Here we describe a low-cost, rapid, controlled and uniform fixation procedure using 4% paraformaldehyde perfused via the vascular system: through the heart of the rat to obtain the best possible preservation of the brain.
The goal of fixation is to rapidly and uniformly preserve tissue in a life-like state. While placing tissue directly in fixative works well for small pieces of tissue, larger specimens like the intact brain pose a problem for immersion fixation because the fixative does not reach all regions of the tissue at the same rate 5,7. Often, changes in response to hypoxia begin before the tissue can be preserved 12. The advantage of directly perfusing fixative through the circulatory system is that the chemical can quickly reach every corner of the organism using the natural vascular network. In order to utilize the circulatory system most effectively, care must be taken to match physiological pressures 3. It is important to note that physiological pressures are dependent on the species used. Techniques for perfusion fixation vary depending on the tissue to be fixed and how the tissue will be processed following fixation. In this video, we describe a low-cost, rapid, controlled and uniform fixation procedure using 4% paraformaldehyde perfused via the vascular system: through the heart of the rat to obtain the best possible preservation of the brain for immunohistochemistry. The main advantage of this technique (vs. gravity-fed systems) is that the circulatory system is utilized most effectively.
1. Prepare Fixative
(See table Fixative and Buffers.)
2. Prepare Perfusion Buffers
(See table Fixative and Buffers.)
3. Prepare Apparatus and Anesthesia
4. Perfusion Surgery
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5. Perfusion
6. Dissection 4,11
7. Post-fixation & Storage
8. Representative Results
An initial indicator of the success of the perfusion is the clearing of extremities such as the nose, ears, and paws and internal organs such as the thymus gland and liver (IHC World). Gross inspection of the brain reveals the blood vessel void of blood (white to pale yellow appearance). This will be also true within tissue sections destine for staining and immunohistochemistry. The final indicator of outcome of the perfusion is the condition of the ultrastructure in the tissue.1,6,7,8
Prepare Fixative: |
Prepare 8% Paraformaldehyde stock |
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Prepare 0.2 M Sodium Phosphate Buffer, pH 7.4 |
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Prepare 4% Paraformaldehyde Fixative |
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Prepare Perfusion and Storage Buffers: |
Prepare Phosphate Buffered Saline, pH 7.4 |
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HEPES Buffered Hanks Solution (HBHS) with Sodium Azide pH 7.4 |
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Table 1. Preparation of Fixative and Buffers.
Figure 1. Perfusion Apparatus with labeled components.
Figure 2. Preparation of the Perfusion Apparatus I. Begin with the fixative line. Flush the tubing of air bubbles and fill with buffer by rapidly expelling and withdrawing buffer into the syringe and through the line. Shut the valve on the needle end off. Place the fixative line into the fixative bottle without introducing air bubbles.
Figure 3. Preparation of the Perfusion Apparatus II. 1. Open valve on the needle end. 2. Turn buffer valve (blue) to position for flow. 3. Flush the tubing of air bubbles and fill with buffer by rapidly expelling and withdrawing buffer with the syringe. 4. Close valve on the needle end. Place tubing into the buffer bottle. Test pressure to make sure the system is sealed correctly by pumping up the manometer bulb and watching the gauge. The apparatus is now ready for the perfusion procedure.
Figure 4. Perfusion Apparatus in position for buffer delivery.
Figure 5. Perfusion Surgery I. a) Make a lateral incision through the integument and abdominal wall. b) Make an incision in the diaphragm and cut across the diaphragm exposing the heart. Make parallel cuts on either side of the ribs up to the collarbone. c) clamp the tip of the sternum with the hemostat and place the hemostat over the head.
Figure 6. Perfusion Surgery II. a) Pass the perfusion needle through the cut ventricle into the ascending aorta. b) Secure the perfusion needle use one set of hemostats to clamp the heart. A second set of a modified hemostat can also be used to clamp the aorta around the needle tip to prevents leakage. Using iris scissors make a small incision to the posterior end of the left ventricle.
