Rapid tissue processing using a temperature-controlled collection device to preserve tumor biomarkers

Precision tissue diagnostics rely on high quality input specimens so that assay results are not affected by artifact, but advances in collection and processing of tissue specimens have lagged behind innovations in diagnostic assay development. Therefore, we have designed and evaluated a novel surgical tissue collection device that maintains and monitors sample temperature and motion throughout transport so that the major preanalytical variable of tissue temperature can be controlled and measured. This device, in combination with an improved cold–hot tissue fixation protocol affords optimal biomarker preservation in less overall time, thereby simultaneously improving diagnostic quality and turnaround time. We collected 50 primary and metastatic liver tumors using a novel transport device. Tissue was fixed using a rapid cold–hot fixation protocol and immunohistochemical assays were used to assess the performance of the device, in comparison to control tissue preserved using standard clinical fixation protocol. Two pathologists evaluated the IHC studies in a blinded fashion to determine the immunophenotype of each tumor. The observed IHC staining intensities and the clinical impressions of the immunophenotypes did not differ between tissue collected with the novel device and control tissue, while improvements in processing time were achieved. The novel cold transport device and rapid fixation protocol can be successfully and safely combined and used to monitor specimen conditions, thus preserving the diagnostic utility of specimens and improving the overall turn-around time of the diagnostic process.

Double Immunohistochemistry and Digital Image Analysis

Immunohistochemistry (IHC) is a commonly used technique for protein detection in tissue sections. The method requires high-affinity antibodies that are specific for the target proteins of interest. More advanced IHC techniques have been developed to meet the need for simultaneous detection of more than one target protein in the same tissue section. This chapter provides general guidelines for double IHC staining of formalin-fixed, paraffin-embedded tissue sections. Chromogenic substrates are chosen based on their excellent contrast and compatibility with the subsequent digital image analysis.

Health Technology Assessment: introducing a vacuum-based preservation system for biological materials in the anatomic pathology workflow

INTRODUCTION

The objective of this work is to assess the implementation of a newly introduced medical equipment technology for the vacuum-based preservation of biological materials within an Anatomic Pathology service.

METHODS

The approach selected for the analysis is the Health Technology Assessment (HTA ), a comprehensive evaluation method based on relevant scientific evidence and designed to support healthcare decision makers in purchasing, replacing or disposing of technologies. The analysis focused on specific domains such as Technology, Organization, Safety and Economy.

RESULTS

The study proves that the use of such technology ensures the biological specimen to be suitably preserved (up to 72 hours), both reducing the amount of fixative being employed in the diagnostic process (30% to 55%) and resulting, in the particular context under examination, in savings of 93%.

DISCUSSION

The HTA reported no significant drawbacks related to the use of the technology being examined. Nonetheless, the workflow for managing the transfer of biological materials from the Operating Room to the Anatomic Pathology department needs to be redefined - in terms of handling, processing, storage and disposal. Other elements concerned the monitoring of storage temperature, fresh tissue handling and especially fixative amount reduction, which positively impacts on the operators' safety with regard to chemical hazards.

Whole-mount in situ hybridization to assess advancement of development and embryo morphology

Whole-mount in situ hybridization (WISH) is widely used to visualize the site and dynamics of gene expression during embryonic development. Various methods of probe labeling and hybridization detection are available nowadays. Meanwhile the technique was adapted to be used on many different species and has evolved from a manual to a larger scale and automated procedure. Standardized automated protocols improve the chance to compare different experimental settings reliably. The high resolution of this method is ideally suited for examination of manipulated (e.g., cloned) embryos often displaying subtle changes only. Embedding and sectioning of in situ hybridized specimen further enhance the detailed examination of their gene expression and morphology.

[A DEVICE FOR THE VACUUM TREATMENT OF HISTOLOGICAL MATERIAL]

A device to carry out all types of vacuum infiltration in a wide temperature range. The device is easy to use and allows you to simultaneously conduct the infiltration of a large number of tissue samples. The main element of the device is a temperature-controlled cuvette, the temperature of which is set in the range of 23-65 °C. The design of the cell allows pumping air from the cell to the 50-100 mm Hg. In practice, histological methods are used to remove the vacuum infiltration of air from the tissue fixation (plant tissue), to accelerate the penetration of fasteners into the tissue. To carry out such a procedure, syringes, water pump and other hand-held devicesare used. Only vacuum infiltration allows a fill lyophilized tissue in paraffin. Efficiency of the described device is checked during the experiments at various fixing plant tissue and nervous tissue filling lyophilized in paraffin.

