Rat Model of Blood-brain Barrier Disruption to Allow Targeted Neurovascular Therapeutics

Endothelial cells with tight junctions along with the basement membrane and astrocyte end feet surround cerebral blood vessels to form the blood-brain barrier¹. The barrier selectively excludes molecules from crossing between the blood and the brain based upon their size and charge. This function can impede the delivery of therapeutics for neurological disorders. A number of chemotherapeutic drugs, for example, will not effectively cross the blood-brain barrier to reach tumor cells². Thus, improving the delivery of drugs across the blood-brain barrier is an area of interest.The most prevalent methods for enhancing the delivery of drugs to the brain are direct cerebral infusion and blood-brain barrier disruption³. Direct intracerebral infusion guarantees that therapies reach the brain; however, this method has a limited ability to disperse the drug⁴. Blood-brain barrier disruption (BBBD) allows drugs to flow directly from the circulatory systeminto the brain and thus more effectively reach dispersed tumor cells. Three methods of barrier disruption include osmotic barrier disruption, pharmacological barrier disruption, and focused ultrasound with microbubbles. Osmotic disruption, pioneered by Neuwelt, uses a hypertonic solution of 25% mannitol that dehydrates the cells of the blood-brain barrier causing them to shrink and disrupt their tight junctions. Barrier disruption can also be accomplished pharmacologically with vasoactive compounds such as histamine⁵ and bradykinin⁶. This method, however, is selective primarily for the brain-tumor barrier⁷. Additionally, RMP-7, an analog of the peptide bradykinin, was found to be inferior when compared head-to-head with osmotic BBBD with 25% mannitol⁸. Another method, focused ultrasound (FUS) in conjunction with microbubble ultrasound contrast agents, has also been shown to reversibly open the blood-brain barrier⁹. In comparison to FUS, though, 25% mannitol has a longer history of safety in human patients that makes it a proven tool for translational research^10-12.In order to accomplish BBBD, mannitol must be delivered at a high rate directly into the brain''s arterial circulation. In humans, an endovascular catheter is guided to the brain where rapid, direct flow can be accomplished. This protocol models human BBBD as closely as possible. Following a cut-down to the bifurcation of the common carotid artery, a catheter is inserted retrograde into the ECA and used to deliver mannitol directly into the internal carotid artery (ICA) circulation. Propofol and N₂O anesthesia are used for their ability to maximize the effectiveness of barrier disruption¹³. If executed properly, this procedure has the ability to safely, effectively, and reversibly open the blood-brain barrier and improve the delivery of drugs that do not ordinarily reach the brain ^8,13,14.     

3-Dimensional Resin Casting and Imaging of Mouse Portal Vein or Intrahepatic Bile Duct System

In organs, the correct architecture of vascular and ductal structures is indispensable for proper physiological function, and the formation and maintenance of these structures is a highly regulated process. The analysis of these complex, 3-dimensional structures has greatly depended on either 2-dimensional examination in section or on dye injection studies. These techniques, however, are not able to provide a complete and quantifiable representation of the ductal or vascular structures they are intended to elucidate. Alternatively, the nature of 3-dimensional plastic resin casts generates a permanent snapshot of the system and is a novel and widely useful technique for visualizing and quantifying 3-dimensional structures and networks.A crucial advantage of the resin casting system is the ability to determine the intact and connected, or communicating, structure of a blood vessel or duct. The structure of vascular and ductal networks are crucial for organ function, and this technique has the potential to aid study of vascular and ductal networks in several ways. Resin casting may be used to analyze normal morphology and functional architecture of a luminal structure, identify developmental morphogenetic changes, and uncover morphological differences in tissue architecture between normal and disease states. Previous work has utilized resin casting to study, for example, architectural and functional defects within the mouse intrahepatic bile duct system that were not reflected in 2-dimensional analysis of the structure^1,2, alterations in brain vasculature of a Alzheimer''s disease mouse model³, portal vein abnormalities in portal hypertensive and cirrhotic mice⁴, developmental steps in rat lymphatic maturation between immature and adult lungs⁵, immediate microvascular changes in the rat liver, pancreas, and kidney in response in to chemical injury⁶.Here we present a method of generating a 3-dimensional resin cast of a mouse vascular or ductal network, focusing specifically on the portal vein and intrahepatic bile duct. These casts can be visualized by clearing or macerating the tissue and can then be analyzed. This technique can be applied to virtually any vascular or ductal system and would be directly applicable to any study inquiring into the development, function, maintenance, or injury of a 3-dimensional ductal or vascular structure.     

