Epidural and Spinal Anesthesia



B. Ligaments


1. The vertebral bodies are stabilized by five ligaments that increase in size between the cervical and lumbar vertebrae (see Fig. 34-1).


2. The ligamentum flavum is thickest in the midline (3–5 mm at L2–L3) and also farthest from the spinal meninges in the midline (4–6 mm at L2–L3). As a result, midline insertion of an epidural needle is least likely to result in accidental meningeal puncture.



TABLE 34-1 LANDMARKS FOR VERTEBRAL INTERSPACES



C. Epidural Space


1. The epidural space lies between the spinal meninges and the sides of the vertebral canal. It is bounded cranially by the foramen magnum, caudally by the sacrococcygeal ligament (sacral hiatus), and posteriorly by the ligamentum flavum and vertebral pedicles.


2. The epidural space is not a closed space but communicates with the paravertebral space via the intervertebral foramina.


3. The epidural space is composed of a series of discontinuous compartments, which become continuous when the potential space separating the compartments is opened up by injection of air or liquid.


4. The most ubiquitous material in the epidural space is fat.


5. Veins are present principally in the anterior and lateral portions of the epidural space with few, if any, veins present in the posterior epidural space (see Fig. 34-1). These veins anastomose freely with extradural veins (pelvic veins, azygous system, intracranial veins).


D. Epidural fat has important effects on the pharmacology of epidurally and intrathecally administered opioids and local anesthetics.


1. Lipid solubility results in opioid sequestration in epidural fat with associated decreases in bioavailability.


2. Transfer of opioids from the epidural space to the intrathecal space is greatest with poorly lipid-soluble morphine and least for the highly lipid-soluble opioids fentanyl and sufentanil.


E. Meninges


1. Dura mater is the outermost and thickest meningeal tissue that begins at the foramen magnum (fuses with the periosteum of the skull, forming the cephalad border of the epidural space) and ends at approximately S2, where it fuses with the filum terminale. The dura mater extends laterally along the spinal nerve roots and becomes continuous with the connective tissue of the epineurium at approximately the level of the intervertebral foramina.


a. The inner edge of the dura mater is highly vascular, which likely results in the dura mater being an important route of drug clearance from both the epidural and subarachnoid space.


b. The presence of a midline connective tissue band (plica mediana dorsalis) running from the dura mater to the ligamentum flavum is controversial but may be invoked as an explanation for unilateral epidural block.


c. The subdural space is a potential space between the dura mater and arachnoid mater. Drug intended for either the epidural space or the subarachnoid space may be accidentally injected into this space.


2. Arachnoid Mater


a. The arachnoid mater is an avascular membrane that serves as the principal physiologic barrier for drugs moving between the epidural space and the subarachnoid space.


b. The subarachnoid space lies between the arachnoid mater and pia mater and contains cerebrospinal fluid (CSF). The spinal CSF is in continuity with the cranial CSF and provides an avenue for drugs in the spinal CSF to reach the brain. Spinal nerve roots and rootlets run in the subarachnoid space.


3. Pia mater is adherent to the spinal cord.


4. CSF (100–160 mL in adults, produced at a rate of 20–25 mL/hr) is replaced roughly every 6 hours (removed by arachnoid villi).


a. Contrary to a widely held view, CSF does not circulate through the subarachnoid space but rather oscillates in parallel with cerebral expansion and contraction during the cardiac cycle. (Net CSF movement is estimated to be 0.04% per oscillation.)


b. CSF cannot be relied on to distribute drugs in the subarachnoid space.


c. The kinetic energy of the injection and baricity of the solution serve to distribute drug during a single-shot spinal.


d. The lack of significant net CSF motion explains why drug distribution during slow infusions used for chronic intrathecal analgesia results in limited drug distribution.


F. Spinal Cord


1. In adults, the caudad tip of the spinal cord typically ends at the level of L1 (extends to L3 in 10% of adults).


2. The spinal cord gives rise to 31 pairs of spinal nerves, each composed of an anterior motor root and a posterior sensory root.


a. Dermatome is the skin area innervated by a given spinal nerve (Fig. 34-2).


b. The intermediolateral gray matter of T1 to L12 contains the cell bodies of the preganglionic sympathetic neurons. These sympathetic neurons travel with the corresponding spinal nerve to a point just beyond the intervertebral foramen, where they exit to join the sympathetic chain ganglia.


c. Because the spinal cord ends between L1 and L2, the thoracic, lumbar, and sacral nerve roots travel increasingly longer distances in the subarachnoid space (cauda equina) to reach the intervertebral foramen through which they exit.



FIGURE 34-2. Human sensory dermatomes.



II. TECHNIQUE. Spinal and epidural anesthesia should be performed only after appropriate monitors are applied in a setting in which equipment for airway management and resuscitation is immediately available.


A. Needles


1. Spinal and epidural needles are named for the design of their tips (“pencil point,” beveled tip with cutting edge) (Fig. 34-3).



