Electrophysiology on Isolated Brainstem-spinal Cord Preparations from Newborn Rodents Allows Neural Respiratory Network Output Recording

Podsumowanie

The central respiratory drive is located in the brainstem. Spontaneous respiratory motor output from an isolated brainstem-spinal cord is recorded by placing an electrode on the fourth ventral root. This experimental approach is valuable for pharmacological investigations or the assessment of respiratory challenges and genetic manipulations on rhythmic motor behavior.

Streszczenie

While it is well known that the central respiratory drive is located in the brainstem, several aspects of its basic function, development, and response to stimuli remain to be fully understood. To overcome the difficulty of accessing the brainstem in the whole animal, isolation of the brainstem and part of the spinal cord is performed. This preparation is maintained in artificial cerebro-spinal fluid where gases, concentrations, and temperature are controlled and monitored. The output signal from the respiratory network is recorded by a suction electrode placed on the fourth ventral root. In this manner, stimuli can be directly applied onto the brainstem, and the effect can be recorded directly. The signal recorded is linked to the inspiratory signal sent to the diaphragm via the phrenic nerve, and can be described as bursts (around 8 bursts per minute). Analysis of these bursts (frequency, amplitude, length, and area under the curve) allows precise characterization of the stimulus effect on the respiratory network. The main limitation of this method is the viability of the preparation beyond the early post-natal stages. Thus, this method greatly focuses on the study of the whole network without the peripheral inputs in the newborn rat.

Wprowadzenie

Breathing is a complex and vital activity controlled by the brain, allowing dioxygen (O₂) uptake and carbon dioxide (CO₂) elimination. The central respiratory drive is generated by a complex network located in the brainstem in both mammals ¹, amphibians ², reptiles ³, birds ⁴ and fishes ⁵. Even if the study of breathing can be processed in vivo, precise mechanistic investigations require direct access to the respiratory control network. To this end, Adrian and Buytendijk developed a reduced goldfish preparation, in which electrodes placed on the brainstem surface record the generated rhythm associated with gill ventilation ⁵. This approach was subsequently adapted by Suzue in 1984 ⁶ for use in newborn rodents. The advent of this preparation has led to significant advances in respiratory neurobiology. Since it is relatively simple, the technique presented here is amenable to a broad range of basic investigations of rhythmic motor behaviors and their origins in newborn rodents.

The overall goal of this method is to record the neural correlate of inspiratory activity, a respiratory-like rhythm called fictive breathing, produced by the respiratory network. This method can be employed in a wide range of research objectives, targeting inspiratory responses to respiratory variations or pharmacology in both wild type ⁷ and transgenic ⁸ animals. Given that experiments are performed at a low temperature, without sensory afferents, and under conditions where the concentrations of glucose and O₂ within the aCSF are high, questions have been raised regarding the physiological relevance of the signal recorded. While there are clear differences between in vivo and in vitro conditions (e.g., the frequency of inspiratory bursts) the fact remains that the presence of the core elements of the respiratory network ⁶ make it possible to study a robust rhythm associated to a vital homeostatic function ^9,10.

The rationale behind the development and the use of this technique is to facilitate direct access to the brainstem elements of the respiratory network, which are hardly accessible in vivo, especially in newborns. The brainstem is placed under strictly controlled conditions: the recorded rhythm is not modulated by peripheral afferent inputs from the lungs or the carotid bodies, allowing the study to focus on the central respiratory drive itself ¹¹. Thus, this access is utilized to apply stimuli and record the output signal. In contrast to plethysmography recordings, the respiratory rhythm is modulated by all of its components throughout the body (e.g., lung distension, peripheral chemosensors), making it difficult to apply precise stimuli.

In a newborn rat, the protocol consists of recording the fourth ventral root signal on an isolated brainstem and a truncated spinal cord, maintained in artificial cerebro-spinal fluid (aCSF). The rhythm generated by brainstem-spinal cord preparations is composed of individual slow bursts that are linked to the inspiratory signal ⁹. Isolated brainstem-spinal cord preparations are easily recordable in rats from post-natal day 0 to 4 (P0 - P4) ⁷. This approach is commonly used to evaluate the hypoxic response of the respiratory network, and also the response to hypercapnia, acidosis or drugs. An acute hypoxia protocol is presented here. This stimulation is obtained by withdrawal of O₂ in the aCSF; this approach is commonly used to assess the tolerance and responsiveness to hypoxic insults. The protocol induces a rhythm depression from the first minute until the end of the hypoxia exposure (Figure 1)¹². This depression is reversed during post-hypoxic recovery ¹². Concerning the experimental design, it is important to notice that the pons, located at the rostral part of the brainstem, has an inhibitory action on the rhythm generator ⁸. Thus, preparations of full brainstem and rostral spinal cord display a lower rhythm. Inclusion of the pons in the isolated sample for the recording is determined according to the goal of the experiment ¹³; the study of pontine influence on the medulla oblongata network would require recordings with and without the pons to compare the results ¹⁴. Moreover, one of the advantages of this technique is the possibility of extending the rostral part of the preparation to include mesencephalic and/or diencephalic regions ^15,16, making it possible to assess the effect of these regions on the ponto-medullary respiratory network.

