Perioperative Acupuncture and Related Techniques
Chernyak, Grigory V. M.D.*; Sessler, Daniel I. M.D.†
Section Editor(s): Warltier, David C. M.D., Ph.D., Editor
Acupuncture and related techniques are increasingly practiced in conventional medical settings, and the number of patients willing to use these techniques is increasing. Despite more than 30 yr of research, the exact mechanism of action and efficacy of acupuncture have not been established. Furthermore, most aspects of acupuncture have yet to be adequately tested. Therefore, considerable controversy remains about the role of acupuncture in clinical medicine. Acupuncture apparently does not reduce volatile anesthetic requirement by a clinically important amount. However, preoperative sedation seems to be a promising application of acupuncture in perioperative settings. Acupuncture may be effective for postoperative pain relief but requires a high level of expertise by the acupuncture practitioner. Acupuncture and related techniques can be used for treatment and prophylaxis of postoperative nausea and vomiting in routine clinical practice in combination with or as an alternative to conventional antiemetics when administered before induction of general anesthesia.
ACUPUNCTURE is an integral part of an ancient Chinese system of medicine that has been used for more than 2,500 yr to treat diseases and relieve pain. According to tradition, the practice of acupuncture is based on a philosophy of balance and unity between the universe, living beings, and energy flow that penetrates everywhere and everything. Any imbalance, disruption, or energy-flow blockage within the body can cause disease or pain. The main concept and philosophy of acupuncture is to return the body to a harmonized, balanced state.
There are numerous techniques and approaches to acupuncture, reflecting a variety of medical traditions and schools from China, Korea, Japan, Vietnam, and other countries. Some of these approaches focus on points located on traditional acupuncture meridians that crisscross the body surface. Other methods focus on points located on the ear (auricular acupuncture) or hands or feet (Korean hand acupuncture, Su-Jok acupuncture). In general, it is believed that the ears, hands, and feet are micromodels of the entire body with areas that represent the body parts, organs, meridians, and acupuncture points. These micromodels have the same principles of energy flow as the whole body. An explanation of this phenomenon is a principle of the fractalization (similarity) of living and nonliving things in which small parts have the same shape as the whole.1
No matter what method of acupuncture is used, it is necessary to apply acupuncture to specific points to achieve analgesia or other beneficial regional or systemic effects.
The origins of Chinese medicine are shrouded in legend and obscured by the Chinese propensity for the veneration of their ancestors. The two most famous medical treatises, on which the cornerstones of all traditional Chinese medicine rest, are credited to two legendary emperor-gods—Shen Nung and Huan Di—who are said to have ruled between 3737 and 2597 BC. The Pen Ts’ao, the pharmacopoeia that forms the basis of traditional herbal medicine in China, is credited to Shen Nung. However, this book most likely appeared during the Han dynasty, between 206 BC and 200 AD. A revised version is still used by traditional doctors in China. The most famous of all writings on Chinese medicine, The Yellow Emperor’s Classic of Internal Medicine, is credited to Huan Di. It was, in fact, probably written during the fourth or third century BC, and over the centuries, it was revised several times. Its current form was written in 762 AD during the Tan dynasty. It is interesting to note that the acupuncture section of this book does not present the rudiments of the technique but rather certain refinements of its application. This suggests that acupuncture was already well developed by the time this book was written.
Modern research on the basic mechanism of acupuncture started after the People’s Republic of China was founded in 1949, and Mao Zedong encouraged the practice of acupuncture in the country. Ten years later, acupuncture was introduced in the former Soviet Union, where research work was initiated. These results remained essentially unknown to most Western scientists and physicians. This typically reflects a failure to publish articles in English—along with a lack of interest in the Western research community.2
There was a surge of interest in acupuncture in the United States after President Nixon’s visit to China in 1971. This resulted in part because James Reston, a New York Times
reporter, was in China covering President Nixon’s trip when he developed acute appendicitis. His postoperative pain was treated with acupuncture. He described his experience on the front page of The New York Times
, and interest in acupuncture exploded.3
Subsequently, American and European physicians visiting China witnessed surgeries being performed with acupuncture as the only anesthetic. An enormous number of articles in newspapers and magazines about the use of acupuncture in anesthesia followed. Serious fundamental research on acupuncture started only in 1976 after the endorphin hypothesis of acupuncture’s mechanism of action was introduced. Further development of acupuncture research was prompted by introduction of magnetic resonance imaging (MRI) and positron emission tomographic scanning, which revealed the relation between acupuncture stimulation and activation of certain brain structures.4–8
Today, a critical mass of scientific work about the mechanism of action of acupuncture has accumulated. Interest in the United States is so great that the National Institutes of Health has funded dozens of experimental and clinical acupuncture studies.