FIGURE 34-3. Examples of commercially available spinal and epidural needles. Needles are distinguished by the design of their tips.



a. Epidural needles have a larger diameter than spinal needles, facilitating injection of air or fluid for the “loss of resistance” technique and passage of catheters.


b. The outside diameters of spinal and epidural needles are used to determine their gauges. Large-gauge spinal needles (22–29 gauge) are often easier to insert if an introducer (inserted into the interspinous ligament) is used. Postdural puncture headache (PDPH) is less likely when small-gauge spinal needles are used.


2. All spinal and epidural needles come with a tight-fitting stylet to prevent the needle from becoming plugged with skin or fat.


B. Sedation before placement of the block is limited because patient cooperation (positioning, determination of level of sensory anesthesia, occurrence of paresthesias) is important. After the anesthesia is established, the patient may be sedated as deemed appropriate.


III. SPINAL ANESTHESIA


A. Position (Table 34-2)


1. In the lateral decubitus position, the patient lies with the operative side down when hyperbaric solutions are being used. The patient’s shoulders and hips are positioned perpendicular to the bed (preventing rotation of the spine), the knees are drawn up to the chest, the neck is flexed, and the patient is asked to actively curve the back outward (which spreads apart the spinous processes).


2. Using the iliac crests as landmarks, the L2 to L3, L3 to L4, and L4 to L5 interspaces are identified and the desired interspace chosen.


3. All antiseptic solutions are neurotoxic, and care must be taken not to contaminate spinal needles and local anesthetics. Chlorhexidine–alcohol antiseptic prevents colonization of percutaneous catheters better than 10% povidone–iodine and is the recommended prep for skin asepsis before regional anesthesia procedures.



TABLE 34-2 PATIENT POSITION FOR PERFORMANCE OF SPINAL ANESTHESIA


Lateral Decubitus


Sitting


Easier to identify the midline in obese patients


Facilitates restriction of block to sacral segments


Prone (Jackknife)


Consider when surgery is to be performed in this position


Hypobaric solution produces sacral block for perirectal surgery


B. Midline Approach


1. After infiltration of the selected needle insertion site with local anesthetic solution, the needle is advanced (subcutaneous tissue to supraspinous ligament to interspinous ligament to ligamentum flavum to epidural space to dura mater [“pop”] to arachnoid mater) until CSF is obtained (gentle aspiration may be helpful). The spinal meninges are typically at a depth of 4 to 6 cm.


2. If bone is encountered, the depth should be noted and the needle withdrawn to subcutaneous tissue and redirected more cephalad (Fig. 34-4).


3. If the patient experiences paresthesia (which should be differentiated from discomfort caused by contacting bone), it is important to immediately stop advancing the needle and determine whether the needle tip has encountered a nerve root in the epidural space or in the subarachnoid space. (The presence of CSF confirms that the needle has encountered a cauda equina nerve root.)



FIGURE 34-4. Midline approach to the subarachnoid space. The spinal needle is inserted with a slight cephalad angulation and advanced in the midline (B). If bone is contacted, it may be either the caudad (A) or cephalad (C) spinous process. The needle should be redirected slightly, and if bone is encountered at a shallower depth, then the needle is likely walking up the cephalad spinous process. If bone is encountered at a deeper depth, then the needle is likely walking down the inferior spinous process. If bone is repeatedly contacted at the same depth, then the needle is likely off the midline and walking along the lamina.



4. After completing the injection of local anesthetic solution, a small volume of CSF is again aspirated to confirm that the needle tip has remained in the subarachnoid space.


5. After the block has been placed, strict attention must be directed to the patient’s hemodynamic status with blood pressure and heart rate supported as necessary.


6. The level of anesthesia should be assessed by pinprick or temperature sensation. If the anesthesia is not rising high enough, the table may be tilted to influence spread of a hyperbaric or hypobaric local anesthetic.


C. The paramedian approach is used when the patient cannot flex the spine or heavily calcified interspinous ligaments. The needle is inserted 1 cm lateral to the desired interspace with advancement toward the midline. (The first significant resistance is the ligamentum flavum as the interspinous ligament is bypassed.)


D. The lumbosacral approach is a paramedian approach directed at the L5 to S1 interspace.


IV. CONTINUOUS SPINAL ANESTHESIA


A. The technique is similar to that used for single-shot spinal anesthesia except that a needle large enough to accommodate the desired catheter must be inserted. (The catheter is inserted 2 to 3 cm into the subarachnoid space.)


B. Although smaller catheters decrease the risk of PDPH, they have been associated with reports of neurologic injury. (The recommendation is to avoid using a catheter smaller than 24 gauge.)


V. EPIDURAL ANESTHESIA


A. Patient preparation and positioning, the use of monitors, and the needle approaches for epidural anesthesia are the same as for spinal anesthesia. However, unlike spinal anesthesia, epidural anesthesia may be performed at any intervertebral space.


1. Using the midline approach, the epidural needle is inserted into the interspinous ligament (“gritty” feel) and then advanced slowly until the ligamentum flavum is contacted (increased resistance).