Ceramic foam plates: a new tool for processing fresh radical prostatectomy specimens

Procurement of fresh tissue of prostate cancer is critical for biobanking and generation of xenograft models as an important preclinical step towards new therapeutic strategies in advanced prostate cancer. However, handling of fresh radical prostatectomy specimens has been notoriously challenging given the distinctive physical properties of prostate tissue and the difficulty to identify cancer foci on gross examination. Here, we have developed a novel approach using ceramic foam plates for processing freshly cut whole mount sections from radical prostatectomy specimens without compromising further diagnostic assessment. Forty-nine radical prostatectomy specimens were processed and sectioned from the apex to the base in whole mount slices. Putative carcinoma foci were morphologically verified by frozen section analysis. The fresh whole mount slices were then laid between two ceramic foam plates and fixed overnight. To test tissue preservation after this procedure, formalin-fixed and paraffin-embedded whole mount sections were stained with hematoxylin and eosin (H&E) and analyzed by immunohistochemistry, fluorescence, and silver in situ hybridization (FISH and SISH, respectively). There were no morphological artifacts on H&E stained whole mount sections from slices that had been fixed between two plates of ceramic foam, and the histological architecture was fully retained. The quality of immunohistochemistry, FISH, and SISH was excellent. Fixing whole mount tissue slices between ceramic foam plates after frozen section examination is an excellent method for processing fresh radical prostatectomy specimens, allowing for a precise identification and collection of fresh tumor tissue without compromising further diagnostic analysis.

Out with the old and in with the new: rapid specimen preparation procedures for electron microscopy of sectioned biological material

This article presents the best current practices for preparation of biological samples for examination as thin sections in an electron microscope. The historical development of fixation, dehydration, and embedding procedures for biological materials are reviewed for both conventional and low temperature methods. Conventional procedures for processing cells and tissues are usually done over days and often produce distortions, extractions, and other artifacts that are not acceptable for today's structural biology standards. High-pressure freezing and freeze substitution can minimize some of these artifacts. New methods that reduce the times for freeze substitution and resin embedding to a few hours are discussed as well as a new rapid room temperature method for preparing cells for on-section immunolabeling without the use of aldehyde fixatives.

The museum maze in oral pathology demystified-part I

Museum technologies provide a wide array of choice of museums to those who wish to exploit technology to attract, excite and ensure an unrivalled visitor experience, as well as capture and sustain share of mind and heart. Museum being a combination of both art and science requires skilled workmanship, meticulous planning and execution to exhibit a specimen to its optimal elegance due to its relatively smaller size and fragile nature. A well established oral pathology museum is rarely seen due to negligence of oral specimens, dearth of knowledge in this field and also available data on it. An insight on oral pathology museum, including its establishment, importance and advanced technologies to make it more simple and accessible are discussed in two parts. Part I emphasizes on basics in oral pathology museum, whereas part II highlights the specialized techniques and recent advances in museum technology. Our effort is to present this article as hands on experience for the pathologists, student population and the technicians.

Immunohistochemical detection of activating transcription factor 3, a hub of the cellular adaptive-response network

Activating transcription factor 3 (ATF3) gene encodes a member of the ATF family of transcription factors and is induced by various stress signals, including many of those that induce the unfolded protein response (UPR). Emerging evidence suggests that ATF3 is a hub of the cellular adaptive-response network and studies using various mouse models indicate that ATF3 plays a role in the pathogenesis of various diseases. One way to investigate the potential relevance of ATF3 to human diseases is to determine its expression in patient samples and test whether it correlates with disease progression or clinical outcomes. Due to the scarcity and preciousness of patient samples, methods that can detect ATF3 on archival tissue sections would greatly facilitate this research. In this chapter, we briefly review the roles of ATF3 in cellular adaptive-response and UPR, and then describe the detailed steps and tips that we developed based on general immunohistochemistry (IHC) protocols to detect ATF3 on paraffin embedded sections.