The World Health Organization issued a list of medical conditions that may benefit from treatment with acupuncture. Such applications include prevention and treatment of postoperative and chemotherapy-induced nausea and vomiting, treatment of pain, alcohol and other drug addiction therapy, treatment of asthma and bronchitis, and rehabilitation from neurologic damage such as that caused by stroke.9
As a result of all these activities, the US Food and Drug Administration removed acupuncture needles from the category of “experimental medical devices” and now regulates them like other medical devices.9
Skepticism about acupuncture nonetheless remains high among medical professionals in the United States. Contributing to this skepticism are the facts that the scientific basis of acupuncture remains unclear, the philosophical basis of acupuncture is difficult for a modern industrial society to accept, the operational language is unusual, and the traditional system of acupuncture points does not correspond to Western concepts of anatomy or neurology. Moreover, acupuncture remains a bit more of an art than a science because many factors that can profoundly influence the outcome of the treatment have to be considered. In addition to the symptoms of the disease, a practitioner might consider the patient’s sex,10
the psychologic constitution of the patient,11
the season, the time of the day,12
and even the location in which treatment is administered.13–15
The result is that the efficacy of interventions may differ substantially in patients with similar symptoms. Such variations make it difficult to standardize procedures and hamper acupuncture clinical research. Another problem associated with acupuncture research is defining an adequate placebo as a control intervention for acupuncture studies. Some trials compare acupuncture to drugs and others use “sham acupuncture” (acupuncture at random spots on the body surface that are thought to be inactive). There is substantial controversy, however, about the use of sham acupuncture as a control treatment.16
Results from studies using sham acupuncture are difficult to interpret because the procedure itself can provide neurohormonal and clinical effects (fig. 1
Despite much skepticism, approximately half of physicians believe that acupuncture is efficacious. It has a higher rate of physician referral than other complementary therapies such as chiropractic, massage, homeopathy, or herbal therapy.17
There has been a stable and substantial increase in the use of and expenditures on alternative medicine, including acupuncture. This use is distributed widely across all sociodemographic groups; however, a greater fraction of women (49%) than men (38%) have used alternative therapies. African-Americans (33%) use alternative therapies less commonly than other racial groups (44%). Interestingly, people aged 35–49 yr report greater use than younger or older people. Use is also greater among those with college educations and annual incomes exceeding $50,000/yr.18
In one study, more than half of surgery patients surveyed preoperatively had a favorable attitude toward the use of complementary and alternative medicine. Forty-two percent expressed an interest in integrating acupuncture as a treatment modality for preoperative anxiety. Those who had previously used acupuncture were more interested in using acupuncture for preoperative anxiety than those without previous experience (62 vs.
The theory of traditional Chinese medicine, of which acupuncture is just a part, is complex and beyond the scope of this review. Unlike Western biomedical science, traditional Chinese medicine does not make a distinction between physical, mental, and emotional components of life. Moreover, it considers a human being as an integral part of the universe. It is believed that everything within the universe, including humans, obeys the same laws. Therefore, health and disease result from spiritual, mental, physical, and environmental balance or imbalance.
Organs and Meridians.
The theory of traditional Chinese medicine recognizes 12 main acupuncture meridians with corresponding organs in the human body. In addition, eight so-called curious meridians can be distinguished. Most “acupuncture organs” have names similar to organs of Western medicine, but their correlation with physiologic functions and anatomical structures of recognized organs is only approximate. Organs, as seen in ancient Chinese traditions, are functional systems rather than anatomical structures with broader and sometimes peculiar physiologic functions and anatomical representations. For example, two traditional “organs,” namely “triple warmer” and “pericardium” (“heart governor”) do not have distinct anatomical representation at all. All meridians and organs are connected and related to each other directly or indirectly according to various rules and principles:
1. Each organ has a corresponding meridian with acupuncture points located along it.
2. Meridians travel inside the body and on the body’s surface and are connected to each other and organs by a complex network of accessory collaterals.
3. The function of the meridians is to regulate and modify the corresponding organ or group of related organs. It is believed that meridians can control pain along the areas they traverse.
In Chinese acupuncture, points are called xue
, which means “cave” or “hole.”20,21
In Chinese acupuncture tradition and language, the names of points are important and informative. In modern Western acupuncture, Chinese names are rarely used. Instead, the points are numbered and classified with the capital letters of the meridian to which they belong. There are 365 classic points located along the meridians and at least the same number of extrameridian points. The exact location of the points is important because, according to classic theory, even small deviations from the intended location can nullify the response. The relation of acupoints to anatomical landmarks is usually described in terms of the so-called Chinese inch or cun.
Several phenomena can be observed in acupuncture points that help to locate them more precisely:
1. All points are located in a small hollow or depression on the skin surface.
2. Acupuncture points are usually tender compared with the surrounding area. The patient feels slight pain radiating circumferentially for at least a centimeter when the point is pressed.
3. A roughness or stickiness can be appreciated when brushing slightly with the finger.21
4. A specific feeling called the De-Qi sensation is usually felt by the patient, when a needle stimulates the acupuncture point.
A specific sensation called De-Qi
can present as soreness, numbness, warmth, heaviness, or distention around the area where a needle is inserted. Sometimes this sensation radiates along the pathway of the meridian to which the stimulated point belongs. An experienced practitioner also feels tightness and some heaviness in the fingers when the needle hits the point. This effect has been compared with the feeling one gets when “the fish catches the hook.”22
Most practitioners consider the De-Qi phenomenon to be crucial in achieving the effect of acupuncture.22–24
The diameter of acupuncture points varies. The actual size depends on the individual point, the patient’s condition, the time of day, and possibly the season of the year. The depth of the points also varies. The depth depends on the complexion of the patient, skin thickness, location of the point, occupation and lifestyle of the patient, and duration of the disease.21,22
However, most are 3–15 mm below the skin surface.
Each point has a specific function and indication for its use. For example, stimulation of certain acupuncture points distant from the source of pain can provide excellent analgesia, whereas stimulation of inappropriately selected points in close proximity to the source of pain might be ineffective or even aggravate the symptoms. Stimulation of site-specific acupoints usually induces spatially restricted analgesia, although this aspect of acupuncture has yet to be studied in detail. However, Benedetti et al.25
demonstrated that placebo or treatment expectation provides an analgesic response with a highly spatial presentation, which is completely abolished by systemic naloxone administration. These data indicate that this type of analgesic response is mediated by endogenous opioid release but that the effect is regional rather than systemic. It is possible that acupuncture manifests a similar mechanism of action. Li et al.26
demonstrated that acupuncture stimulation of the ipsilateral Huantiao (GB 30) point, which is traditionally thought to be effective for pain in the lower limbs including sciatica pain, significantly inhibits nociceptive responses of spinal dorsal horn neurons evoked by stimulation of the sural nerve in the rat. In contrast, stimulation of the contralateral Huantiao (GB 30) and some other points produce much less, if any, inhibition.
