to generate 3‐D images for digital measurement enables isolation of skeletal structures based on degree of mineralization (local radiodensity), eliminating the complications of blurred stain boundaries and soft tissue inclusion that accompany clear‐staining and gross measurement techniques. Microcomputed tomography provides a facile, accurate, and nondestructive method for determining the developmental state of the fetal skeleton using not only limb lengths and identification of malformations, but total skeletal bone volume and average skeletal mineral density as well. Birth Defects Res (Part B) 2008. © 2008 Wiley‐Liss, Inc.     

In utero bone marrow transplantation of fetal baboons with mismatched adult baboon marrow.

In utero bone marrow transplantation to fetuses offers the potential advantage of ameliorating the effects of genetic disorders by transplanting allogeneic hematopoietic stem cells into recipients who are immunoincompetent and require no preparative regimen. Therefore, we undertook studies to examine the feasibility of in utero bone marrow transplantation of unrelated allogeneic adult bone marrow into fetal baboons. Thirty-one baboon fetuses were transplanted between the ages of 60 and 160 days gestation (normal gestation, 182 days) with unrelated allogeneic adult bone marrow containing a different isozyme of glucose-phosphate isomerase (GPI). Approximately one third of the 80-day fetuses demonstrated engraftment 1 month after transplantation. Three of three of the initial chimeras died in utero 45 to 80 days after transplantation and the remaining chimeras lost their graft. Furthermore, 80-day fetal baboons were able to recognize donor cells, maternal cells, and other adult baboon peripheral blood cells in a mixed lymphocyte culture (MLC) reaction but still could engraft with allogeneic bone marrow. In contrast all nonchimeric animals survived to term. These data suggest that fetal transplantation of primates is feasible using techniques employed in these studies and that transplantation of younger fetuses who are immunocompetent should be attempted.     

Caffeine and reduction of fetal ossification in the rat: fact or artifact?

This study was done to determine the gestational period during which the rat fetus is susceptible to reduction of skeletal ossification by caffeine. Caffeine, 100 mg/kg/day by gavage, caused the greatest reduction in ossification, as assessed by staining with alizarin red S, in fetuses exposed between day 16 to 19 of gestation, less in those treated between day 7 to 19, and markedly less in those receiving it between day 7 to 16; a single dose on day 19 had very little effect. This indicates that the fetus is most susceptible late in pregnancy. Bones in early stages of mineralization on day 20 showed a greater reduction in staining than those in later stages. Thus, caffeine appears to lower the rate of ossification rather than reduce its final extent. In the day 7 to 19 caffeine treatment group, but not in the day 16 to 19 group, maternal and fetal body weights were reduced, and 1.6% of the fetuses had aphalangia. The day 7 to 16 caffeine treatment reduced fetal body weight. This argues against an association between reduction in fetal weight and ossification. None of the treatments affected rates of resorption or litter size. A novel and important observation made is that the different caffeine treatments affected the staining by alizarin of both claws and bones in a qualitatively and quantitatively similar manner. Since claws are devoid of osteoid, this observation questions the specificity of alizarin for the assessment of the state of fetal ossification and raises doubt as to the significance of the observed action of caffeine on ossification.     

The extent of fetal ossification as an index of delayed development in teratogenic studies on the rat

In teratogenic studies toxic effects may manifest themselves in retarded fetal development, such as a reduction in fetal weight. In searching for an additional index, the number of centers of ossification in seven skeletal districts (sternum, metacarpus, metatarsus, cervical and caudal vertebrae, anterior and posterior proximal phalanges) of rat fetuses delivered on days 19, 20 and 21 of gestation were counted and compared. Results showed uneven ossification in day-19 and -20 fetuses, but sufficiently advanced, homogeneous and uniform ossification in day-21 fetuses to provide a reliable quantitative index for evaluating retarded fetal development. It is therefore proposed that the stage of skeletal ossification in day-21 fetuses be used in teratogenic studies in the rat to evaluate retarded fetal development.     