Comprehensive periorbital rejuvenation with resorbable endotine implants for trans-lid brow and midface elevation

Periorbital rejuvenation can enhance a patient's appearance, with changes of only a few millimeters making a significant impact. Many patients undergoing blepharoplasty often have mild brow or midfacial changes for which they are unwilling to undergo additional concurrent forehead or midface procedures, however, because these procedures may be associated with an unacceptable postoperative recovery and may not provide adequate tissue fixation. This article describes limited incision procedures capable of providing excellent elevation and support to the brow and midface that can be incorporated easily into a comprehensive periorbital rejuvenation treatment plan using semi-permanent subperiosteal fixation devices.

Dual Cryogenic Fixation for Mechanical Testing of Soft Musculoskeletal Tissues

Mechanical testing of soft musculoskeletal structures like tendons and ligaments are essential to medical advances. A long-standing limitation for testing these structures in isolation has been the ability to solidly fix both ends of the tendon. Cryogenic fixation technology was leveraged into the development of a dual cryogenic fixation (DCF) device. Results of the study show that the DCF allows tendons to be tested in isolation, at physiologic temperatures, with excellent reproducibility.

Ultrasound-accelerated formalin fixation of tissue improves morphology, antigen and mRNA preservation

Formalin fixation and paraffin embedding are conventional tissue preservation and processing methods used for histologic diagnosis in over 90% of cases. However, formalin fixation has three disadvantages: (1) slow fixation (16-24 h) hinders intraoperative decision making, (2) slow quenching of enzymatic activity causes RNA degradation, and (3) extensive molecule modification affects protein antigenicity. Applying high-frequency, high-intensity ultrasound to the formalin fixative cuts fixation time to 5-15 min. Fixation of various tissues such as lymph node, brain, breast, and prostate suggests that, compared to the conventional method, implementation of ultrasound retains superior and more uniform tissue morphology preservation. Less protein antigenicity is altered so that rapid immunohistochemical reactions occur with higher sensitivity and intensity, reducing the need for antigen retrieval pretreatment. Better RNA preservation results in stronger signals in in situ hybridization and longer RNA fragments extracted from fixed tissues, probably due to rapid inhibition of endogenous RNase activity. Molecules extracted from ultrasound-fixed tissues are of greater integrity and quantity compared to conventionally fixed tissues, and thus better support downstream molecular analyses. Overall, ultrasound-facilitated tissue preservation can provide rapid and improved morphological and molecular preservation to better accommodate both traditional and molecular diagnoses.

Incorporation of microwave tissue processing into a routine pathology laboratory: impact on turnaround times and laboratory work patterns

AIMS

To examine the impact of microwave (MW) tissue processing on turnaround times (TATs) in a routine diagnostic laboratory.

METHODS

A retrospective review of TATs for tissue processing (specimen receipt to completion of H&E-stained section) and pathologists' report generation (receipt of stained section to validation of completed report) for small biopsies processed in a MW-histoprocessor (Milestone RHS-2, Italy) was performed and compared with similar TATs for specimens processed conventionally prior to the introduction of MW histoprocessing.

RESULTS AND CONCLUSIONS

The TAT for conventional tissue processing was almost 21 h compared with 6.5 h by MW-processing. Reporting TATs fell from 4.3 to 3.2 hours per case, respectively, largely because stained sections became available for reporting in the early afternoon instead of towards the end of the working day. If small biopsies are triaged and handled separately, the TATs can be further reduced, and in selected urgent cases, sections can be available for diagnosis within 90 minutes. The quality of MW processed sections was indistinguishable from those obtained with routine 4-hour processing. The drastic reduction in TATs signifies a new era in histopathological diagnosis in which the majority of reports can be generated within 24 hours of specimen receipt with attendant impact on patient management and hospitalisation costs.

Experience with an automated microwave-assisted rapid tissue processing method: validation of histologic quality and impact on the timeliness of diagnostic surgical pathology

We studied the effect of a fully automated microwave-assisted rapid tissue processor (RTP) on histologic examination and on the turnaround time for surgical pathology reports. A quality assurance program reviewed the histologic sections obtained by the rapid processing method for the last 3 calendar years. In addition, the histologic results from this method were compared blindly with those obtained from the conventional overnight tissue processing (CTP) method by 9 pathologists with different levels of experience. The surgical pathology turnaround times for 1 year of use of the RTP were compared with the last year for CTP. We found that the RTP reproducibly yielded histologic material comparable in quality to CTP. The turnaround time for surgical pathology reports was improved substantially, and, in particular, same-day reporting was achieved in approximately 55% of cases compared with fewer than 1% before use of the RTP. Moreover, use of the RTP enhanced safety by eliminating formalin and xylene from the procedure.