Cho et al.
using functional MRI, demonstrated a correlation between activation of specific areas of the brain and corresponding acupoint stimulation predicted by ancient acupuncture literature. In this study, acupuncture points belonging to the bladder meridian and located on the foot were stimulated. These points are traditionally related to the eyes and visual function. The investigators were able to demonstrate activation or deactivation of signal intensity in the visual cortex. A subsequent study confirmed this finding and demonstrated activation of visual and auditory cortex caused by electroacupuncture stimulation of eye-related points and ear-related points, respectively.8
However, electroacupuncture at sham points also elicited activation in the auditory cortical zone, suggesting that acupuncture-induced activation of medial occipital cortex and superior temporal gyrus may not be an acupoint-specific phenomenon.
Point specificity was also questioned in another functional MRI study by Cho et al.
where meridian and sham acupuncture were both involved in the process of transmission and perception of pain. Meridian acupuncture demonstrated more profound pain control than sham point stimulation, but the effect may not have been entirely point specific (fig. 1
). Point specificity, as stated by traditional acupuncture literature and demonstrated by clinical practice and some experimental studies, is not fully supported by other studies and therefore remains a controversial issue. Only careful systematic research using site-, organ-, and function-specific acupuncture points with carefully selected sham control points will resolve this issue.
The ear is believed to have a close relation with the entire body. Every part of the body has a corresponding zone of representation on the external ear. A reaction often occurs in a corresponding area on the ear when an internal organ or other part of the body is afflicted with an ailment. The nature of ear points remains unclear, and there is no good theory to explain the existence of reactive points on the ears.
Each organ is thought to be represented by a point on the external ear, and this point is usually needled to achieve an analgesic or other effect in this organ or area. The problem, however, is that auricular points have different locations according to different systems.28
For example, French and Chinese auricular acupuncture systems have different mapping. A related problem is the fact that opinions vary with regard to the properties of different ear points. Increased tenderness on pressure, spots of skin discoloration on the ear, or decreased electrical resistance is thought by some to help identify optimal sites for needling.
Mechanisms of Action
Starting in the 1960s, Western-trained Chinese physicians began to study acupuncture analgesia, particularly acupuncture-induced physiologic changes in the central nervous system. This and subsequent research in Western countries resulted in the discovery of the pathways of acupuncture analgesia, receptors, and several types of endogenous opioids involved in the process; hence, a comprehensive hypothesis of acupuncture analgesia was formed. Experimental studies on animals and clinical studies on humans have since identified numerous clinical and physiologic responses to acupuncture stimulation.
Based on a review of hundreds of modern scientific studies on acupuncture analgesia, Pomeranz and Stux2
proposed a comprehensive mechanism of action for acupuncture analgesia. The basis for the theory is that three mechanisms contribute to acupuncture analgesia.
1. Acupuncture needles stimulate type I and type II afferent nerves or A-δ fibers in muscles, all of which send impulses to the anterolateral tract of the spinal cord. At the spinal cord, pain is blocked presynaptically by the release of enkephalin and dynorphin, preventing pain messages from ascending in the spinothalamic tract.
2. Acupuncture stimulates midbrain structures by activating cells in the periaqueductal gray matter and the raphe nucleus. They in turn send descending signals through the dorsolateral tract, causing the release of the monoamines norepinephrine and serotonin in the spinal cord. These neurotransmitters inhibit pain presynaptically and postsynaptically by reducing transmission of signals through the spinothalamic tract.
3. Stimulation in the pituitary–hypothalamic complex provokes systemic release of β endorphin into the bloodstream from the pituitary gland. Its release is accompanied by the release of adrenocorticotropic hormone.
A-δ fibers are activated by pinprick, pressure, thermal manipulation, and high-threshold ergo receptors in muscles. A-δ fibers provide rapid, precisely located perception of noxious stimulation without much affective response. Some of these fibers terminate on the rostral reticular formation and thalamus. From here, they pass forward to the arcuate nucleus of the hypothalamus and on to the prefrontal cortex.24
Myelinated A-δ fibers are considered the most likely candidates for conveying acupuncture stimuli, but other fibers, including unmyelinated C fibers and A-β fibers, may contribute. C fibers, which are ontogenetically older, produce pain described as slow, deep, throbbing, and dull. This sort of pain is often accompanied by a strong affective component. Therefore, noxious stimulation by the C-fiber system leads to a perception of pain that is poorly localized but has considerable affective impact. These fibers primarily make synaptic contacts in substantia gelatinosa in lamina II. Different kinds of fibers are involved in different components of the De-Qi sensation.29
Because different modalities of acupuncture stimulation produce different types of De-Qi sensation, they may trigger diverse brain networks based on the types of afferent input.6
That acupuncture influences regional brain activity was elaborated by Wu et al.
who reported that acupuncture at two major points, Zusanli (ST 36; fig. 2
) and Hegu (LI 4; fig. 3
), activates the hypothalamus and nucleus accumbens on functional MRI imaging and deactivates the rostral part of the anterior cingulate cortex, amygdala, and hippocampal complex. In contrast, control stimulation by superficial needling that did not elicit the De-Chi sensation did not alter regional brain activity. Therefore, acupuncture at major points with strong analgesic properties seems to activate structures of the descending antinociceptive pathway and to deactivate multiple limbic areas subserving pain association.