The role of the blood-brain barrier in perfusion fixation of the brain for electron microscopy

Synopsis Regions of the brain vascularized by capillaries of the blood-brain barrier (BBB) type require a different fixative from regions which have capillaries of the endocrine type. Fixative with isotonic buffer gives excellent ultrastructural preservation in the BBB regions, but causes severe shrinkage of cells in the endocrine regions. This is evidently due to the difference in the permeability of the capillary walls to solutes in the fixative. In the BBB regions the less perimeable capillaries do not allow outflow of osmotically active particles to a harmful extent, whereas in the endocrine regions osmotic imbalances are created between the intra-and extracellular compartments.The diffusion rate of the fixative and the final volume of the fixed brain depend on the balance between the intravascular and interstitial hydrostatic and oncotic pressures across the capillary wall during the perfusion fixation, as those pressures regulate the amount of perfusate that will enter the parenchyma. Generally, as high a perfusion pressure as possible is recommended to obtain effective wash-out of blood and rapid diffusion of dixative into the tissue. Addition of macromolecules (2% PVP, mol. wt. 40000) into the fixative slightly improved the ultrastructural preservation in the BBB regions of the centrel nervous system.     

Preparation of tissues for localization of sex hormones by autoradiography

Summary Tissues of rats given ³H-oestradiol were prepared for autoradiography according to methods commonly used in light and electron microscopy.By formalin fixation large amounts of radioactive material were lost, both in the fixative and during dehydration. Altogether 78.6±7.5 per cent was extracted from uterine tissue, while 49.0±4.6 per cent was lost from liver tissue removed 15 minutes after the injection. Significantly more radioactivity was lost in the fixative from liver tissue than from uterine. In the former fixation accounted for about 60 per cent of the loss, whereas in the latter it was responsible for about 25 per cent.Osmium tetroxide fixation was found to retain the radioactivity of liver and uterine tissue almost completely. However, large amounts were invariably extracted during dehydration. Although only 3.9±1.2 per cent of the radioactivity of uterine tissue diffused into the fixative, 72.8±12.4 per cent was extracted during ethanol dehydration. A heavy loss was also registered when dehydration and infiltration were carried out in glycol methacrylate.Glutaraldehyde perfusion and postfixation with osmium tetroxide retained almost completely the radioactivity of uterine and pituitary tissue. Nevertheless, nearly all of it was extracted during ethanol/propylene oxide dehydration and Epon embedding.The methods studied are not adequate for accurate autoradiographic localization of oestradiol.This work was supported by grants from The Norwegian Cancer Society and by Nordisk Insulinfond. The skilful assistance of Miss Helga Friedl and Mrs. Jane Larsen is gratefully acknowledged.     

Histomorphometric comparison after fixation with formaldehyde or glyoxal

Abstract

Formaldehyde has long been the fixative of choice for histological examination of tissue. The use of alternatives to formaldehyde has grown, however, owing to the serious hazards associated with its use. Companies have striven to maintain the morphological characteristics of formaldehyde-fixed tissue when developing alternatives. Glyoxal-based fixatives now are among the most popular formaldehyde alternatives. Although there are many studies that compare staining quality and immunoreactivity, there have been no studies that quantify possible structural differences. Histomorphometric analysis commonly is used to evaluate diseased tissue. We compared fixation with formaldehyde and glyoxal with regard to the histomorphological properties of plantar foot tissue using a combination of stereological methods and quantitative morphology. We measured skin thickness, interdigitation index, elastic septa thickness, and adipocyte area and diameter. No significant differences were observed between formaldehyde and glyoxal fixation for any feature measured. The glyoxal-based fixative used therefore is a suitable fixative for structural evaluation of plantar soft tissue. Measurements obtained from the glyoxal-fixed tissue can be combined with data obtained from formalin-fixed for analysis.     