2. The epidural needle must traverse the ligamentum flavum and stop in the epidural space (“loss of resistance”) before encountering the spinal meninges.


a. A glass syringe containing 2 to 3 mL of saline and 0.1 to 0.3 mL of air is attached to the epidural needle, and the plunger is pressed. If the needle is properly placed in the ligamentum flavum, it will be possible to compress the air bubble without injecting the saline. If the air bubble cannot be compressed without injecting fluid, then the needle tip is most likely not in the ligamentum flavum but instead in the interspinous ligament or off midline in the paraspinous muscles.


b. After the ligamentum flavum is identified, the needle is slowly advanced with the nondominant hand while the dominant hand maintains constant pressure on the syringe plunger (Fig. 34-5).


c. As the needle enters the epidural space, there will be a sudden and dramatic loss of resistance as the saline is rapidly injected. (The patient should be warned of possible pain.) If the needle is advancing obliquely through the ligamentum flavum, it is possible to enter into the paraspinous muscles instead of the epidural space. (Loss of resistance is less dramatic.)



FIGURE 34-5. Proper hand position when using the loss of resistance technique to locate the epidural space. After placing the tip of the needle in the ligamentum flavum, a syringe containing 2 to 3 mL of saline and an air bubble is attached. The dominant hand maintains constant pressure on the syringe plunger while the nondominant hand rests against the patient’s back and is used to slowly advance the needle. If the needle is properly placed in the ligamentum flavum, it will be possible to compress the air bubble without injecting the saline. As the needle tip enters the epidural space, there will be a sudden loss of resistance, and the saline will be easily ejected from the syringe.



d. When the syringe is disconnected from the needle, it is common to have a small amount of fluid flow from the needle hub (usually saline, which is at room temperature in contrast to CSF).


3. A test dose of local anesthetic solution is injected to help detect unrecognized intravenous (IV) or subarachnoid placement of the needle. After a negative test dose, the desired volume of local anesthetic solution should be administered in 5-mL increments. (This decreases the risk of pain during injection and allows early detection of adverse reactions.)


VI. CONTINUOUS EPIDURAL ANESTHESIA


A. Use of a catheter for epidural anesthesia affords greater flexibility than the single-shot technique but introduces the risk of catheter migration (subarachnoid space, intervertebral foramen) and increases the likelihood of a unilateral epidural block.


B. Epidural catheters are usually inserted through a curved-tip needle to help direct the catheter away from the dura mater. The catheter typically encounters resistance as it reaches the curve of the needle, but using steady pressure usually results in its passage into the epidural space. One explanation for the inability to thread an epidural catheter is that the tip of the epidural needle was bent during bony contact and now partially occludes the needle lumen.


1. The catheter should be advanced only 3 to 5 cm into the epidural space. This minimizes the risk of forming a knot, entering a vein, puncturing dura mater, exiting via an intervertebral foramen, and wrapping around a nerve root.


2. After the catheter is appropriately positioned, the needle is slowly withdrawn with one hand as the catheter is stabilized with the other. The length of the catheter in the epidural space is confirmed because this distance is important when trying to determine if a catheter used in the postoperative period has been dislodged.


3. A test dose of the local anesthetic solution is injected before the initial injection and any subsequent “top-up dose” (typically 50% of the initial dose at an interval equal to two thirds the expected duration of the block).


VII. EPIDURAL TEST DOSE


A. The most common test dose is 3 mL of local anesthetic solution containing 5 μg/mL of epinephrine (1:200,000).


1. This dose is sufficient to produce evidence of spinal anesthesia if accidental subarachnoid injection occurs.


2. IV injection of the epinephrine dose typically increases the heart rate an average of 30 beats per minute.


a. Reflex bradycardia may occur in patients being treated with α-blockers. (A increase in systolic blood pressure of 20 mm Hg or more may be a more reliable indicator of intravascular injection in these patients.)


b. The sensitivity of epinephrine as a test dose in parturients is questionable because maternal heart rate increases during contractions are often as large as those produced by epinephrine.


B. Aspirating the catheter or needle to check for blood or CSF is helpful if positive, but the incidence of false-negative aspirations is too high to rely on this technique alone.


VIII. COMBINED SPINAL–EPIDURAL ANESTHESIA


A. This technique combines the rapid onset and dense block of spinal anesthesia with the flexibility afforded by an epidural catheter.


B. After the peak spinal block height has been established, the injection of saline or a local anesthetic solution into the epidural space causes the block height to increase, presumably reflecting compression of the spinal meninges forcing CSF cephalad as well as a local anesthetic effect.


C. A potential risk of this technique is that the meningeal hole made by the spinal needle may allow high concentrations of subsequently administered epidural drugs to reach the subarachnoid space.


IX. PHARMACOLOGY. Interindividual variability makes it difficult to reliably predict the height and duration of central neuraxial block that will result from a particular local anesthetic dose (Table 34-3).


A. Spinal Anesthesia


1. Block Height (Table 34-4)


a. Baricity and Patient Position. Of the factors that exert significant influence on local anesthetic spread, the baricity of the local anesthetic solution relative to patient position is probably the most important.



TABLE 34-3 REPRESENTATIVE SURGICAL PROCEDURES APPROPRIATE FOR SPINAL ANESTHESIA


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Sep 11, 2016 | Posted by in ANESTHESIA | Comments Off on Epidural and Spinal Anesthesia

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