A rapid method for preparing high quality alizarin stained skeletons of adult mice

A simple three-day technique is described for preparing completely cleared and high quality alizarin stained total skeletons of adult mice. Unfixed specimens are partially macerated during staining. Older specimens are heated for 15 min in 1% KOH. A heated solution of benzyl and ethyl alcohol, glycerin, and water is used for final clearing and hardening. This procedure requires about 10 min work per specimen and greatly simplifies preparation of stained and cleared skeletons of adult mice. Another technique, giving slightly better preparations, but requiring 11-14 days, is also described.     

A Rapid Method for Preparing High Quality Alizarin Stained Skeletons of Adult Mice

A simple three-day technique is described for preparing completely cleared and high quality alizarin stained total skeletons of adult mice. Unfixed specimens are partially macerated during staining. Older specimens are heated for 15 min in 1% KOH. A heated solution of benzyl and ethyl alcohol, glycerin, and water is used for final clearing and hardening. This procedure requires about 10 min work per specimen and greatly simplifies preparation of stained and cleared skeletons of adult mice. Another technique, giving slightly better preparations, but requiring 11-14 days, is also described.     

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.     

Automated Differential Staining for Cartilage and Bone in Whole Mount Preparations of Vertebrates

An automated, rapid procedure for differential staining of cartilage and bone of vertebrates is described. The process involves rapid, complete staining of freshly skinned, eviscerated specimens after 30 sec immersion in a 70 C water bath, fixation in formol acetic alcohol and a rinse in 70% alcohol. Using an automatic tissue processor, the specimen is stained in alcian blue for 24 hr and macerated in 3% potassium hydroxide for 8 hr. Staining in alizarin red with maceration in 3% potassium hydroxide is completed manually. The specimens are cleared and preserved in glycerol. Good quality evenly stained specimens can be examined in less than three days and up to 600 fetuses can be processed in less than five days.     

Automated differential staining for cartilage and bone in whole mount preparations of vertebrates

An automated, rapid procedure for differential staining of cartilage and bone of vertebrates is described. The process involves rapid, complete staining of freshly skinned, eviscerated specimens after 30 sec immersion in a 70 C water bath, fixation in formol acetic alcohol and a rinse in 70% alcohol. Using an automatic tissue processor, the specimen is stained in alcian blue for 24 hr and macerated in 3% potassium hydroxide for 8 hr. Staining in alizarin red with maceration in 3% potassium hydroxide is completed manually. The specimens are cleared and preserved in glycerol. Good quality evenly stained specimens can be examined in less than three days and up to 600 fetuses can be processed in less than five days.     

Demonstrating the Osseous Skeleton of Human Embryos and Fetuses

Transparent human embryos and fetuses whose osseous skeletons are stained in toto by alizarin red S are successfully prepared when the KOH clearing of the soft tissues and the alizarin staining of the bones are performed simultaneously instead of independently. This modification minimizes the possibility of macerating and staining the soft tissues. Fetuses over 50 mm. CR length are skinned, eviscerated, decerebrated, defatted by dissection, fixed in 95% alcohol, bleached in H₂O₂, cleared and stained simultaneously in an aqueous solution of KOH (from 2% to 10% depending upon the size of the specimen) and .0001 to .00005% alizarin red S (solution has a pale lavender color). This solution is changed periodically to maintain the concentration of the KOH until the clearing of the tissues is complete and of the alizarin until the bones are properly stained. Tissues are dehydrated in increasing concentrations of glycerin and stored in white glycerin plus thymol.     

A procedure for differential staining of cartilage and bone in whole formalin-fixed vertebrates.

This paper describes a modification of the Simons and Van Horn (1971) procedure for rendering cartilage blue, bone red, and soft tissue translucent or transparent in whole vertebrate specimens. Alcian blue and alizarin red S are used to stain cartilage and bone respectively. In our procedure formalin is used as a fixative. This is a significant modification because formalin is the common fixative for museum specimens. This clearing and staining procedure is thus readily applicable to comparative studies in anatomy, embryology and systematic zoology.     

Cartilage-staining technique for the examination of unskinned fetal rat specimens previously processed with alizarin red S

A novel staining technique has been devised that permits a cartilage examination of unskinned fetal rats that have been previously processed for skeletal examination with alizarin red S. The procedure consists of rinsing alizarin red S-stained specimens in distilled water and placing the specimens in a 3% acetic acid solution. A transfer of the stain from bone to adjacent cartilage occurs, producing purple-stained cartilaginous structures that can be differentiated from still-discernible bone structures.     