Mapping stimulus-induced nervous activity in small brains by [3H]2-deoxy-D-glucose

Summary Nervous activity may be localized in anatomical sections of brain tissue by the autoradiographic deoxyglucose technique. The method provides sufficient structural preservation and spatial resolution for detailed functional investigation of complex but small-sized nervous systems when the original technique is modified as follows: (i) use of ³H instead of ¹⁴C as radioactive label, (ii) application of labeled deoxyglucose in concentrations close to physiological glucose levels rather than in trace amounts, (iii) stimulation for 4–9 h after deoxyglucose application instead of 20–45 min, (iv) subsequent preparation avoiding aqueous phases at all stages from fixation to autoradiography, and (v) plastic embedding of the tissue such that serial semithin sections of good structural preservation may be routinely cut. Brief aqueous fixation and dehydration at room temperature as has been described for vertebrates apparently cannot preserve stimulus-induced distribution of radioactive label in the brain of the fly Drosophila melanogaster. Aspects of the results that illustrate the potential and some limitations of the present technique are discussed.     

The pressure-flow relation for plasma in whole organ skeletal muscle and its experimental verification.

The whole-organ pressure-flow relation in resting rat skeletal muscle is examined for the flow of plasma. Due to the small size of the blood vessels in this organ, inertia and convective forces in the blood are negligible and viscous forces dominate. Direct measurements in the past have shown that skeletal muscle blood vessels are distensible. Theoretical formulations based on these measurements lead to a third order polynomial model for the pressure-flow relation. The purpose of the current study is to examine this relation experimentally in an isolated muscle organ. A high precision feedback controlled pump is used to perfuse artificial plasma into the vasodilated rat gracilis muscle. The results indicate that the pressure-flow curve in this tissue is nonlinear in the low flow region and almost linear at physiological flow rates, following closely the third order polynomial function. Vessel fixation with glutaraldehyde causes the curves to become linear at all pressures, indicating that vessel distention is the primary mechanism causing the nonlinearity. Furthermore, the resistance of the post-fixed tissue is determined by the pressure at which the fixative is perfused. At fixation pressures below 10 mmHg, the resistance is three times higher than in vessels fixed at normal physiological pressures. Dextran (229,000 Dalton) is used to obtain Newtonian perfusates at different viscosities. The pressure-flow relation is found to be linearly dependent on viscosity for all flow rates.(ABSTRACT TRUNCATED AT 250 WORDS)     

Formaldehyde fixation and microwave irradiation

Summary Formaldehyde is the most commonly used fixative in pathology laboratories. However, due to time pressures, this fixative is often not optimally exploited. the majority of biopsies are only partly fixed when histoprocessing is started, with adverse effects. This paper reports how formaldehyde fixation is improved, by using 1.5 min of microwave irradiation of tissue previously soaked for four hours in the fixation solution. It is argued that this beneficial effect of microwave irradiation can be attributed to the acceleration of the reaction of formaldehyde to the tissue. Formation of free formaldehyde, by the dehydration of methylene glycol present in the tissue when the irradiation starts, is also enhanced. Five different formaldehyde-containing fixatives were evaluated, using five different working protocols. Spleen was taken as a suitable tissue for these tests. The technique described leads to uniform microscopical results. It is a simple method and is suitable for use in routine laboratories.     

Fixation variables in horseradish peroxidase neurohistochemistry. I. The effect of fixation time and perfusion procedures upon enzyme activity.

