Embedding Iliac Bone Biopsies at Low Temperature using Glycol and Methyl Methacrylates

A mixture of pure and anhydrous glycol methacrylate and methyl methactylate is used as an embedding medium for iliac bone biopsies. Infiltration is carried out at -20 C with the embedding medium and a cold inactivated catalyst-initiator system. Raising the temperature to 4 C initiates polymerization and limits the peak temperature of polymerization to 25 C. In this way, such thermolabile enzymes as osteoclastic acid phosphatase are preserved. After staining, sections are dehydrated in polyethylene glycol 400 30% in 2-propanol. This gives flat sections and improves staining properties.     

Alkaline and Acid Phosphatase Demonstration in Human Bone and Cartilage: Effects of Fixation Interval and Methacrylate Embedments

Human bone and cartilage specimens were evaluated for acid and alkaline phosphatase localization following varying fixation periods for fresh or frozen tissue. Formalin fixations of up to 183 hr were followed by embedment in methyl methacrylate; frozen tissue was examined either without fixation or following fixation for up to 1 hr and subsequent glycol or methyl methacrylate embedding. The humeral epiphysis of a young patient with osteogenic sarcoma showed optimum acid and alkaline phosphatase localization following fixation for periods up to 15 hr and embedding in methyl methacrylate. Frozen costochondral junction from a newborn with osteogenesis imperfecta type II showed optimum acid and alkaline phosphatase localization following 30 min fixation in formalin and embedding in methyl methacrylate or after 5 min fixation and embedding in glycol methacrylate.     

Alkaline and acid phosphatase demonstration in human bone and cartilage: effects of fixation interval and methacrylate embedments

Human bone and cartilage specimens were evaluated for acid and alkaline phosphatase localization following varying fixation periods for fresh or frozen tissue. Formalin fixations of up to 183 hr were followed by embedment in methyl methacrylate; frozen tissue was examined either without fixation or following fixation for up to 1 hr and subsequent glycol or methyl methacrylate embedding. The humeral epiphysis of a young patient with osteogenic sarcoma showed optimum acid and alkaline phosphatase localization following fixation for periods up to 15 hr and embedding in methyl methacrylate. Frozen costochondral junction from a newborn with osteogenesis imperfecta type II showed optimum acid and alkaline phosphatase localization following 30 min fixation in formalin and embedding in methyl methacrylate or after 5 min fixation and embedding in glycol methacrylate.     

An embedding method for histochemical studies of undecalcified skeletal growth plate

We have used glycol methacrylate to study undecalcified skeletal growth plate and subchondral bone. Minor modifications of the original technique including dehydration in glycol methacrylate vacuum infiltration and polymerization in the cold make it quite suitable for embedding of such tisssues. Moreover, specimens can be processed quickly and the morphologic and biochemical integrity of the tissue retained so that histochemical procedures can be readily applied. Collagen, glycosaminoglycan, glycogen, lipid, calcium and the activity of alkaline and acid phosphatase were localized. This technique appears to be very useful for studying skeletal tissues.     

An Embedding Method for Histochemical Studies of Undecalcified Skeletal Growth Plate

We have used glycol methacrylate to study undecalcified skeletal growth plate and subchondral bone. Minor modifications of the original technique including dehydration in glycol methacrylate vacuum infiltration and polymerization in the cold make it quite suitable for embedding of such tissues. Moreover, specimens can be processed quickly and the morphologic and biochemical integrity of the tissue retained so that histochemical procedures can be readily applied. Collagen, glycosaminoglycan, glycogen, lipid, calcium and the activity of alkaline and acid phosphatase were localized. This technique appears to be very useful for studying skeletal tissues.     

Initiating Polymerization of Glycol Methacrylate with Cyclic Diketo Carbon Acids

Several pharmacologically active cyclic diketone carbon acids, including phenylbutazone and 2-phenyl-1,3-indandione, catalyze the polymerization of glycol methacrylate momomers. GMA-cyclic diketone carbon acid monomer mixtures incorporating imidazole polymerize smoothly without obvious exothermicity at temperatures ranging from ambient to -5 C without the use of ultraviolet light. The only equipment required for this embedding technique is a refrigerator with a freezing compartment which can maintain temperatures of -15 C. A recipe consisting of 5 ml glycol methacrylate (2-hydroxyethyl methacrylate), 0.8 ml 1-pentanol, 16 mg imidazole, and 30 mg monophenylbutazone is recommended for general use. The use of dicyclopentyl methacrylate-glycol methacrylate comonomer mixtures incorporating cyclic ketone catalysts is advocated, as blends of these monomers have low basophilia, and tissues embedded in these matrices stain sharply and brilliantly. It is hypothesized that the driving force for the cyclic ketone-mediated polymerization of glycol methacrylate under basic conditions is furnished by the lysis of cyclic ketone carbon acid peroxides.     