A simple flow-through micro-chamber for handling fragile, small tissue explants and single non-adherent cells

The flow-through chambers described are easily assembled in the laboratory with no need for sophisticated or expensive equipment. They allow for treating micro-explants or single non-adhesive cells with different solutes for defined times by easy and quick changes of the medium in the chambers. The specimen can be fixed, immunostained and observed microscopically within the chamber. During these procedures the cells are not exposed to undue mechanical stress and fragile intercellular structures are well preserved.

Development and evaluation of an automated stainer for acid-fast bacilli

The current strategy for the control of tuberculosis (TB) relies on early diagnosis, and smear microscopy is an essential component of the laboratory diagnosis of TB in most countries with a high prevalence of the disease. However, even simple smear microscopy examination is far from satisfactory because staining results can vary among individual technicians. In an effort to minimize variations in manual staining procedures, we developed an automated stainer for AFB and evaluated its usefulness in comparison with manual staining. The key feature of our automated stainer is a heating apparatus required for fixation and carbol-fuchsin staining. After smear slides are placed into the machine, the entire staining process is fully automated, from fixation to final washing and drying. With the automated methods, five slides can be fixed and stained in 21 min at consistent high quality. Using sputum samples from 91 TB patients, the staining results of the automated stainer were compared blindly with those of manual staining. The concordance rate between the two methods was 94.5%. In addition, there was no significant difference in the rate of detection of AFB in the sputum samples. Although further optimization of the auto staining procedures is required, the results indicate that the automated AFB stainer developed in this study looks promising for use in clinical mycobacteriology laboratory in order to minimize personal variation during AFB staining.

[A new technique for foetal brain fixation and extraction]

We performed a new technique for foetal brain fixation and extraction that offers a remarkable reduction in sampling time facilitates specimen handling while conserving high quality. With the new fixation method, it is possible to obtain samples adequate for macroscopic and microscopic observations and immunohistochemical analysis. The technique involves the creation of an ex vacuo phenomenon in the subarachnoideal space prior to injecting the fixative solution. In this manner, the solution is homogenously distributed. Ease, reproducibility and the possibility of standardizing the procedure are the principal advantages. Low costs, reduced wording time and less need for human resources are other advantages. Histologically, we obtained, quickly, high quality slides with routine and immunohistochemical stains. Disadvantages of the technique derive from the use of formaldehyde and glacial acetic acid, rather than water to wash the samples; thus one must work in a well ventilated area, with gloves, protective glasses and an adequate lab coat to avoid skin and respiratory tract damage.

Biomechanical porcine model of median sternotomy closure

BACKGROUND

Healing complications following median sternotomy commonly include instability, nonunion, and infection. They are associated with a high mortality rate if mediastinitis supervenes. Closure complications are best avoided by improving stability at the union, but there has thus far been no widespread agreement among surgeons about relative superiority among the available closure techniques.

MATERIALS AND METHODS

A biological sternotomy closure model was developed utilizing whole porcine sterna. A special stainless-steel clamp with multiple spikes was created to reliably attach the sterna to a biomechanical testing device.

RESULTS

Two wiring techniques, single peristernal and pericostal figure-eight, were used in 14 fresh cadaveric porcine sterna. The more rigid closure utilized single peristernal wires (P < 0.0001). There was no tissue associated with clamp spikes penetrating the specimen's layers, and there was no clamp displacement even at closure failure loads.

CONCLUSIONS

The porcine sternotomy model is a valuable tool for comparing closure techniques based on geometrical and mechanical wiring patterns. The model's low cost and easy reproducibility make it a promising first step in sternotomy closure research. The stainless-steel clamp used in the porcine model provided reliable repeat specimen fixation.