In a series of neurohistochemical experiments the effect of aldehyde fixation upon the detection of horseradish peroxidase (HRP) was examined. These experiments demonstrated that: a) Increments in fixation of as little as 1 hr significantly decreased the number of labeled neurons; 12-hr fixation abolished HRP activity in many neuronal populations and significantly reduced the apparent size of the injection site. b) This negative fixation effect was greatest where the HRP concentration was low (e.g. in small, lightly labeled neurons) but was still evident in areas of high concentration (e.g. large, heavily labeled neurons). c) This effect was also most prominent when a less sensitive diaminobenzidine histochemical procedure was employed but was still apparent with a more sensitive benzidine dihydrochloride procedure. d) Immersion of the brain in fixative after perfusion produced a greater attenuation of HRP activity in more superficial areas. e) Immersion of the brain in buffer to terminate fixation produced a prolonged and unpredictable gradient of fixation. f) Excess, unbound fixative inhibited the histochemical reaction per se and had to be removed from the tissue but prolonged washing did not resurrect enzyme activity which was lost by fixation. To obviate these problems and optimize HRP enzyme activity a new perfusion-fixation procedure was developed. It entails 30 min fixation by perfusion which is terminated by a subsequent 30 min perfusion with cold sucrose-fuller to wash out unbound fixative. This allows the tissue to be processed immediately, produces a uniform and morphologically adequate fixation, and minimizes the negative effects of fixation on HRP enzyme activity.     

Pronase treatment increases the staining intensity of GABA-immunoreactive structures in the paravertebral sympathetic ganglia

Summary A novel tissue preparation technique for improving gamma-aminobutyric acid (GABA) immunocytochemistry has been developed. The influence of the glutaraldehyde concentration in the fixative and the effect of pronase treatment on the GABA immunostaining were tested. This method includes fixation with a high concentration of glutaraldehyde, gelatin embedding and treatment of the sections with pronase. In sympathetic (paravertebral) ganglia and their connectives, the most intense and specific immunoreaction was obtained with the following procedure: immersion fixation in 5% glutaraldehyde, infiltration and embedding in 15% gelatin, secondary fixation of the samples with 4% formaldehyde, floating frozen sections and digestion with 0.1% pronase for 15–20 min. With this technique, the GABA-containing structures (cells and nerve fibers with varicosities forming basket-like networks around some principal neurons) were selectively labeled. The data presented suggest that (1) a high concentration (5%) of glutaraldehyde in the primary fixative is necessary to preserve a large proportion of the GABA content; (2) this glutaraldehyde fixation partly masks the GABA immunoreactivity; and (3) this masking may be overcome by a proteolytic treatment preceding the immunostaining. This method has been extensively tested for the light microscopic visualization of GABA-containing tissue components in the sympathetic ganglion chain, but it may probably also be used for the immunocytochemical detection of other small molecules in other parts of the nervous system.     

MEASUREMENTS OF SOME CELLULAR CHANGES DURING THE FIXATION OF AMPHIBIAN ERYTHROCYTES WITH OSMIUM TETROXIDE SOLUTIONS

On average, 15 per cent of the total haemoglobin present in the blood of the newt Triturus cristatus was extracted during 45 minutes of fixation in Palade-Caulfield fixative. This extraction was reduced with fixatives buffered at pH 6.2 instead of pH 7.4. The addition of Ca⁺⁺ ions to a final concentration of 0.01 M in the fixative completely suppressed haemoglobin extraction. The effect of the pH, and the presence or absence of Ca⁺⁺ ions in the fixative, on the rate of haemoglobin extraction has been determined. During Palade-Caulfield fixation the average projected area of newt erythrocytes increased by 37 per cent, and after dehydration and embedding in Epon the average area was 25 per cent greater than that of the unfixed cell. Fixatives buffered at pH 6.2 and containing 0.01 M Ca⁺⁺ ions caused cellular shrinkage, with the average projected area decreasing by 10 per cent in the fixative. This shrinkage continued during dehydration, and the final average area of the erythrocytes in Epon was 26 per cent less than that of the unfixed cells. Similar measurements with erythrocytes of Amphiuma tridactylum showed that after Palade-Caulfield fixation the average cellular area was increased by 45 per cent, and after dehydration and embedding in Araldite it was 36 per cent greater than that of the unfixed cell. The average nuclear area increased by 35 per cent during fixation but after embedding it was 26 per cent greater than that of the unfixed nuclei. With a fixative at pH 6.2 containing 0.01 M Ca⁺⁺ ions, both the nucleus and the whole cell shrank during fixation. The nuclear area decreased by 20 per cent and the cellular area by 22 per cent. After dehydration and embedding in Araldite, the average nuclear area had decreased by 35 per cent and the cellular area by 40 per cent. It has been shown that OsO₄ fixation lowers the isoelectric points of haemoglobins and other proteins. This finding has been used in the interpretation of the observed cellular changes resulting from fixation.     