Other Potential Mechanisms.
Acupuncture not only provokes release of endogenous opioids from central nervous system stores, but may also activate other analgesic mechanisms. For example, acupuncture may relieve pain by modulating the hypothalamic–limbic system.4,8
Biella et al.4
used positron emission tomography scans in healthy volunteers who were not experiencing any pain to evaluate regional cerebral blood flow in response to classic manual acupuncture stimulation of the Zusanli (ST 36) and Qize (LU 5) acupuncture points. They were able to demonstrate activation of the left anterior cingulum, the insulae bilaterally, the cerebellum bilaterally, the left superior frontal gyrus, and the right medial and inferior frontal gyri. Several imaging studies indicate that the same structures are activated by acute and chronic pain.30–33
Placebo acupuncture (needles inserted superficially into nonacupuncture points 1 cm lateral to each acupoint and then immediately extracted) also produced a degree of cerebral activation, but at areas differing from those activated by real acupuncture. Cho et al.27
had similar results (figs. 1 and 4
). All the structures that were activated by acupuncture are also involved in nociceptive processing and play a role in the concept of the “neuromatrix” as proposed by Melzack.34
Biella et al
. proposed that according to this concept, acupuncture can be thought as a conflicting message in the pain neuromatrix, unbalancing it and thus modifying the perception of pain.4
An interesting theory was proposed recently suggesting a potentially important integrative role of connective tissue in the mechanism of action of acupuncture.35
Langevin et al.36
found 80% correspondence between acupuncture points and the location of intramuscular connective tissue planes in postmortem tissue sections. According to this theory, needle manipulations lead to the development of coupling between needle and tissue with subsequent transduction of the mechanical signal to a cellular response that may underlie some of the therapeutic effects of acupuncture both locally and distally. The theory probably does not explain moxibustion, acupressure, laser, and other noninvasive methods of point stimulation.
Acupuncture analgesia leads to development of tolerance, when applied continuously or repeatedly over short time intervals. It would be reasonable to speculate that when acupuncture stimulation releases endogenous opioids to exert an analgesic effect, it also provokes the release of antianalgesic substances. Cholecystokinin is a powerful antagonist of the analgesic effect of acupuncture,37–41
and cholecystokinin antisense RNA increases the analgesic effect induced by acupuncture.41
The majority of the studies have focused on the analgesic effects of acupuncture and the role of endogenous opioids in acupuncture analgesia. However, acupuncture stimulation results in a much broader spectrum of systemic responses, including altering the secretion of neurotransmitters and neurohormones and changing the central and peripheral regulation of blood flow. There are also data suggesting that acupuncture alters immune function24
and accelerates nerve regeneration.42,43
The mechanisms of these physiologic responses remain unclear.
Types of Acupuncture
Acupoint stimulation can be roughly divided into invasive and noninvasive methods. Invasive methods include skin penetration with an acupuncture needle with subsequent manual stimulation of needles, electroacupuncture, or chronic intradermal needle insertion. These methods are considered “dry needle” techniques. Drugs can be injected into acupoints, a technique considered “wet needle” acupuncture. Noninvasive methods include acupressure, transcutaneous electrical stimulation, moxibustion, and application of various stimulating patches and pellets.
Because the theory of acupuncture is based on the concept that diseases are caused by an imbalance of Qi, the goal of needle insertion is, roughly speaking, to disperse excessive Qi or to replenish it. These two goals can be achieved by several means: applying needles of different sizes or lengths, using needles made of different material, changing the direction of needle insertion, selecting different points for stimulation, and so forth. Strong stimulation—a bigger needle, more intense needle manipulation, or directing the tip of the needle against the hypothetical energy flow along the meridian—is believed to disperse the excessive energy, whereas mild stimulation—a smaller needle, gentle and more superficial needle insertion, or directing the needle toward the energy flow—is used to replenish it. Manual stimulation techniques can be altered to provide the desired effect by using strong vertical up-and-down movements, rotational movements, or mild vibrating movements, for example. Practitioners believe that selecting the proper acupuncture maneuvers and appropriate point selections are key to obtaining a satisfactory therapeutic effect. Consistent with this theory, Chen et al.44
demonstrated that different manual needling maneuvers provide different responses on tail-flick latency and vocalization threshold in rats.
Electrical stimulation of acupuncture points was developed as an alternative to manual acupuncture. Electrical stimulation has several advantages in that it (1) is less painful than manual stimulation, (2) requires less practitioner time directly spent with the patient, (3) provides better analgesia,45
and (4) facilitates standardization. Electrostimulation is now the most common type of acupuncture analgesia.46
The De-Qi sensation depends on the type of acupuncture stimulation. Manual stimulation mainly produces soreness, fullness, and distention, whereas electroacupuncture generally produces tingling and numbness. Kong et al.6
report that manual acupuncture manipulations decrease MRI signals, in contrast to electroacupuncture stimulation, which generally increases MRI signal intensity. Both types of stimulation, however, produce analgesia. Therefore, various stimulation modalities seem to trigger different brain networks, depending on how acupoints are stimulated.
Electroacupuncture (electrical stimulation of acupuncture points) with high-frequency (100–200 Hz) stimulation provides rapid-onset analgesia that is not cumulative and cannot be blocked by naloxone. This type of analgesia is probably mediated by norepinephrine, serotonin, and dynorphins.47
In contrast, low-frequency (2–4 Hz) and medium-frequency (15–30 Hz) stimulation produces an analgesic effect that is reversed by naloxone (and therefore presumably mediated by enkephalin and endorphins), has a tendency to accumulate, and lasts at least an hour after treatment ceases.45,47
Antinociception induced by low-frequency stimulation is mediated by both μ- and δ-opioid receptors; high-frequency electroacupuncture stimulation induces antinociception mediated by κ receptors; and medium-frequency (e.g.