Initiating polymerization of glycol methacrylate with cyclic diketo carbon acids

Several pharmacologically active cyclic diketone carbon acids, including phenylbutazone and 2-phenyl-1,3-indandione, catalyze the polymerization of glycol methacrylate monomers. GMA-cyclic diketone carbon acid monomer mixtures incorporating imidazole polymerize smoothly without obvious exothermicity at temperatures ranging from ambient to -5 C without the use of ultraviolet light. The only equipment required for this embedding technique is a refrigerator with a freezing compartment which can maintain temperatures of -15 C. A recipe consisting of 5 ml glycol methacrylate (2-hydroxyethyl methacrylate), 0.8 ml 1-pentanol, 16 mg imidazole, and 30 mg monophenylbutazone is recommended for general use. The use of dicyclopentyl methacrylate-glycol methacrylate comonomer mixtures incorporating cyclic ketone catalysts is advocated, as blends of these monomers have low basophilia, and tissues embedded in these matrices stain sharply and brilliantly. It is hypothesized that the driving force for the cyclic ketone-mediated polymerization of glycol methacrylate under basic conditions is furnished by the lysis of cyclic ketone carbon acid peroxides.     

Selective acylation of cholic acid derivatives with multiple methacrylate groups

Bile acids in the family of steroid compounds can be chemically modified for biochemical and other applications. Derivatives of cholic acid with multiple methacrylate groups can be prepared by the use of methacrylic acid, methacryloyl chloride and methacryloyl anhydride as the acylating agents. The hydroxyl groups of cholic acid methyl ester and cholic acid ethylene glycol ester have been selectively acylated by changing the acylating agents and the number of substitutions have been varied by changing the amount of the acylating agents used. In the acylation reactions with methacryloyl chloride, the reactivity of secondary hydroxyl groups on the steroid skeleton of cholic acid derivatives follows the order of C3>C12>C7.     

Glycol Methacrylate Embedding in Histotechnology: The Hematoxylin-Eosin Stain as A Method for Assessing the Stability of Glycol Methacrylate Sections

Glycol methacrylate (GMA) samples containing inhibitor in the range of 200-300 ppm were included in a standard embedding mixture. The pH of the GMA samples was measured as a 10% solution of the sample in distilled water. The acidity of GMA due to methacrylic acid causes background staining of sections after basic dyes. The concentration of GMA and the amount of impurities such as methacrylic acid (MA) and ethylene glycol dimethacrylate (EDMA) were measured by gas chromatography. Distinct variations in purity were found among five samples of GMA. Sections derived from GMA samples containing more than 2% EDMA showed few, if any, minifolds after staining with hematoxylin and eosin and were more stable in alcoholic and basic solutions; sections from purer GMA showed minifolds and were less stable. Addition of crosslinkers, EDMA or triethylene glycol dimethacrylate (TEDMA) prevented these artifacts. Crosslinkers clearly influence dimensional changes in sections. Addition of crosslinkers to GMA samples containing minimal amounts of MA improved the results. The possibility of obtaining a high quality GMA embedding medium is discussed.     

Glycol methacrylate embedding in histotechnology: the hematoxylin-eosin stain as a method for assessing the stability of glycol methacrylate sections

Glycol methacrylate (GMA) samples containing inhibitor in the range of 200-300 ppm were included in a standard embedding mixture. The pH of the GMA samples was measured as a 10% solution of the sample in distilled water. The acidity of GMA due to methacrylic acid causes background staining of sections after basic dyes. The concentration of GMA and the amount of impurities such as methacrylic acid (MA) and ethylene glycol dimethacrylate (EDMA) were measured by gas chromatography. Distinct variations in purity were found among five samples of GMA. Sections derived from GMA samples containing more than 2% EDMA showed few, if any, minifolds after staining with hematoxylin and eosin and were more stable in alcoholic and basic solutions; sections from purer GMA showed minifolds and were less stable. Addition of crosslinkers, EDMA or triethylene glycol dimethacrylate (TEDMA) prevented these artifacts. Crosslinkers clearly influence dimensional changes in sections. Addition of crosslinkers to GMA samples containing minimal amounts of MA improved the results. The possibility of obtaining a high quality GMA embedding medium is discussed.     