An Automated Double Staining Procedure for Bone and Cartilage

Differential skeletal staining is an important part of developmental toxicologic studies. Traditionally these studies have required time-consuming differentiation of one or both stains used and careful attention to the maceration step to prevent specimen destruction. We present a fully automated protocol which does not require differentiation of either dye and incorporates a controlled maceration step which is highly reproducible. This has resulted in high quality staining that is reproducible, stable, and can be done in volume with minimal personnel time. The process involves the staining of skinned, eviscerated specimens fixed in 95% ethanol. Using an automated tissue processor, the specimen is stained in alcian blue for 24 hr, macerated in 3% potassium hydroxide for 24 hr and stained with murexide for 24 hr. The specimens are cleared and preserved in glycerol. Within three days specimens have red stained bone and blue stained cartilage. The procedure was developed using 20-day-old Sprague-Dawley rat fetuses to evaluate the feasibility of using the procedure for teratology studies involving the fetal skeleton. Evenly stained specimens can be examined within three days and stored for years without loss of staining.     

Skeletal maturation of the human fetus assessed radiographically on the basis of ossification sequences in the hand and foot

In studies of postnatal human development the skeletal maturation of the hand has been found to be a better indicator of general physical maturation than attained body height. For assessment of prenatal human development the Crown-rump length (CRL) has so far been the most commonly used measure. The object of the present study is to examine the possibility of also using the skeletal maturation of the hand as a maturity indicator in fetal development. The study is based upon a radiographic and histochemical investigation of 169 human fetuses. On the basis of counting silver-impregnated diaphyses on radiographs of the hand and foot a maturity indicator (CNO = Composite Number of Ossified bones in hand and foot) was established. Owing to the marked regularity of the recorded ossification pattern, the CNO parameter can be used for evaluating fetal maturation during the early half of the prenatal period. To supplement the assessment of skeletal maturation during the later stages of development, a classification based on the shape of some bones was included in the study. In many cases fetuses of the same size (CRL) exhibited different stages of skeletal maturation (CNO). In accordance with findings from assessment of postnatal development, a more accurate evaluation of fetal development is obtained by combining the size parameter CRL with an assessment of fetal skeletal maturation, CNO.     

Changes in the fetal tibial growth plate secondary to maternal zinc deficiency in the rat: a histological and histochemical study

Zinc deficiency (ZD) is teratogenic in rats, and fetal skeletal defects are prominent. To elucidate further the effects of maternal ZD in the fetal skeleton, we performed a morphological and histochemical study of tibial growth plate (GP) in ZD rat fetuses. The histochemical study included the identification of calcium, of hydrolytic enzymes associated with the process of calcification, and of oxidative enzymes related to energy production and to the synthesis of proteoglycans. Pregnant Sprague-Dawley rats were fed (1) a control diet (76.4 micrograms Zn/g diet) ad libitum (group C), (2) a zinc-deficient diet (0 micrograms/g) ad libitum (group ZD), or (3) the control diet pair-fed to the ZD rats (group PF). On day 21 of gestation, laparotomies were performed, the fetuses were removed, and fetal tibiae obtained. Specimens were stained with hematoxylin-eosin (H&E) and Masson Trichrome and were processed for identification of alkaline phosphatase, adenosine triphosphatase, succinic dehydrogenase, NADH dehydrogenase, and calcium. The morphologic patterns found in ZD fetal tibiae indicated defects in various cell types implicated in bone metabolism. Staining for hydrolytic enzymes revealed alterations in the size and distribution of matrix vesicles and a weaker staining for ATPase in ZD fetuses. Staining for oxidative enzymes was overall more intense in ZD fetal tibiae. ZD fetuses also presented irregular and defective calcification. These findings indicate that severe maternal ZD in the rat results in structural and functional alterations in the GP of fetal bone, leading to a defective endochondral ossification.     