Figure 7. Perfusion with Buffer Pump the manometer bulb to create pressure in the line. Open up the valve (1) and attach to the needle hub. It is critical to make sure no air bubbles are introduced. Pump up the manometer bulb to a pressure of 80 mm Hg and maintain this pressure throughout the buffer infusion period.
Figure 8. Perfusion with Fixative Once buffer is almost finished (200 ml) switch the buffer valve (1) to allow for the fixative to flow. The pressure can gradually be increased up to a maximum of 130 mm Hg.
Figure 9. Dissection I. a) remove the head using a pair of scissor. b) make an incision in the skin along the midline from the neck to the nose and expose the skull. c) trim off the remaining neck muscle so that the base of the skull is exposed. Hold the head so that the large opening in the cranium surface (foramen magnum) is accessible. Carefully insert the sharp end of a pair of iris scissors into the foramen magnum and make a cut. Repeat the same maneuver for the contralateral side. Use the rongeurs to clear away the skull around the cerebellum.
Figure 10. Dissection II. a) carefully slide the scissors along the inner surface of the skull. Lift up on the tip as you are cutting to prevent damage to the brain. Repeat the same for opposite side. Use rongeurs peel the skull away from the brain. b) illustration with the skull removed and the brain exposed. c) use a spatula to sever the olfactory bulbs and nerve connections at the most anterior location of the brain. Carefully guide the spatula tip along the underside of the brain to sever connections for ease of remove. Remove the brain and place it in a vial of fixative.
Additional notes for a successful surgery:
The authors have nothing to disclose.
This work was funded by the Center for Neural Communication Technology (CNCT), a P41 Resource Center funded by the National Institute of Biomedical Imaging and Bioengineering (NIBIB, P41 EB002030) and supported by the National Institutes of Health (NIH).
Equipment | Company | Catalogue number | Yorumlar |
Anesthetic: | |||
Ketamine/xylazine mixture (Anesthetic may vary per laboratory / institution) | Ketaset | NDC 0856-2013-01 | 10 mL vial |
Surgery: | |||
Needle tip, 27 GA x 1.25″ | Materiel Services | 25251 | |
Large blunt/blunt curved scissors (~14.5 cm) | Fine Science Tools | 14519-14 | |
Straight iris scissors | Fine Science Tools | 14058-11 | |
Standard tweezers | Fine Science Tools | 11027-12 | |
Pair of fine (Graefe) tweezers | Fine Science Tools | 11050-10 | |
1 large hemostat forceps – curved or straight (~19 cm) | surgicaltools.com | 17.21.51 | |
2 standard hemostat forceps – straight serrated (14 cm) | Fine Science Tools | 13013-14 | |
1 modified hemostat (with 15-gauge hole filed through the tip) | Fine Science Tools | 13013-14 | |
15-gauge blunt or olive-tipped needle (perfusion needle) | Fisnar | 5601137 | |
Perfusion: | |||
HyPerfusion system or equivalent | |||
Phosphate buffered saline, pH 7.4 | |||
4% Paraformaldehyde in 0.1 M Phosphate Buffer, pH 7.4 | |||
Shallow glass or plastic tray, approximately 10″ x 10″ | |||
Crushed ice | |||
Water bath (37 °C) | |||
Timer | |||
50 ml syringe | Medline Industries | NPMJD50LZ | |
Dissection: | |||
Pair of standard sharp/blunt straight scissors (~12 cm) | Fine Science Tools | 14054-13 | |
Medium curved or straight rongeurs (14-16 cm) or skull bone removal pliers | Fine Science Tools | 16020-14 | |
Straight iris scissors (~9 cm) | Fine Science Tools | 14058-11 | |
Micro-spatula (double 2″ flat ends, one rounded, one tapered to 1/8″) | Fine Science Tools | 10091-12 | |
Post-Fixation & Storage: | |||
50 ml glass vial | |||
40 ml HEPES-Buffered Hanks Solution (HBHS) with sodium azide (90mg/l) |