Improved Stability of A Purified Glycol Methacrylate Preparation: Comments

The technical note from Bernier et al. (1984) presents additional observations on our procedure for purifying glycol methacrylate (GMA), a hydrophylic resin (Chappard et al. 1982). It is becoming increasingly popular and widely used as an embedding medium for light microscopic studies. GMA is prepared by esterification of methacrylic acid (MA), but about 1% of free unreacted MA remains in the monomer. MA can copolymerize with GMA and it also binds strongly to thiazin and other basic dyes (Tipett and O'Brien 1975) so as an undesirable impurity it must be removed.     

Science and Art in Preparing Tissues Embedded in Plastic for Light Microscopy, with Special Reference to Glycol Methacrylate, Glass Knives and Simple Stains

Plastic embedding preserves tissue structure much more faithfully than does paraffin. Acrylic polymerization is innocuous to dye-binding groups in sections. The water solubility of glycol methacrylate monomer and the hydrophilic properties of the polymer allow for convenience in dehydration and for versatility in staining sections. Five years of experience with glycol methacrylate (GMA) embedding for light microscopy is summarized. Methods for purifying GMA monomer are cited. Procedures for fixing, dehydrating, embedding, polymerizing, sectioning and staining, using GMA, are explained. A method is provided for making glass knives long enough to cut large blocks. Simple, reliable, quick staining methods are outlined. When compared with paraffin, GMA offers opportunities for simpler, quicker procedures and yields sections of superior quality, greater information content, and less distortion.     

Science and art in preparing tissues embedded in plastic for light microscopy, with special reference to glycol methacrylate, glass knives and simple stains.

Plastic embedding preserves tissue structure much more faithfully than does paraffin. Acrylic polymerization is innocuous to dye-binding groups in sections. The water solubility of glycol methacrylate monomer and the hydrophilic properties of the polymer allow for convenience in dehydration and for versatility in staining sections. Five years of experience with glycol methacrylate (GMA) embedding for light microscopy is summarized. Methods for purifying GMA monomer are cited. Procedures for fixing, dehydrating, embedding, polymerizing, sectioning and staining, using GMA, are explained. A method is provided for making glass knives long enough to cut large blocks. Simple, reliable, quick staining methods are outlined. When compared with paraffin, GMA offers opportunities for simpler, quicker procedures and yields sections of superior quality, greater information content, and less distortion.     

Simultaneous demonstration of bone alkaline and acid phosphatase activities in plastic-embedded sections and differential inhibition of the activities

Summary Bone alkaline (AlP) and acid phosphatase (AcP) activities were simultaneusly demonstrated in tissue sections obtained from mice, rats, and humans. The method involved tissue fixation in ethanol, embedding in glycol methacrylate (GMA), and demonstration of AlP and AcP activities employing a simultaneous coupling azo dye technique using substituted naphthol phosphate as a substrate. AlP activity was demonstrated first followed by AcP activity. Both enzyme activities were demonstrated in tissue sections from bones fixed and/or stored in acetone or 70% ethanol for up to 14 days or stored in GMA for 2 months. AlP activity in tissue sections from bones fixed in 10% formalin, 2% glutaraldehyde, or formal-calcium, however, was markedly inhibited after 3–7 days and was no longer detectable after 14 days of fixation. Moreover, AlP activity was diminished in tissue sections from bones fixed in 70% ethanol or 10% formalin and subsequently demineralized in 10% EDTA (pH7) for 2 days, and the activity was completely abolished in tissue sections from bones subsequently demineralized in 5% formic acid: 20% sodium citrate (1:1, pH 4.2) for 2 days. Methyl methacrylate (MMA) embedding at concentrations above 66% completely inhibited AlP activity. AcP activity, however, was only partially inhibited by formalin, glutaraldehyde, or formal-calcium after 7 or 14 days of fixation or by MMA embedding and was unaffected by the demineralizing agent formic acid-citrate for 2 days. While AcP activity was preserved in bones fixed in formalin and subsequently demineralized in EDTA, the activity was completely abolished when EDTA demineralization was carried out on bones previously fixed in 70% ethanol. These results indicate that bone AlP and AcP activities can be demonstrated simultaneously in the same section using a simple tissue preparation technique and that the activities are retained in tissues fixed and/or stored in acetone, 70% ethanol or GMA, but are differentially inactivated by other fixatives studied, and by EDTA, formic acid-citrate, and MMA embedding.Abbreviations AcP acid phosphatase - AlP alkaline phosphatase - GMA glycol methacrylate - MMA methyl methacrylate - EDTA ethylenediaminetetraacetic acid     

Glycol Methacrylate Sections of the Crystalline Lens

Sections of the crystalline lens are difficult to prepare because of the hardness of the fixed lens. After paraffin procedures the lens shatters and cracks when cut because the reagents and high temperatures used for infiltration further harden it. Plastic has been successfully used as an embedding medium for other difficult tissues. It allows prolonged infiltration times at room temperature, and provides a firm matrix for tissues containing areas of varying density. However, standard procedures for embedding tissue in plastic do not allow for complete infiltration of the crystalline lens. The purpose of this report is to describe a modification of the glycol methacrylate embedding technique which ensures complete infiltration of the lens. The following protocol was found to produce consistently good 1-5 μm sections of lenses from 10-2O-day-old rats.     