, 30 Hz) stimulation induces antinociception mediated by all three opioid receptor types.48
Most modern acupuncture needles are made of stainless steel, although needles made of gold or silver are also available. Gold needles are thought to possess stimulating properties, whereas silver needles are believed to be sedative. Most acupuncture needles are between 1.3 and 12.7 cm in length and range from 26 to 36 gauge in diameter. The tips of the needles are rounded and thus separate fibers rather than cutting tissues. For this reason, even capillary bleeding from an acupuncture site is rare unless a needle accidentally penetrates a vessel. Special needles are available for intradermal use, auricular acupuncture, and hand and foot acupuncture.
Application in Perioperative Care
Perioperative acupuncture and related techniques have been advocated for preoperative sedation, to reduce intraoperative opioid use, and to decrease postoperative pain. There is compelling evidence that acupuncture reduces postoperative nausea and vomiting (PONV). It may also stabilize cardiac function and ameliorate some consequences of anesthesia and surgery.
proposed the theory that diseased organs have a reduced response threshold to stimuli, whereas a considerable stimulus is needed to alter the function of a healthy organ. Therefore, just the small stimulus of an acupuncture needle may cure severe disease, whereas a comparable stimulus normally produces little or no effect on healthy volunteers.49
To some extent then, perioperative acupuncture contradicts a fundamental principle of acupuncture philosophy in that its goal is to achieve an abnormal insensitivity to pain and reduced awareness and concern.
Perioperative acupuncture can be divided into three components: (1) preoperative preparation; (2) intraoperative acupuncture-assisted anesthesia; and (3) postoperative care, which includes postoperative pain control, nausea and vomiting reduction, and normalization of bowel function.
The goals of preoperative preparation with acupuncture are to optimize the physiologic and psychological conditions of the patient, reduce preoperative anxiety, and trigger release of endogenous opioids to enhance analgesia. One way that acupuncture might help preoperative preparation is by producing relaxation and sedation. For example, Ekbom et al.50
demonstrated that although acupuncture did not produce intraoperative and postoperative analgesia for dental surgery, it caused significant relaxation and drowsiness. Ulett et al.45,51
reported that electroacupuncture to classic acupoints is associated with a deep calming effect. Postoperative pain intensity and consumption of postoperative analgesics both correlate with the amount of anxiety patients experience.52,53
Auricular acupuncture seems to be effective for treatment of preoperative anxiety. In two double-blinded, sham-placebo studies, Wang et al.54,55
found that preoperative acupuncture at the “relaxation” point on the ear (fig. 5
) reduced anxiety at up to 48 h postoperatively compared with sham acupuncture. In a prospective, randomized, placebo-controlled, double-blinded study, electroacupuncture was shown to reduce anxiety, discomfort, and demand for sedative drugs during colonoscopy. Points LI 4 (Hegu; fig. 3
), ST 36 (Zusanli; fig. 2
), SP 6 (Sanyinjiao), SP 9 (Yinlingquan), and auricular point Shenmen at the apex of triangular fossa of the ear were stimulated. Patients were divided into three groups: active acupuncture, sham acupuncture, and no acupuncture (control). All patients were given 0.02 mg/kg midazolam 15 min before the procedure. Additional midazolam was required in three patients in the acupuncture group (30%), eight patients in sham group (80%), and nine patients in the control group (90%). Patients in the acupuncture group scored procedure acceptability better. This small study suggests appropriately administered acupuncture may complement preoperative anxiolytic treatment with benzodiazepines.
Intraoperative Acupuncture-assisted Anesthesia.
Reduction in volatile anesthetic or opioid requirement is a clinically important outcome because it can reduce anesthetic toxicity and duration of recovery. There is evidence to suggest that inadequately treated pain, even during general anesthesia, activates pain pathways.56
Subsequent release of local mediators then primes the pain-sensing systems and aggravates postoperative pain.57
To the extent that intraoperative acupuncture prevents activation of pain pathways and provides analgesia, it may similarly reduce postoperative pain and the requirement for postoperative opioids (table 1
It is important to emphasize that acupuncture does not provide true anesthesia or unconsciousness, because it preserves all normal sensory, motor, and proprioception sensations. It does not provide adequate muscle relaxation or suppress autonomic reflexes caused by intraabdominal visceral pain.58
Instead, acupuncture produces analgesia59–61
Acupuncture is safe and, in combination with conventional anesthetic techniques, is capable of reducing the required dose of opioids and offers more comfortable postoperative conditions than anesthesia alone.59,63
Questionable results, however, were obtained by Sim et al.58
in a blinded, randomized, placebo-controlled study on the effect of electroacupuncture on intraoperative alfentanil and morphine consumption during gynecologic surgery. Patients received true acupuncture or placebo acupuncture (continued throughout surgery) or they received no preoperative treatment and acupuncture postoperatively (continued for 45 min). Intraoperative alfentanil consumption was similar in the acupuncture and control groups but was significantly greater (P
= 0.024) in the group that received acupuncture postoperatively. This finding may indicate a treatment-expectation placebo effect accompanied by endogenous opioid release in both control and preoperative acupuncture groups, rather than an acupuncture effect, although endogenous opioid concentrations were not measured. Acupuncture-induced postoperative analgesia in the preoperative acupuncture group was obvious during the first 6–12 h postoperatively. However, cumulative 24-h, patient-controlled analgesia consumption of morphine was not significantly less in the acupuncture-treated groups than in the placebo groups. The inability of acupuncture to reduce the 24-h morphine consumption can be explained by the fact that the analgesic effect of a single session of electroacupuncture lasts only 2–3 h.64
Acupuncture might decrease volatile anesthetic requirements. In an experimental setting, electroacupuncture produces a small but statistically significant reduction of halothane requirement in anesthetized dogs.65
An advantage of evaluating acupuncture during general anesthesia is that it permits full blinding without resorting to sham stimulation. In three volunteer studies, anesthetic requirement with and without acupuncture was determined by the Dixon “up-and-down” method and defined by the average desflurane concentration required to prevent purposeful movement of the extremities in response to noxious electrical stimulation.66–68