Micro-computed tomography and alizarin red evaluations of boric acid–induced fetal skeletal changes in Sprague-Dawley rats

BACKGROUND: Assessment of developmental toxicity has historically included assessment of fetal skeletal morphology after alizarin red staining. X-ray micro-computed tomography (micro-CT) produces high-resolution images of skeletal structures and was investigated as an alternative method. METHODS: Groups of 5 mated Crl:CD (SD) female rats each were administered vehicle or boric acid (40 to 500 mg/kg/day) from GD 6 through 11. On GD 21, all live fetuses were weighed, euthanized, and viscera removed. Each litter was placed into a custom-made polystyrene holder and scanned in the micro-CT imaging system. Raw projection data were acquired in approximately 15 sec (∼20 litters per hour) and reconstructed images at 100-micron cubic voxel dimension could be viewed as early as 20 min later. Fetuses were subsequently stained with alizarin red, and findings recorded separately for each method without knowledge of treatment group. RESULTS: Micro-CT evaluation of fetal rat skeletons detected essentially the same skeletal malformations, variations, and incomplete ossifications as seen by the staining method. The specific skeletal abnormalities that did not match exactly involved the smallest skeletal elements with minimal degrees of ossification (i.e., cervical ribs, hypoplastic 13^th ribs, supernumerary ribs, the 5^th sternebra, and numbers of caudal vertebrae), but the differences did not impact the overall conclusions. Additional measures such as femur length were easily measured by micro-CT. CONCLUSIONS: These results indicate that micro-CT imaging can effectively assess rat fetal skeletal structures, and for those laboratories with this resource, it may be used to significantly reduce time prior to skeletal evaluation and hazardous wastes associated with staining. Birth Defects Res (Part B) 33:214–219, 2009 © 2009 Wiley-Liss, Inc.     

Nucleoside phosphatase and nucleotide tetrazolium reductase as markers of arteriolar differentiation in fetal pig tissue

Nucleoside phosphatase and nucleotide tetrazolium reductase reactions were studied as potential markers of arteriolar differentiation. Arteriolar systems were analyzed cytochemically and morphologically in a variety of fetal pig tissues at 70 and 110 days of gestation. In skeletal muscle and subcutaneous adipose tissue there were age dependent changes in phosphatase and reductase reactivity in arteriolar vessels. These changes were temporally associated with the morphological differentiation of the tunica medial arteriolar layer. There were no age dependent changes in the cytochemistry of arterioles in liver and cardiac muscle. In the youngest fetuses, arterioles in liver and cardiac muscle displayed a typical tunica medial layer (normal morphology). The cytochemical reactions (phosphatase, reductase) of arterioles in cardiac muscle and liver from 70 (and 110) days old fetuses were identical to cytochemical reactions of arterioles in muscle and adipose tissue from 110 days old fetuses. In the skin, there were age dependent increases in phosphatase reactive arterioles and capillaries. Capillary staining (phosphatase) and capillary bed size were inversely correlated in the skin. Capillaries in skeletal muscle, cardiac muscle, adipose tissue and liver were not phosphatase reactive. These results indicate that the morphological and cytochemical differentiation of arterioles is dependent on tissue and age in the fetal pig. Furthermore, several histochemical techniques (phosphatase, reductases) are validated as simple means to analyze arteriolar differentiation in general.     

Nucleoside phosphatase and nucleotide tetrazolium reductase as markers of arteriolar differentiation in fetal pig tissue

Summary Nucleoside phosphatase and nucleotide tetrazolium reductase reactions were studied as potential markers of arteriolar differentiation. Arteriolar systems were analyzed cytochemically and morphologically in a variety of fetal pig tissues at 70 and 110 days of gestation. In skeletal muscle and subcutaneous adipose tissue there were age dependent changes in phosphatase and reductase reactivity in arteriolar vessels. These changes were temporally associated with the morphological differentiation of the tunica medial arteriolar layer. There were no age dependent changes in the cytochemistry of arterioles in liver and cardiac muscle. In the youngest fetuses, arterioles in liver and cardiac muscle displayed a typical tunica medial layer (normal morphology). The cytochemical reactions (phosphatase, reductase) of arterioles in cardiac muscle and liver from 70 (and 110) days old fetuses were identical to cytochemical reactions of arterioles in muscle and adipose tissue from 110 days old fetuses. In the skin, there were age dependent increases in phosphatase reactive arterioles and capillaries. Capillary staining (phosphatase) and capillary bed size were inversely correlated in the skin. Capillaries in skeletal muscle, cardiac muscle, adipose tissue and liver were not phosphatase reactive. These results indicate that the morphological and cytochemical differentiation of arterioles is dependent on tissue and age in the fetal pig. Furthermore, several histochemical techniques (phosphatase, reductases) are validated as simple means to analyze arteriolar differentiation in general.     