Fixation, fine structure, and immunostaining for neuropeptides: perfusion versus immersion of the neuroendocrine hypothalamus

The effects of various fixatives and fixation methods on ultrastructural morphology and the immunocytochemical localization of beta-endorphin were examined in rat brain. The mediobasal hypothalamus was preserved by vascular perfusion and/or immersion in nine different fixatives. We tested several combinations of paraformaldehyde, glutaraldehyde, acrolein, and picric acid in various isosmolar buffers. Vibratome sections were stained for beta-endorphin employing the peroxidase-antiperoxidase technique, or processed directly for electron microscopy. The ultrastructural quality of a given region was attributed to its location with respect to the blood-brain barrier, the method of fixation, and the concentrations of some of the fixative components. Immersion fixation gave better results and reduced extracellular space in the median eminence (outside the blood-brain barrier) and areas close to the hypothalamic surface. Positive immunostaining of beta-endorphin perikarya occurred only in tissue fixed with periodate-lysine-paraformaldehyde. Light to moderate fiber staining was also present in some paraformaldehyde-glutaraldehyde-acrolein combinations. However, a glutaraldehyde concentration of 1% or higher abolished all positive staining for beta-endorphin. These results emphasize the necessity of optimizing fixation for ultrastructure and for immunocytochemical staining of each individual antigen. The choice of the best fixation method depends not only on the intracellular location of the antigen but also on the relationship between hypothalamic tissue compartments and the blood-brain barrier.     

High subzero cryofixation: A technique for observing ice within tissues

While various fixation techniques for observing ice within tissues stored at high sub-zero temperatures currently exist, these techniques require either different fixative solution compositions when assessing different storage temperatures or alteration of the sample temperature to enable alcohol-water substitution. Therefore, high-subzero cryofixation (HSC), was developed to facilitate fixation at any temperature above −80 °C without sample temperature alteration. Rat liver sections (1 cm²) were frozen at a rate of −1 °C/min to −20 °C, stored for 1 h at −20 °C, and processed using classical freeze-substitution (FS) or HSC. FS samples were plunged in liquid nitrogen and held for 1 h before transfer to −80 °C methanol. After 1, 3, or 5 days of −80 °C storage, samples were placed in 3% glutaraldehyde on dry ice and allowed to sublimate. HSC samples were stored in HSC fixative at −20 °C for 1, 3, or 5 days prior to transfer to 4 °C. Tissue sections were paraffin embedded, sliced, and stained prior to quantification of ice size. HSC fixative permeation was linear with time and could be mathematically modelled to determine duration of fixation required for a given tissue depth. Ice grain size within the inner regions of 5 d samples was consistent between HSC and FS processing (p = 0.76); however, FS processing resulted in greater ice grains in the outer region of tissue. This differed significantly from HSC outer regions (p = 0.016) and FS inner regions (p = 0.038). No difference in ice size was observed between HSC inner and outer regions (p = 0.42). This work demonstrates that HSC can be utilized to observe ice formed within liver tissue stored at −20 °C. Unlike isothermal freeze fixation and freeze substitution alternatives, the low melting point of the HSC fixative enables its use at a variety of temperatures without alteration of sample temperature or fixative composition.     