The first study was a crossover, double-blinded, placebo-controlled study in which Greif et al.66
showed that transcutaneous electrical stimulation of the lateralization-control point near the ear tragus reduces anesthetic requirement to acute noxious stimulation by 11 ± 7% (P
< 0.001). Acupuncture stimulation was initiated after induction of general anesthesia. In the second study, Taguchi et al.68
found that acupuncture initiated after induction of general anesthesia reduced desflurane requirement by 8.5 ± 7%. Auricular acupuncture was performed after induction of general anesthesia with needles placed at the Shen Men, thalamus, tranquilizer, and master cerebral points on the right ear (fig. 5
). In the third volunteer trial, Morioka et al.67
tested the hypothesis that electroacupuncture at the Zusanli (ST 36), Yanglingquan (GB 34), and Kunlun (BL 60) acupuncture points on the leg decreased anesthetic requirement during electrical noxious stimulation on the thighs. Desflurane requirement on the acupuncture (4.6 ± 0.6%) and control (4.6 ± 0.8%) days did not differ (fig. 6
). Acupuncture significantly reduced anesthetic requirement in two of these three volunteer trials, but neither reduction was clinically important. This conclusion is consistent with a recent clinical study in which patients given acupuncture-assisted anesthesia required even more volatile anesthetic than patients in the control group.69
Available data therefore indicate that acupuncture has little if any effect on anesthetic requirement. As might be expected, manual stimulation of classic acupuncture points during surgery did not influence pain scores or change intraoperative or postoperative analgesic requirements.70
Postoperative Pain Control.
Acupuncture and related techniques can potentially serve as important adjuvants for pain control and for relieving opioid-related adverse effects during the postoperative period. However, controversial results, dissimilar study designs, and diverse modes of acupuncture-point stimulation make it difficult to evaluate the clinical importance of perioperative acupuncture analgesia. There are few randomized, controlled clinical trials on acupuncture-related postoperative pain relief published in English (table 2
). Interpretation of these available studies is complicated by the fact that acupuncture success depends on numerous factors, including adequate patient selection and the acupuncturist’s knowledge and skill level.
Christensen et al.71
demonstrated that patients receiving electroacupuncture before and during hysterectomy had no reduction in their postoperative analgesic requirement or pain. However, in this study, patients were also given relatively high doses of meperidine for induction and intraoperative pain control. Opioid-induced analgesia may have masked the putative benefit of electroacupuncture.
In another study, acupuncture increased intraoperative discomfort, postoperative pain, and consumption of analgesic after dental surgery.50
In this study, local anesthesia was supplemented by preoperatively or postoperatively administered acupuncture with manual stimulation. Both acupuncture groups had increased consumption of pain medication and greater pain rating postoperatively than did the control group.50
In addition, patients from the preoperative acupuncture group needed more local anesthetic than patients from the other groups and expressed more distress during the surgical procedure. However, patients in both acupuncture groups demonstrated significant mental relaxation. There are several potential explanations for these conflicting results. First, the relaxing effect of acupuncture might blunt the activation of a natural endogenous pain inhibiting system. Second, the vasodilatation induced by acupuncture might have caused faster washout of the local anesthetic. Third, the investigators might have used suboptimal acupoint selection and stimulation technique.
In contrast, in a randomized, double-blind, placebo-controlled trial, Lao et al.72
demonstrated the efficacy of acupuncture for reducing pain and postoperative analgesic consumption after a similar oral surgery procedure. The stimulated acupoints and technique selected for this study were similar to those selected for the previous one. An experienced acupuncturist performed the procedure, in contrast to the previous study, where the level of expertise of the person performing acupuncture was not discussed. (It is not uncommon that acupuncture for research purposes is performed by insufficiently experienced personal.) Acupuncture or a well-designed, noninsertion placebo treatment was administered twice: immediately after the surgical procedure and after the patient reported moderate pain. The results showed that pain-free postoperative time was significantly longer in the acupuncture group (173 min) than in the placebo group (94 min; P
= 0.01). Average pain medication consumption was significantly less in the acupuncture group.
As previously mentioned, point selection and mode of stimulation perform important roles in the outcome of acupuncture for postoperative pain relief. It seems that different components of postoperative pain respond to different combinations of acupuncture points. Shu points of the internal organs are located bilaterally 3 cm lateral to the posterior midline. Shu points are associated with the viscera20
and traditionally have been used for treatment of internal organ diseases. Stimulation of these points may alleviate pain caused by visceral dysfunction (fig. 7
For example, consumption of supplemental morphine is reduced by 50% and the incidence of postoperative nausea is reduced by 20–30% in acupuncture patients undergoing upper or lower abdominal surgery (P
< 0.01; fig. 8
In this controlled, double-blinded study, intradermal needles were inserted paravertebrally in shu points. All needles were inserted while patients were in the preinduction area. In addition to less morphine consumption and postoperative nausea, patients with intradermal acupuncture had better pain relief than controls (P
< 0.05). Plasma cortisol and epinephrine concentrations were 30–50% less in the acupuncture group during recovery and on the first postoperative day (P
Transcutaneous electrical nerve stimulation (TENS) near the incision site significantly reduces postoperative pain.73
However, this treatment seems to be most effective for the superficial cutaneous component of postoperative pain, leaving the deep visceral pain component largely intact. It seems likely that high-frequency transcutaneous electrical nerve stimulation near the incision site mainly stimulates specific afferent nerve fibers74,75
instead of triggering endogenous opioid-release mechanisms. Combining TENS and stimulation of viscera-associated shu points in the treatment plan is therefore promising for reducing postoperative superficial and deep visceral pain, respectively.