Dehydrogenase enzyme histochemistry on freezedried or fixed resin-embedded tissue

Summary A method has been developed for the histochemical demonstration of a variety of dehydrogenases in freeze-dried or fixed resin-embedded tissue. Seven dehydrogenases were studied. Lactate dehydrogenase, NADH dehydrogenase and NADPH tetrazolium reductase were all demonstrable in sections of paraformaldehyde-fixed resin-embedded tissue. Freeze-dried specimens were embedded, without fixation, in glycol methacrylate resin or LR Gold resin at either 4°C or –20°C. All the dehydrogenases except succinate dehydrogenase retained their activity in freeze-dried, resin-embedded tissue. Enzyme activity was maximally preserved by embedding the freeze-dried tissue specimens in glycol methacrylate resin at –20°C. The dehydrogenases were accurately localized without any diffusion when the tissue sections were incubated in aqueous media. Addition of a colloid stabilizer to the incubating medium was not required. Freeze-drying combined with low-temperature resin embedding permits accurate enzyme localization without diffusion, maintenance of enzyme activity and excellent tissue morphology.     

Properties and degradation of a new bioresorbable bone glue]

In trauma surgery gluing is an attractive method of bonding fractured bone, which is rapid and does not require the use of screws and plates. The purpose of this study was to analyze in vitro the properties of a new bioresorbable bone glue, and in vivo its structure and degradation. The newly developed bone glue is based on alkylenbis(oligolactoyl)methacrylates and employs a two-component initiator system. Starting components for synthesis are ethylene glycol, lactic acid and methacrylic acid. In vitro the solidified glue is degraded via hydrolysis of ester bonds. Degradation products are ethylene glycol, lactic acid and oligomeres of methacrylic acid. After the first week polymer pellets (MMA, HEMALA, ELAMA) showed a weight loss of 12%. From week 2-20 a linear weight loss of 1.5% per week, that is 40% after 20 weeks, was observed. The in vivo investigations of the ultrastructure of the glue revealed a transparent and homogeneous mass with large electron-tight vacuoles. Differences in structure and degradation were not observed. Degradation of glue by hydrolysis and phagocytosis, with good biocompatibility was demonstrated.     

Rapid Removal of Acid from Glycol Methacrylate for Improved Histological Embedding

A method for the rapid and complete removal of methacrylic acid from commercial samples of glycol methacrylate is presented. It entails conversion of the acid to an insoluble N-acylurea by treatment with an equivalent amount of N, N'-dicyclohexylcarbodiimide. Sections of tissue embedded in polymer prepared from the purified monomer can be stained with basic dyes without simultaneously staining the polymer.     

pH-sensitive unimolecular polymeric micelles: synthesis of a novel drug carrier

Novel amphiphilic star-shaped polymers showing pH-sensitivity were synthesized by atom transfer radical polymerization. These new polymers present a core-shell structure similar to polymeric micelles, but are inherently stable to dilution and are referred to as unimolecular polymeric micelles. A four-armed multifunctional initiator was used for the sequential polymerization of hydrophobic ethyl methacrylate and tert-butyl methacrylate and hydrophilic poly(ethylene glycol)methacrylate. Polymers of molecular weight ranging from 9000 to 20,000 were obtained. Results of dynamic light scattering showed micelle size ranging from 11 to 40 nm. Unimolecular micelles were also analyzed by static light scattering in aqueous environment. Star-shaped polymers which presented the highest molar ratio of hydrophobic monomers tended to form high molecular weight aggregates in water. Hydrolysis of the tert-butyl methacrylate units permitted the introduction of ionizable methacrylic acid functions. Size distributions were bimodal at both acidic and basic pH. Since, the polymers were designed as potential delivery systems for the oral administration of hydrophobic drugs, they were titrated to evaluate the degree of ionization as a function of pH. In the stomach, the carboxylic functions are expected to be fully protonated. However, in the intestine, the micelles will be more than 40% ionized. Fluorescence studies were conducted in order to evaluate the polarity of the micellar core. Results showed an increase in polarity with pH due to the ionization of the acid functions present along the polymer chains. The pH rise was associated with an increase in the in vitro release rate of progesterone, which was used as hydrophobic drug model.