Substrate Infiltration and Histological Fixatives Affect the In Situ Localisation of β‐Glucuronidase Activity in Transgenic Tissues

The β‐glucuronidase (GUS) gene is a widely used reporter gene in transgenic research. This study shows that although histochemical localisation of GUS activity may be very specific, differences in incubation conditions and tissue status can lead to artificial localisations that are independent of gene activity. The objective of the current studies was to evaluate the factors that affect the in‐situ localisation of β‐glucuronidase using transgenic tobacco plants as model tissues. The aspects considered include tissue size as well as and the addition of surfactants, vacuum infiltration and chemical fixatives. Transgenic tobacco plants exhibited variable staining patterns dependent on the size of tissue assayed and the treatments that affected the infiltration of substrate. A gradient of blue staining was observed in larger tissue pieces (10 mm²), where staining in central areas was light blue in contrast to edges, which stained deep indigo. More intense staining was associated with peripheral cell layers and regions adjacent to leaf veins. Thinner tissue strips incubated under similar conditions exhibited intense and even X‐Gluc staining. Addition of Triton X‐100 (1%) surfactant and vacuum infiltration (2 min) produced considerably quicker and more uniform staining (intense and consistent indigo blue colour) of the examined tissue after a 4 to 6‐h incubation. Chemical fixation of tissues before GUS assay resulted in quantitative and histochemical differences in enzyme activity that were dependent on the fixative type and duration. Quantitative measurements using the MUG fluorometric assay showed that Histochoice? provided the highest retention of GUS activity, maintaining more than 80 and 50% of the activity after fixation for 15 and 30 min, respectively. Activity in decreasing order was obtained with paraformaldehyde, glutaraldehyde, ethanol and FAA. GUS activity was affected not only by the type of fixative, but also by the duration of fixation with longer fixation producing lower GUS activity. From the experiments performed it can be concluded that those treatments that enhance substrate penetration, i.e., the addition of surfactant and vacuum infiltration, improve the consistency and speed of X‐Gluc staining.     

Coculture System with an Organotypic Brain Slice and 3D Spheroid of Carcinoma Cells

Patients with cerebral metastasis of carcinomas have a poor prognosis. However, the process at the metastatic site has barely been investigated, in particular the role of the resident (stromal) cells. Studies in primary carcinomas demonstrate the influence of the microenvironment on metastasis, even on prognosis^1,2. Especially the tumor associated macrophages (TAM) support migration, invasion and proliferation³. Interestingly, the major target sites of metastasis possess tissue-specific macrophages, such as Kupffer cells in the liver or microglia in the CNS. Moreover, the metastatic sites also possess other tissue-specific cells, like astrocytes. Recently, astrocytes were demonstrated to foster proliferation and persistence of cancer cells^4,5. Therefore, functions of these tissue-specific cell types seem to be very important in the process of brain metastasis^6,7.Despite these observations, however, up to now there is no suitable in vivo/in vitro model available to directly visualize glial reactions during cerebral metastasis formation, in particular by bright field microscopy. Recent in vivo live imaging of carcinoma cells demonstrated their cerebral colonization behavior⁸. However, this method is very laborious, costly and technically complex. In addition, these kinds of animal experiments are restricted to small series and come with a substantial stress for the animals (by implantation of the glass plate, injection of tumor cells, repetitive anaesthesia and long-term fixation). Furthermore, in vivo imaging is thus far limited to the visualization of the carcinoma cells, whereas interactions with resident cells have not yet been illustrated. Finally, investigations of human carcinoma cells within immunocompetent animals are impossible⁸.For these reasons, we established a coculture system consisting of an organotypic mouse brain slice and epithelial cells embedded in matrigel (3D cell sphere). The 3D carcinoma cell spheres were placed directly next to the brain slice edge in order to investigate the invasion of the neighboring brain tissue. This enables us to visualize morphological changes and interactions between the glial cells and carcinoma cells by fluorescence and even by bright field microscopy. After the coculture experiment, the brain tissue or the 3D cell spheroids can be collected and used for further molecular analyses (e.g. qRT-PCR, IHC, or immunoblot) as well as for investigations by confocal microscopy. This method can be applied to monitor the events within a living brain tissue for days without deleterious effects to the brain slices. The model also allows selective suppression and replacement of resident cells by cells from a donor tissue to determine the distinct impact of a given genotype. Finally, the coculture model is a practicable alternative to in vivo approaches when testing targeted pharmacological manipulations.     