Both high- and low-frequency electroacupuncture at Zusanli (ST 36) point performed 20 min immediately before induction of anesthesia reduces morphine consumption after abdominal hysterectomy.60
This point is traditionally considered effective for the treatment of abdominal disorders. The high-frequency acupuncture group had a 61% reduction in 24-h patient-controlled analgesia morphine consumption. Pain scores postoperatively did not significantly differ between groups, but cumulative morphine consumption for the first 24 h, number of patient-controlled analgesia demands, and intervals for the first request for analgesic were significantly less in both the high- and low-frequency electroacupuncture groups. The above parameters were also reduced in the sham acupuncture group compared with the control group, although they were greater than in the acupuncture groups. This is unsurprising because sham acupuncture seems to have an analgesic effect in 40–50% of patients compared with 60–70% for real acupuncture and 30–35% for placebo (control).76
In contrast, another study did not confirm acupuncture-induced postoperative analgesia.58
Similar acupuncture techniques were used and similar patient populations participated, but a statistically significant effect of preoperative acupuncture was observed only 6–12 h postoperatively. These data are in accord with those of a previous study,64
however, which demonstrated that the analgesic effect of a single session of acupuncture lasts only a limited amount of time (3 h in that particular study) after stopping of the treatment.
Chen et al.77
compared the effect of TENS applied to various sites on postoperative opioid analgesic requirement after lower abdominal surgery. (In contrast to electroacupuncture, the TENS technique does not require skin penetration with the needle.) TENS was equally effective when applied on point Zusanli (ST 36; fig. 2
) and on the dermatomes at the level of incision. It provided approximately a 35% reduction in the hydromorphone consumption compared with control and sham stimulation groups. Patients given acupuncture also had less PONV. They were also less sedated, presumably because they required less opioid. A previous study similarly demonstrated a correlation between the intensity of TENS stimulation and its effectiveness for postoperative pain relief.62
Postoperative Nausea and Vomiting.
Postoperative nausea and vomiting frequently complicate both general and neuraxial anesthesia and frequently delay recovery from surgery.78,79
Although better anesthetic techniques and a new generation of anesthetic drugs and antiemetics have significantly reduced the incidence of PONV, up to 70% of high-risk patients are still affected.80
The etiology of PONV is likely to be multifactorial, with important predictors being female sex, history of PONV or motion sickness, nonsmoking status, and use of postoperative opioids.81
Risk for PONV can be predicted.81
Unfortunately, the efficacy of currently available antiemetics remains limited, with each reducing relative risk for PONV by roughly 25% and all having adverse effects. Relatively low efficacy combined with occasional complications has generated interest in alternative methods of treatment for PONV.
The use of acupuncture for treatment of postoperative nausea and vomiting is one of the most commonly used and best investigated applications of acupuncture in anesthesia practice (table 3
). Stimulation of point Neiguan (P 6; fig. 9
) is effective at reducing PONV,82,83
and it may be more powerful to prevent early PONV than late PONV.84–86
Electroacupuncture at this point is also effective for postoperative nausea87,88
and somewhat effective for vomiting after tonsillectomy in children.89
Stimulation of P 6 is reportedly as effective as pharmacologic treatment for PONV with ondansetron in both adults and children.84,89–91
Many methods of acupuncture stimulation have been tried for PONV, including manual needle stimulation,83,92
acupuncture with electrical stimulation,89
combination of acupuncture and acupressure,93
normal saline injection,84
acupressure with electrical stimulation (i.e.
, Relief Band),90
transcutaneous electrical stimulation,88
and capsaicin application.85
The optimal method of stimulation has not been identified. Noninvasive methods are easier to perform, painless, and better tolerated by the patients. However, they also seem to be less effective because they have yielded more negative study results94,96
and more trials with partial effects (e.g.
, effective for nausea but not vomiting),87,88
which suggests that noninvasive stimulation is insufficiently intense.97
In 1987, Weightman et al.98
were unable to replicate the ability of P 6 stimulation to reduce PONV. However, in this study, acupuncture was not started until after the patients had been anesthetized. This observation prompted an ongoing debate about the importance of starting acupuncture before induction of general anesthesia.83,99,100
Vickers reviewed 33 controlled trials in which the Neiguan (P 6) acupuncture point was stimulated for treatment of nausea, vomiting, or both associated with chemotherapy, pregnancy, or surgery.101
Acupuncture of P 6 was equal or inferior to control in all studies when acupuncture was started after induction of anesthesia. Conversely, when acupuncture was administered to conscious patients, it was statistically superior to control. A second analysis was restricted to 12 high-quality, randomized, placebo-controlled trials in which the P 6 point was stimulated in conscious patients. Eleven of these trials, involving nearly 2,000 patients, showed a significant positive effect of Neiguan (P 6) stimulation for prevention of nausea and vomiting. The reviewed articles showed consistent results across investigators, groups of patients, and forms of acupuncture point stimulation.101
The author concluded that, except when administered during anesthesia, P 6 acupuncture point stimulation is an effective antiemetic technique. An alternative explanation is that a placebo effect is responsible for the antiemetic action of acupuncture in those patients receiving it while they were awake. Many of the studies cited above did have adequate placebo control groups, which argues against a placebo effect.