Bovine viral diarrhea virus: prevention of persistent fetal infection by a combination of two mutations affecting Erns RNase and Npro protease

Different genetically engineered mutants of bovine viral diarrhea virus (BVDV) were analyzed for the ability to establish infection in the fetuses of pregnant heifers. The virus mutants exhibited either a deletion of the overwhelming part of the genomic region coding for the N-terminal protease N(pro), a deletion of codon 349, which abrogates the RNase activity of the structural glycoprotein E(rns), or a combination of both mutations. Two months after infection of pregnant cattle with wild-type virus or either of the single mutants, the majority of the fetuses contained virus or were aborted or found dead in the uterus. In contrast, the double mutant was not recovered from fetal tissues after a similar challenge, and no dead fetuses were found. This result was verified with a nonrelated BVDV containing similar mutations. After intrauterine challenge with wild-type virus, mutated viruses, and cytopathogenic BVDV, all viruses could be detected in fetal tissue after 5, 7, and 14 days. Type 1 interferon (IFN) could be detected in fetal serum after challenge, except with wild-type noncytopathogenic BVDV. On days 7 and 14 after challenge, the largest quantities of IFN in fetal serum were induced by the N(pro) and RNase-negative double mutant virus. The longer duration of fetal infection with the double mutant resulted in abortion. Therefore, for the first time, we have demonstrated the essential role of both N(pro) and E(rns) RNase in blocking interferon induction and establishing persistent infection by a pestivirus in the natural host.     

Frozen-sectioning yields similar results as traditional methods for fetal cephalic examination in the rat

BACKGROUND: An integral component of developmental toxicity studies is the evaluation of fetal anatomy, which consists of external, visceral, and skeletal examinations. The visceral examination includes an assessment of the fetal head which, in the rat, is typically completed after chemical fixation. Because chemical fixation requires approximately 7 days, a comprehensive visceral examination, including the head, of the fetal rodent cannot be completed at the time of cesarean section. An alternative method to chemical fixation was desired, whereby one could complete an overall visceral examination at the time of cesarean section. In addition, the method would also have to present fetal cranial structures in a manner consistent with that derived after chemical fixation. METHODS: Pregnant Sprague-Dawley rats were administered either 6-aminonicotinamide (6AN), 6 or 12 mg/kg on gestation day 13, or all-trans retinoic acid (RA) 5 or 25 mg/kg on gestation days 9 and 10, untreated dams served as a control group. On gestation day 20, fetuses were sacrificed and removed via cesarean section and one-half of the fetuses from each litter were placed in Bouin's solution (chemical fixation) and the remaining fetuses maintained under refrigeration until just before frozen tissue preparation (freeze fixation). Sectioning of the fetal head was similarly conducted after either chemical or frozen-fixation. Fetal cranial findings observed after chemical fixation were compared to those observed after frozen-fixation in the untreated control and 6AN and RA-treated groups. RESULTS: The incidence and severity of the cranial findings, including effects on the eye, brain, and palate, were similarly observed, regardless of fixation method. CONCLUSIONS: A frozen sectioning method for evaluation of the fetal head, yielding results comparable to those derived after chemical fixation, is described. This procedure provides a viable alternative to chemical fixation, and allows the teratologist to complete a comprehensive fetal visceral examination at the time of cesarean section.