Simultaneous Differential Staining of Cartilage and Bone in Rodent Fetuses: an Alcian Blue and Alizarin Red S Procedure without Glacial Acetic Acid

Differential staining of cartilage and bone has several applications including developmental toxicology studies of new chemical candidates for pharmaceutical, industrial, and environmental use. It has been more common to stain fetal bone only using the dye alizarin red S: however, failure to evaluate the cartilaginous portion of the skeleton may result in the failure to identify toxicologically important alterations in skeletal morphology. Previously, differential staining of fetal cartilage and bone was best achieved by combining alizarin red S for staining bone with alcian blue to stain cartilage in glacial acetic acid solution: however, occupational hazards posed by the use of glacial acetic acid make these methods undesirable. Replacement of the glacial acetic acid with potassium hydrogen phthalate eliminates these hazards without compromising the quality of the stained specimen.     

Alizarin Red S and Toluidine Blue for Differentiating Adult or Embryonic Bone and Cartilage

This technic has been successfully employed by the author for staining, in toto, the bones and cartilage of mature specimens of Urodela and the developing bone and cartilage of the embryonic human, cat, pig and rat. The differential staining is accomplished by using a modification of Dawson's method of staining bone with alizarin red S following a toluidine blue solution specific for cartilage. Specimens are fixed in 10% formalin, stained one week in a solution of .25 g. of toluidine blue in 100 cc. of 70% alcohol, macerated 5 to 7 days in a 2% KOH solution, counterstained for 24 hours in a 0.001% solution of alizarin red S in 2% aqueous KOH, dehydrated in cellosolve and cleared in methyl salicylate. In the adult and embryonic forms thus treated the soft tissues are cleared while the osseous tissue is stained red, the cartilage blue.     

Whole-mount bone and cartilage staining of chick embryos with minimal decalcification

Abstract

Whole-mount staining with Alcian blue for cartilage and alizarin red for bone has been widely used for visualizing the skeletal patterns of embryos and small adult vertebrates. The possibility of decalcification by the acidic Alcian blue solution is known, but standard staining protocols do not always avoid this issue. We investigated the effects of acidity on the stainability of developing bones in stage 36 chick embryos and developed an optimal procedure for obtaining reliable results with minimal decalcification. The diaphyses of long bone rudiments and the maxillofacial membranous bones progressively lost their stainability with alizarin red when the chick embryos were soaked for long periods in the preceding acidic Alcian blue staining solution for cartilage. Unless the acidity was neutralized with an alkaline solution, the remaining acidity in the specimens rendered the pH sufficiently low to prevent the subsequent alizarin red staining of the bones. These findings indicate that the mineralizing bones at the early stages of development are labile to acidity and become decalcified more substantially during the staining process than previously appreciated. The following points are important for visualizing such labile mineralizing bones in chick embryos: 1) fixing with formaldehyde followed by soaking in 70% ethanol, 2) minimizing the time that the specimens are exposed to the acidic Alcian blue solution, and 3) neutralizing and dehydrating the specimens by an alkaline-alcohol solution immediately after the cartilage staining. When the exact onset and/or an early phase of ossification are of interest, the current double-staining procedure should be accompanied by a control single-staining procedure directed only toward bone.     

Permanent Preservation of Whole Alizarin Red S Skeletons by Clearing and Embedding in Polyester Resins

A one-step clearing and embedding procedure for alizarin red S stained skeletons is described. Embryos are fixed in formalin, skinned and eviscerated. After staining in a 10 mg/liter solution of alizarin red S in 5% aqueous KOH, specimens are dehydrated in a graded series of acetone-polyester monomer solutions. Finally, the specimens are embedded at room temperature in the polyester resin. A special reusable metallic mold is described for embedment of large fetuses. Specimens previously cleared in glycerol can be processed with this method.     

Permanent preservation of whole alizarin red S skeletons by clearing and embedding in polyester resins

A one-step clearing and embedding procedure for alizarin red S stained skeletons is described. Embryos are fixed in formalin, skinned and eviscerated. After staining in a 10 mg/liter solution of alizarin red S in 5% aqueous KOH, specimens are dehydrated in a graded series of acetone-polyester monomer solutions. Finally, the specimens are embedded at room temperature in the polyester resin. A special reusable metallic mold is described for embedment of large fetuses. Specimens previously cleared in glycerol can be processed with this method.     