Protokół

This method required the use of animal subjects, allowed by Laval University Animal Ethics Committee (protocol # 2012-170).

1. Setup and Preparation

1. Solutions
   1. Prepare aCSF stock solutions according to the following recipes ^7,17. Other recipes with concentration variations are available in the literature. Store stock solutions at 4 °C for up to one month.
      1. Salt solution: add 75.39 g of NaCl (129 mM final); 2.5 g of KCl (3.35 mM final); 0.81 g of NaH2PO4 (0.58 mM final); 2.33 g of MgCl2 (1.15 mM final); 1.85 g of CaCl2 (1.26 mM). Dissolve in 800 ml of distilled water then fill to 1 L with distillated water.
      2. Bicarbonate solution: add 17.65 g of NaHCO₃ (21 mM final). Dissolve in 900 ml of distillated water then fill to 1 L with distilled water. Variations of the bicarbonate concentration will result in pH variations.
      3. Glucose solution: add 54.06 g of glucose (30 mM final). Dissolve in 400 ml of distillated water then fill to 500 ml with distilled water.
   2. Prepare aCSF by diluting 100 ml of salt solution, 100 ml of bicarbonate solution, and 50 ml of glucose solution in 1 L of distilled water. Store at 4 °C until use.
   3. Prepare a glass electrode by warming and stretching a glass tube until it breaks. Sand down the tip before use. The electrode can be reused many time as long as it stays clean.
2. Experimental Setup
   Note: The set-up details are presented in Figure 2.
   1. Turn on the amplifier, moving averager, data acquisition system, temperature controller and pump. Check the signal amplification (gain = 10,000), the filtration (low threshold, 10 Hz; high threshold, 5 kHz), and the sampling rate of the analog to digital conversion of the raw signal (2.5 kHz).
   2. Fill a bottle with aCSF and bubble it with carbogen (95% O₂, 5% CO₂). Induce a bubbled- and warmed-aCSF flow in the recording chamber (volume 5 ml) at 4 ml/min. Hold the temperature in the recording chamber at 26 (± 1) °C. pH should be 7.4 in these standard conditions.
   3. Keep 50 ml of RT and carbogen-bubbled aCSF in a 50 ml syringe near the dissection chamber.
   4. Turn on the computer and start the recording software.

2. Dissection

1. Weigh and visually determine the sex of the animal (males have a longer ano-genital distance, while females have a short ano-genital distance; males genitals are often dark while female genitals are pink).
2. Anesthetize the newborn rodents by one of the following options: cryoanesthesia (completely immerse the animal in ice for 4 – 5 min ¹⁸), injection (equitensine at 4 ml/kg) ¹⁹ or inhalation of volatile anesthetics (isoflurane ²⁰ or ether ²¹). Confirm an adequate plane of anesthesia by the absence of a paw withdrawal reflex.
3. Place the animal on the bench, ventral face down. Section the rostral part of the head coronally with a scalpel at the bregma level (visible through the skin and skull). Perform this step immediately after the animal is anesthetized.
4. Section the body coronally with a scalpel under the anterior members .
5. Remove skin, muscles, fatty tissues and viscus with surgical and thin scissors and pliers. Since bones are soft at this age, be cautious to not damage the nervous system. Perform this step on the bench.
6. Place the preparation in the dissection chamber. Use the aCSF stored in the syringe to oxygenate the preparation. From this point to the end of the recording, use a microscope.
7. On the dorsal face of the preparation, cut the skull and vertebras from the rostral to the caudal part along the medium axis with surgical and thin scissors and pliers. Open the cut skull and vertebras in order to expose the nervous tissue. Use the aCSF strored in the syringe to oxygenate the preparation.
8. With the pliers, remove the Arachnoid membrane, a thin tissue covering the surface of the nervous tissue. Retain the pia mater and blood vessels against the nervous tissue. Use the aCSF stored in the syringe to oxygenate the preparation.
9. Place the preparation with the dorsal face down, and carefully bring down the brainstem and spinal cord by cutting the nerves and connective tissue with the scissors while holding the preparation in place. A dorsal approach is also possible. Keep the roots and nerves as long as possible. Remove the bones to isolate the brainstem and spinal cord. Use the aCSF stored in the syringe to oxygenate the preparation.
10. Remove the cerebellum and remaining rostral structures by sectioning them with the scalpel. Use the aCSF stored in the needle to oxygenate the preparation.
11. Optionally depending on experimental design, remove the pons with the scalpel by a coronal section anterior to the inferior cerebellar artery ²². Note that keeping the whole pons will slow down the rhythm in rats and fully inhibit it in mice. Preparations that include only the caudal part of the pons display a respiratory-like activity with a stable frequency at the C4 root.