Method of producing tissue sections from endometrial scrapings

Endometrial cytology is important not only for observing cytological findings, but also for assessing histological architecture. Therefore, we attempted to produce a histological preparation from the sample using an automatic fixation apparatus (ACF 1000) which employs a membrane filter method. After observation of the cytological features, the cover slip was removed and a paraffin-embedded section was prepared. Producing a histological section from a cytological specimen prepared with the ACF 1000 apparatus was more useful and easier than with the techniques described to date. Peelability of the cell was avoided by using a silane-coated membrane filter. Observation of the same cell cluster as that observed in the cytological sample was also facilitated in the histological section by this technique.

A new approach for cryofixation by high-pressure freezing

A newly designed high-pressure freezing machine for cryofixation was established and tested (Leica EMPACT), based on ideas originally proposed by Moor & Riehle in 1968. The new machine, essentially an improved version of our prototype, pressurizes the sample to 2000 bar in a small container (using methylcyclohexane as hydraulic fluid) and at the same time cools the outer surface of the container with a jet of liquid nitrogen. The advantage of this approach is that the machine uses little liquid nitrogen and can be built small and light. The machine is able to vitrify and freeze well a variety of specimens, for example, plant leaves, yeast cells, liver or nerve tissue (more samples are shown at: http://www.ana.unibe.ch/empact). Cooling efficiency is the same as in the traditional machines that use liquid nitrogen to pressurize and simultaneously cool the sample.

Ultrastructural preservation of rat embryonic dental tissues after rapid fixation and dehydration under microwave irradiation

Adequate preservation of the cells and matrix of mineralising tissues remains difficult, as organic components and initial mineral deposits may be lost during conventional processing for electron microscopy. In this study, we have reduced significantly the processing time using microwave irradiation. Rat molar tooth germs were fixed in 4% glutaraldehyde + 4% formaldehyde with 0.1 M sodium cacodylate in a laboratory microwave oven for two periods of 20 s with a maximal temperature of 37 degrees C. After conventional washing and post-fixation, specimens were dehydrated in graded ethanols under microwave irradiation for a total of 7 min 20 s. For comparison, some specimens were processed by conventional methods. After embedding, ultrathin sections were examined by electron microscopy. In differentiating ameloblasts and odontoblasts, plasma membranes, mitochondria, rough endoplasmic reticulum, the Golgi complex, together with all other cytoplasmic organelles exhibited excellent preservation. Microtubules, microfilaments and coated vesicles were particularly evident. Crystal-like mineral deposits were conspicuously present in relation to dentine matrix vesicles and collagen fibrils as well as in enamel matrix. The matrix of forming enamel had a globular electron-lucent appearance. It is concluded that this is a rapid method which provides a preserved or even improved morphology.

Spaceflight hardware allowing unilateral irradiation and chemical fixation in petri dishes

To accommodate a spaceflight experiment with moss (SPM), experiment-unique equipment (EUE) was developed by engineers at Kennedy Space Center. The hardware allows sterile culture for an extended period of time in commercial petri dishes, lateral illumination of each culture with light of a specific wavelength (660 nm; other wavelengths are possible) and a range of intensities (0.05-5 micromoles photons m-2 s-1), incubation in complete darkness, and chemical fixation to terminate the experiment under conditions of microgravity. The use of a fixative required triple containment to protect the astronaut crew. An external panel on the experiment container allowed the timing of illumination and fixation to be controlled by the crew. Light quality is provided by light emitting diodes (LEDs) that are located in the lid of the outer container, the BRIC (Biological Research In Canisters)-LED. Each canister accommodates 6 Petri Dish Fixation Units (PDFUs), and each PDFU holds one 6 cm petri dish. All components are autoclavable. LED illumination is piped through a transparent glass rod. Each PDFU contains fixative in a reservoir that is released by the depression of an actuator. This hardware performed well during its first flight, the 16-day STS-87 mission in Nov./Dec., 1997 as part of the Collaborative USA and Ukrainian Experiment (CUE). It supported vigorous and sterile moss growth, cells were maintained in position and were well-fixed, and there was a vigorous and consistent response to light. Although here used for moss, in future flight experiments this unique new hardware can be used for many types of organisms normally grown in petri dishes, with or without a requirement for illumination.