Toluidine Blue-Alizarin Red S Staining of Cartilage and Bone in Whole-Mount Skeletons in Vitro

Cartilage and bone of the developing skeleton can be reliably differentiated in whole-mount preparations with toluidine blue-alizarin red S staining after FAA fixation. The recommended staining procedure is based chiefly on the use of newborn white and Swiss-Webster mice, 4-9 days postnatal, but was tested also on mice and rats 3-8 wk of age. Procedure: Sacrifice, skin, eviscerate, remove body fat, and place specimens in FAA (formalin, 1; acetic acid, 1; 70% alcohol, 8) for approximately 40 min. Stain in 0.06% toluidine blue made in 70% ethyl alcohol for 48 hr at room temperature. Use 20 volumes of stain solution to the estimated volume of the specimen. Destain soft tissues in 35% ethyl alcohol, 20 hr; 50%, 28 hr; and 70%, 8 hr. Counterstain in a freshly prepared 1% aqueous solution of KOH to which is added 2-3 drops of 0.1% alizarin red S per 100 ml of solution. Each day for 3 days, transfer the specimen to a fresh 1% KOH-alizarin mixture, or until the bones have reached the desired intensity of red and soft tissues have cleared. Rinse in water, and place in a 1:1 mixture of glycerol and ethyl alcohol for 1-2 hr, then transfer the specimen to fresh glycerol-alcohol for final clearing and storage. Older mice and rats require procedural modifications: (1) fixation for 2 hr, (2) 0.12% toluidine blue, (3) maceration for 4 days in 3% KOH-alizarin, and (4) preliminary clearing for 24 hr in a mixture of glycerol, 2; 70% ethyl alcohol, 2; and benzyl alcohol, 1 (v/v) before placing in a 1:1 alcohol-glycerol mixture.     

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 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.     

Selective staining methods for cartilage of rat fetal specimens previously treated with alizarin red S.

A convenient method for staining cartilage with several basic stains after alizarin red S staining of bone was investigated in rat fetuses. It was found that bromophenol blue was useful and effective for staining of the margin and center areas of cartilage, even in specimens stored in glycerin for over 10 years. The specimens were washed in running tap water for 1 hr, and subsequently were immersed in water or in 70% ethanol at pH 4 for 1 hr or longer. The specimens were then stained with 0.005% bromophenol blue in 40% ethanol adjusted to pH 4 for 2 hr, or with 0.001% bromophenol blue in 40% ethanol adjusted to pH 4 for 24 hr. Furthermore, the bromophenol blue stain color actually faded when the specimens were immersed in water or in 70% ethanol at pH 8. Descending order of the stain-effective action on fetal rat cartilage for the basic stains tested was bromophenol blue, aniline blue, Evans blue, methyl violet, trypan blue, and water blue.     

Technique for Revealing the Three-Dimensional Architecture of Whole Preserved Spiculated Invertebrates

Procedures for revealing the three-dimensional arrangement of calcareous sclerites, spicules, or ossicles embedded within connective tissue in formalin fixed invertebrates are described. Spicules are stained with alizarin red S following maceration of preserved animals or colonies with either trypsin or KOH solutions. Connective tissue is stained with alcian blue in different samples prior to maceration. Stained animals or colonies are cleared in glycerin. This method for revealing spicular structure and arrangement and the gross morphology of connective tissues offers several advantages over either scanning electron microscopy or reconstruction from serial sections.     

A two-color acid-free cartilage and bone stain for zebrafish larvae

Traditionally, cartilage is stained by alcian blue using acidic conditions to differentiate tissue staining. The acidic conditions are problematic when one wishes to stain the same specimen for mineralized bone with alizarin red, because acid demineralizes bone, which negatively affects bone staining. We have developed an acid-free method to stain cartilage and bone simultaneously in zebrafish larvae. This method has the additional advantage that PCR genotyping of stained specimens is possible.     

Enzyme clearing of alcian blue stained whole small vertebrates for demonstration of cartilage.

Preparation of small vertebrates cleared after alcian blue staining of cartilage is facilitated by trypsin digestion. Specimens are fixed in formation, washed, skinned, and eviscerated. After staining in a solution of alcian blue in acetic acid-alcohol for 24-48 hours, they are transferred to water through graded alcohols. Excess alcian blue is removed over a period of up to three weeks by changes every 2-3 days of 1% trypsin in approximately one-third-saturated sodium borate. Bony tissues may be stained after this in a solution of alizarin red S in 0.5% KOH. Specimens are bleached if necessary and dehydrated through graded KOH-glycerine mixtures for storage in glycerine. Since alcohol treatment in addition to formalin fixation does not affect results with this method, it should be useful to researchers who want to study the cartilage or cartilaginous skeletons in museum specimens, which are routinely fixed in formalin and stored in alcohol.