3. Recording

1. Place the preparation in the recording chamber, ventral face up. Fix the preparation with pins in the lowest part of the spinal cord and rostral-most part of the brainstem.
2. Using a syringe linked to the electrode by its needle, induce a depression in the electrode (glass tip diameter: 150 - 225 µm) by pulling out the syringe piston, in order to partially fill the electrode with aCSF.
3. Using a micromanipulator, carefully place the electrode close to one of the fourth ventral roots. Other ventral roots could also present a respiratory-like activity (e.g., XII cranial nerve, C1 ventral root).
4. Induce a depression in the electrode tank via the syringe by pulling out the piston in order to gently aspirate the nerve rootlet. Then carefully move the electrode to apply it against the spinal cord.
   Note: Ideally the size of the rootlet matches the size of the electrode opening and thus creates a seal between the internal and external compartments of the electrode. Since differential amplifiers are commonly used for such recordings, any opening between the inside of the electrode and the recording chamber reduces the quality of the signal and makes it difficult to eliminate background noise.
5. Start the recording.
6. Record the rhythm produced by the preparation under normoxic conditions (i.e., aCSF bubbled with carbogen: 95% O₂ and 5% CO₂) for at least 20 min to determine the baseline parameters of the preparation.
7. Switch the perfusion from carbogen-bubbled aCSF to stimulus aCSF (i.e., bubbled with 95% N₂ and 5% CO₂ for hypoxia stimulus) for 15 min. Alter exposure duration depending of the experimental protocol. Record the exposure duration on the recording and animal datasheet. Use stainless steel tubes between the aCSF bottle and the chamber whenever possible to avoid gas diffusion to the outside of the tube.
8. Switch the perfusion back to standard carbogen-bubbled aCSF for at least 15 min for a recovery recording. Record this on the recording and animal datasheet.
9. End the recording.

4. Statistical Analysis

1. From the integrated signal, calculate the frequency as the number of bursts per minute (expressed in bursts/min), the amplitude as the difference between the baseline and the peak of the burst (expressed in mV), the burst duration as the duration from the beginning to the end of the burst (expressed in s), the burst area as the area under the curve of the burst on the integrated signal (expressed in mV·s) (Figure 3).
2. Calculate the frequency, amplitude, burst duration and burst area under normoxic (baseline), hypoxic (stimulus) and post-hypoxic (post-stimulus) recovery conditions as the average of the last 5 min of the recordings for each condition. Do not analyze the first portion of each condition because there is a delay between switching the perfusion and aCSF homogenization in the recording chamber.
3. Express then stimulus (i.e., hypoxia) and post-stimulus (i.e., post-hypoxic) recovery values as a percentage of the baseline values for the corresponding recording. Express the results as means ± S.D.

Wyniki

As mentioned in the introduction, one of the most important advantages of this technique is the direct access to the brainstem to apply various stimuli. As an example, hypoxia was applied here. Figure 1.A.B. displays a full protocol recording, with both normoxic and hypoxic conditions. Figure 1.C.E. displays the rhythm recorded in normoxic conditions (i.e., aCSF bubbled with 95% O₂ and 5% CO₂ at 26 °C). As previously demonstrated in th...

Dyskusje

Accurate quantification of respiratory activity can be challenging. Indeed, breathing is a function that can be both automatic and voluntary, and that is modulated according to the environment, the body’s needs, the emotional state and the behavior. The advantage of this technique is the isolation of the neural elements responsible for producing the respiratory command. Thus, electrophysiological recordings of brainstem-spinal cord preparations and plethysmography are complementary techniques to study the whole neu...

Materiały

Name	Company	Catalog Number	Comments
Sylgard	Sigma Aldrich	761036-5EA	Use under hood
NaCl	Bioshop	SOD002
KCl	Bioshop	POC888
CaCl2	Bioshop	CCL444
MgCl2	Bioshop	MAG510
NaHCO3	Bioshop	SOB999
NaH2PO4	Bioshop	SPM306
D-glucose	Bioshop	GLU501
Carbogen	Linde	343-02-0006
Temperature Controller	Warner Instruments, Hamden, CT, USA	TC-324B
Suction electrode	A-M Systems, Everett, WA, USA	model 573000
Differential AC amplifier	A-M Systems, Everett, WA, USA	model 1700
Moving averager	CWE, Ardmore, PA, USA	model MA-821
Data acquisition system	Dataq Instruments, Akron, OH, USA	model DI-720
LabChart software	ADInstruments, Colorado Springs, CO, USA
Prism sofware	Graphpad, La Jolla, CA, USA
Dissection chamber	Plastic box (e.g. petri box) will do
Recording chamber	Home made
Base	Kanetec, Bensenville, IL, USA	MB
Micromanipulator	World Precision Instrument Inc, Sarasota, FL, USA	KITE-R
Base	Kanetec, Bensenville, IL, USA	MB
Peristaltic pump	Gilson, Middleton, WI, USA	MINIPULS 3
Faraday Cage	Home made
Computer