Calibration and standardization of microwave ovens for fixation of brain and peripheral nerve tissue

Rapid and reproducible fixation of brain and peripheral nerve tissue for light and electron microscopy studies can be done in a microwave oven. In this review we report a standardized nomenclature for diverse fixation techniques that use microwave heating: (1) microwave stabilization, (2) fast and ultrafast primary microwave-chemical fixation, (3) microwave irradiation followed by chemical fixation, (4) primary chemical fixation followed by microwave irradiation, and (5) microwave fixation used in various combinations with freeze fixation. All of these methods are well suited to fix brain tissue for light microscopy. Fast primary microwave-chemical fixation is best for immunoelectron microscopy studies. We also review how the physical characteristics of the microwave frequency and the dimensions of microwave oven cavities can compromise microwave fixation results. A microwave oven can be calibrated for fixation when the following parameters are standardized: irradiation time; water load volume, initial temperature, and placement within the oven; fixative composition, volume, and initial temperature; and specimen container shape and placement within the oven. Using two recently developed calibration tools, the neon bulb array and the agar-saline-Giemsa tissue phantom, we report a simple calibration protocol that identifies regions within a microwave oven for uniform microwave fixation.

Fixation procedure for transmission electron microscopy of Chara rhizoids under microgravity in a Spacelab (IML-2)

A special fixation device and fixation procedure have been developed to investigate for the first time the ultrastructure of gravity-sensing, unicellular Chara rhizoids grown for 30 h under microgravity (MG) conditions during the IML-2 mission. The fixation unit allowed culture, fixation and storage of Chara rhizoids in the same chamber without transferring the samples. The procedure was easy and safe to perform and required a minimum of crew time. Rhizoids fixated with glutaraldehyde in space and further processed for electron microscopy on ground showed that the fixation was of high quality and corresponded to the fixation quality of rhizoids in the ground controls. Thus, the equipment accomplished the manifold problems related to the physical effects of MG. The polarity of the rhizoids was maintained in MG. Well-preserved organelles and microtubules showed no obvious difference in ultrastructure or distribution after 30-h growth in MG compared to ground controls. The statoliths were more randomly distributed, however, only up to 50 microns basal to the tip. Thus, changing the gravity conditions does to disturb the cellular organisation of the rhizoids enabling the tip-growing cells to follow their genetic program in development and growth also under MG.

A stereologic study of postmature placentas fixed by dual perfusion

OBJECTIVE

Placental insufficiency has been considered the cause of increased morbidity in infants delivered postmaturely. Former quantitative studies have indicated a decrease in some placental structures just before term. In this study we describe a method of dual perfusion fixation to provide tissue for stereologic examination. Postmature placentas were examined with this method.

STUDY DESIGN

Eleven postmature placentas and 14 placentas delivered at term were fixed by dual perfusion. The volume and the surface area of villi, the trophoblast volume, and the volume, surface area, and length of villous capillaries were estimated by stereologic examination. The Mann-Whitney test (p < or = 0.05) was used for statistical analysis.

RESULTS

Morphologic features were normal in all placentas. No significant differences were disclosed in the stereologic estimates of placentas delivered at term and postmature placentas.

CONCLUSION

No morphologic or significant quantitative changes were found in postmature placentas.

Microwave fixation and localization of calcium in synaptic vesicles

The distribution of Ca2+ ions is demonstrated in the synaptic terminals by means of a 2-step chemical precipitation of Ca2+ ions in nervous tissue. K-oxalate/K-antimonate chemical replacement with simultaneous computerized microwave irradiation is used. This precipitate in cell structures was investigated by computerized electron probe X-ray micro-analysis. The calculated values (from the theoretical, standards and sections), elemental binding ratios and elemental molecular weight ratios were compared. Each calculated value coincided with the theoretical value. This method can reliably detect Ca2+ ions at the micromolar level. Ca2+ ions were distributed in the synaptic vesicles and surrounding membranes. Further progress is expected in freeze-substitution and in the application and propagation of the EELS-Imaging system in calcium determinations.

[The use of perfusion for brain fixation]

Two modifications of the apparatus for the fixation of the whole human brain are described. This apparatus can also be used for the fixation of other organs and for dead body embalming.

A simple device for sectioning fresh rat brain

This article describes a simple device that enables sectioning of an unfixed unfrozen fresh rat brain corresponding in position with the de Groote's stereotaxic coordinate systems. The construction of this device allows adjustment of the thickness of the individual brain slices and, thus, facilitates quick and precise removal of whole discrete brain particles or nuclei from a minimal number of slices. Adaptation of this device for other stereotaxic brain atlases is easily possible.