Modifications of S100-protein immunoreactivity in rat brain induced by tissue preparation

Immunocytochemistry using antibodies against various molecular forms of the Ca⁺⁺ and Zn⁺⁺-binding S100 proteins predominantly labelled astrocytes. However, especially in the neocortex the staining pattern is variable. Methods of tissue preparation have been evaluated with the aim to preserve as much S 100 immunoreactivity as possible. Optimal results were obtained after perfusion fixation with 4–5% aldehydes, 0.1M sodium cacodylate, 0.1% CaCl₂, pH 7.3. In such preparations, astrocytes were completely labelled including their lamellar compartments in large parts of the central nervous system. Ca⁺⁺-withdrawal had adverse affects on S100 immunoreactivity. Cryostat sections treated with EDTA-containing solutions before fixation showed that Ca⁺⁺-free S100 can apparently not be fixed to the tissue. Perfusion fixatives containing EDTA resulted in inhomogeneous loss of S100 staining, indicating a differential susceptibility of astrocytic subpopulations. A different type of reduction in S100 immunoreactivity occurred around large neocortical blood vessels. Perivascular defects in immunostaining occasionally appeared even after optimal fixation, but could be regularly provoked by mildly acidic fixation (pH 6.6) or prolonged barbiturate anaesthesia. These defects might be based on S100 release into the cerebrospinal fluid. Presumably under none of the conditions studied can the immunoreactivity of all S100-forms and-fractions be completely preserved in the tissue. However, recommendations are presented for optimizing tissue preparation, to the extent that premortal modifications affecting the stainability of astrocytes may be detected by S100 immunohistochemistry in fixed brain tissue.     

Vascular Patterns in Iguanas and Other Squamates: Blood Vessels and Sites of Thermal Exchange

Squamates use the circulatory system to regulate body and head temperatures during both heating and cooling. The flexibility of this system, which possibly exceeds that of endotherms, offers a number of physiological mechanisms to gain or retain heat (e.g., increase peripheral blood flow and heart rate, cooling the head to prolong basking time for the body) as well as to shed heat (modulate peripheral blood flow, expose sites of thermal exchange). Squamates also have the ability to establish and maintain the same head-to-body temperature differential that birds, crocodilians, and mammals demonstrate, but without a discrete rete or other vascular physiological device. Squamates offer important anatomical and phylogenetic evidence for the inference of the blood vessels of dinosaurs and other extinct archosaurs in that they shed light on the basal diapsid condition. Given this basal positioning, squamates likewise inform and constrain the range of physiological thermoregulatory mechanisms that may have been found in Dinosauria. Unfortunately, the literature on squamate vascular anatomy is limited. Cephalic vascular anatomy of green iguanas (Iguana iguana) was investigated using a differential-contrast, dual-vascular injection (DCDVI) technique and high-resolution X-ray microcomputed tomography (μCT). Blood vessels were digitally segmented to create a surface representation of vascular pathways. Known sites of thermal exchange, consisting of the oral, nasal, and orbital regions, were given special attention due to their role in brain and cephalic thermoregulation. Blood vessels to and from sites of thermal exchange were investigated to detect conserved vascular patterns and to assess their ability to deliver cooled blood to the dural venous sinuses. Arteries within sites of thermal exchange were found to deliver blood directly and through collateral pathways. The venous drainage was found to have multiple pathways that could influence neurosensory tissue temperature, as well as pathways that would bypass neurosensory tissues. The orbital region houses a large venous sinus that receives cooled blood from the nasal region. Blood vessels from the nasal region and orbital sinus show anastomotic connections to the dural sinus system, allowing for the direct modulation of brain temperatures. The generality of the vascular patterns discovered in iguanas were assessed by firsthand comparison with other squamates taxa (e.g., via dissection and osteological study) as well as the literature. Similar to extant archosaurs, iguanas and other squamates have highly vascularized sites of thermal exchange that likely support physiological thermoregulation that “fine tunes” temperatures attained through behavioral thermoregulation.     