Improvements in the technique of vascular perfusion-fixation employing a fluorocarbon-containing perfusate and a peristaltic pump controlled by pressure feedback

A new improved technique for whole-body perfusion-fixation of rats and other small animals is described. The driving force is a peristaltic pump which is feedback regulated by a pressure transducer that monitors the blood-perfusion pressure in the left ventricle of the heart. The primary perfusate-fixative is composed of a blood substitute--13.3% oxygenated fluorocarbon FC-75--in 0.05 M cacodylate buffer (pH 7.4) with a 2% glutaraldehyde. The secondary perfusate-fixative is composed of 2% glutaraldehyde in 0.05 M cacodylate buffer (pH 7.4) with 20 mM CaCl2. A double-barrelled, self-holding cannula is used to cannulate the heart; the outer and inner barrels of the cannula are connected to the peristaltic pump and to the pressure transducer, respectively. The tissue oxygen tension in the rat is monitored by a subcutaneous oxygen electrode. Measurements showed that tissue hypoxia/anoxia did not develop before or during the perfusion-fixation. Thus, the technique permits study of specimens which do not exhibit fixation gradients and do not contain cells fixed in a state of asphyxia. This is substantiated by electron micrographs of cells from different organs, revealing new fine structural elements. By adding oxygenated fluorocarbon to glutaraldehyde perfusate-fixatives, enough oxygen is made accessible for cellular respiration as well as for the oxygen-consuming chemical reactions of glutaraldehyde with the tissue. Data on anaesthesia, operative manoeuvres, mechanical components of the system, preparation of fixatives and flow of the perfusate-fixatives are furnished and discussed.

Automatic fixation facility for plant seedlings in the TEXUS Sounding Rocket Programme

Automatic chemical fixation of plant seedlings within a 6 min period of reduced gravity (10(-4)g) was performed on three ballistic rocket flights provided by the German Sounding Rocket Programme TEXUS (Technologische Experimente unter Schwerelosigkeit = Technological Experiments in Microgravity). The described TEXUS experiment module consists of a standard experiment housing with batteries, cooling and heating systems, timer, and a data recording unit. Typically, 60 min before launch an experiment plug-in unit containing chambers with the plant material, the fixation system, and the temperature sensors is installed into the module which is already integrated in the payload section of the sounding rocket (late access). During the ballistic flight plant chambers are rapidly filled at pre-selected instants to preserve the cell structure of gravity sensing cells. After landing the plant material is processed for transmission electron microscopy. Up to now three experiments were successfully performed with cress roots (Lepidium sativum L.). Detailed improvements resulted in an automatic fixation facility which in principle can be used in unmanned missions.

Microwave fixation and rapid processing in a large throughput histopathology laboratory

Technical details of a method of microwave fixation and rapid processing are described. Fresh biopsy specimens are sampled and trimmed into 2 mm thick blocks and irradiated to a temperature of 68 degrees C. They are then processed through cycles of absolute alcohol (75 min), xylene (50 min) and wax (50 min). It is possible, in this manner, to run several 'short' cycles of about 3 hrs each during the working day so that stained sections are available on the same day as receipt of the specimens. Endoscopic biopsies are processed through a shorter cycle comprising 30 min of absolute alcohol (4 changes), 20 min of xylene (3 changes) and 20 min of wax (2 changes). For convenience we also employ an overnight cycle whereby microwave-fixed blocks are processed through several changes of absolute alcohol, xylene and wax without the use of formalin. This method of processing not only removes the use of noxious and potentially toxic formalin but also allows rapid preparation of good quality diagnostic sections with superior antigen preservation compared to formaldehyde fixation.

Microwave oven for improved tissue fixation and decalcification

The present study reports on our experience on microwave (MW) fixation and decalcification. A common kitchen microwave oven was used. Autoptical material and biopsies from different organs were immersed in 10% formalin and MW irradiated varying time and power. Bone biopsies were immersed in 5% formic acid and MW irradiated. The tissues were then routinely embedded in paraffin. The results, checked on routinely stained sections, indicate that MW irradiation speeds up both fixation and decalcification. Optimal treatment conditions are indicated.