Ethanol-induced Adaptation of Alcohol Dehydrogenase Activity in Rat Brain

ALTHOUGH the presence of alcohol dehydrogenase (ADH) in cerebral tissue has been established¹, a physiological role for such a brain ethanol-oxidizing system has been unclear. The brain may be more biochemically adaptive than was once thought²; thus, it seemed possible that brain ADH may be substrate-induced. We now report that significant elevations of brain ADH activity occur in alcohol-imbibing rats; no changes from control values were found in liver ADH, liver aldehyde dehydrogenase (AldDH), or brain AldDH activities.     

Identification of Inter-Organ Vascular Network: Vessels Bridging between Organs

Development and homeostasis of organs and whole body is critically dependent on the circulatory system. In particular, the circulatory system, the railways shuttling oxygen and nutrients among various organs, is indispensible for inter-organ humoral communication. Since the modern view of the anatomy and mechanics of the circulatory system was established in 17^th century, it has been assumed that humoral factors are carried to and from organs via vascular branches of the central arteries and veins running along the body axis. Over the past few decades, major advances have been made in understanding molecular and cellular mechanisms underlying the vascularization of organs. However, very little is known about how each organ is linked by vasculature (i.e., inter-organ vascular networks). In fact, the exact anatomy of inter-organ vascular networks has remained obscure. Herein, we report the identification of four distinct vessels, V1^LP, V2^LP, V3^LP and V4^LP, that bridge between two organs, liver and pancreas in developing zebrafish. We found that these inter-organ vessels can be classified into two types: direct and indirect types. The direct type vessels are those that bridge between two organs via single distinct vessel, to which V1^LP and V2^LP vessels belong. The indirect type bridges between two organs via separate branches that emanate from a stem vessel, and V3^LP and V4^LP vessels belong to this type. Our finding of V1^LP, V2^LP, V3^LP and V4^LP vessels provides the proof of the existence of inter-organ vascular networks. These and other yet-to-be-discovered inter-organ vascular networks may facilitate the direct exchange of humoral factors that are necessary for the coordinated growth, differentiation and homeostasis of the connected organs. It is also possible that the inter-organ vessels serve as tracks for their connected organs to follow during their growth to establish their relative positions and size differences.     

Importance of fixation in immunohistochemistry: use of formaldehyde solutions at variable pH for the localization of tyrosine hydroxylase

Adequate fixative in immunohistochemistry requires not only a rapid and total immobilization of the antigen, but also a sufficient preservation of its immunoreactivity and maintenance of its accessibility to the immunochemical reagents for localization. Thus, the optimal fixation condition for a specific antigen necessitates a compromise between these opposing variables and can be determined by the preparation of a series of tissues with a progressively increasing degree of fixation. Unless the results of localization using such a series is available, one must be satisfied with adequate but less than optimal results. In the present study, this principle is demonstrated using the localization of tyrosine hydroxylase in the dopaminergic system with formaldehyde as the fixative. The rate and degree of fixation with formaldehyde was shown to be highly pH dependent. By perfusing the tissue with formaldehyde at pH 6.5 (where the rate of fixation is extremely slow) it is possible to rapidly distribute the fixative homogeneously into the tissue. By suddenly changing to a formaldehyde perfusate of higher pH, the cross-linking reaction is rapidly increased. This two-step fixation procedure provides a means of obtaining a rapid and uniform immobilization of the antigen, so that its translocation can be avoided. The final degree of fixation is controlled by the duration and pH of the second fixative solution. The results obtained by increasing the pH of the second solution demonstrated that complete fixation of tyrosine hydroxylase in the dopaminergic system with formaldehyde maybe obtained using a very basic formaldehyde solution (pH 11) while still retaining immunoreactivity of the enzyme. The localization that was achieved at lower pH appeared adequate until it was compared to the results obtained by perfusion at pH 11 in the second step.