Most of the studies in which acupuncture was initiated after induction of general anesthesia and did not elicit an antiemetic effect were performed on children,93,96,100,102,103
who generally do not cooperate with needle insertion while awake. These studies led to the conclusion that acupuncture was ineffective for PONV in children.91
Later studies, with better design and probably better technique, refuted this conclusion and found that acupuncture for PONV is as effective in children as in adults.84,89,92
An interesting finding was that even when started after induction of general anesthesia,92
bilateral Neiguan (P 6) stimulation reduced PONV in children. These investigators also stimulated point Shangvan (CV 13) and used a special device (cunometer) for better point location.
Almost all clinical trials on the effect of acupuncture on PONV have used a standardized treatment involving stimulation of the Neiguan (P 6) point. Such simplification may not always be appropriate and may be the reason for failure in many studies. The classic acupuncture approach is to treat a disease or syndrome in various ways, depending on the complex characteristics of patients and their symptoms. Neiguan (P 6) is hardly the only point thought to prevent PONV.59,92,104
In fact, more than 30 classic meridian acupuncture points are described as being effective for nausea and vomiting,12,21,105
although specific effects of the other points or point combinations have not been studied in detail. Chu et al.
however, were able to decrease PONV from 64% in placebo patients to 24% in treated patients after strabismus correction surgery in a randomized, controlled trial using acupressure on points Tianzhu (BL 10), Dazhu (BL 11) and Yanglingquan (GB 34). All these points are located on meridians connected to the eyes, and the authors hypothesized that they were able to achieve good results because their point selection allowed them to diminish parasympathetic stimulation from surgical traction of eye muscles. In contrast, P 6 acupuncture does not prevent PONV after strabismus surgery.96,103
Postoperative nausea and vomiting can also be treated successfully with the Korean hand acupuncture system.85,107,108
In contrast to classic Chinese acupuncture, the Korean hand acupuncture system is comparatively recent and has been studied even less. Kim et al.85
found approximately a 50% reduction in PONV after abdominal hysterectomy in a randomized, double-blinded, placebo-controlled study in which capsicum plaster was applied on the point located on the lateral distal phalanx of the index finger on both hands. Results were similar when Korean hand acupuncture was used for PONV after gynecologic laparoscopy.107
Acupuncture may reduce nausea and vomiting via
endogenous β-endorphin release in the cerebrospinal fluid109
or a change in serotonin transmission via
activation of serotonergic and noradrenergic fibers110
The exact mechanisms have yet to be established.
Acupuncture and Perioperative Complications.
Acupuncture can be used to a certain extent as an alternative treatment of intraoperative and postoperative complications when conventional treatment is unavailable, is undesirable, or increases risk.
Acupuncture with bloodletting is a technique that involves a quick needle prick with thick, sharp needles on the acupuncture points. It is usually performed on distal endpoints of the meridians on the fingers or toes. Bloodletting acupuncture at Shaoshang (LU 11), Shangyang (LI 1), or both (fig. 10
) reportedly prevents laryngospasm after tracheal extubation. This technique was used successfully in children, who are most prone to development of postextubation laryngospasm. However, the study design did not include the blinding of investigators.111
The dangers of this unblinded study design were illustrated by a subsequent investigator, who demonstrated that the same acupuncture technique actually aggravated laryngospasm.112
Available data therefore do not support using acupuncture for laryngospasm.
In a study using 35 dogs anesthetized with halothane, acupuncture reversed cardiovascular depression induced by morphine and halothane. Acupuncture at point Jen Chung (GV 26; fig. 11
) significantly increased cardiac output, stroke volume, heart rate, mean arterial pressure, and pulse pressure while simultaneously significantly decreasing total peripheral resistance and central venous pressure. The authors concluded that stimulation of the GV 26 acupoint could be helpful in resuscitating patients whose cardiovascular system is depressed by opioids and volatile anesthetics.113
Neiguan (P 6) point has long been considered a primary point for treatment of various cardiovascular diseases.21
It has been shown to be effective as an adjunct therapeutic modality in conservative treatment of severe angina pectoris.114
Electroacupuncture at Neiguan (P 6) was effective in maintaining the hemodynamics and cardiac contractility in anesthetized open-chest dogs.115
End-diastolic volume was maintained and even slightly increased in comparison with the control group, in which end-diastolic volume gradually decreased over 1.5 h; stroke volume and cardiac output also slightly increased compared with the control group. The end-systolic pressure and end-systolic elastance increased markedly in the Neiguan (P 6) acupuncture group. No analogous data support acupuncture-induced cardiovascular benefits in humans, an obvious prerequisite to clinical application of the technique.
Impaired Intestinal Function.
A major side effect of the opioid administration for postoperative pain control is the impairment of intestinal function.116
Intraoperative and postoperative acupuncture for pain relief decreases perioperative opioid consumption59
and may thus be beneficial for indirectly speeding postoperative recovery of intestinal function.
Acupuncture treatment has also been shown to promote postoperative recovery of impaired intestinal function after abdominal surgery.117
Patients were treated with auricular plaster therapy (stimulating plaster applied on specific auricular points) combined with acupuncture at Zusanli (ST 36) to relieve abdominal distension and dysfunction after abdominal operations. Among 13 patients in the treatment group, 12 (92.4%) showed recovery of normal peristalsis within 72 h after operation; in contrast, only 46% of the 13 control patients recovered in that time. An obvious limitation of this study is that it is extremely small compared with most trials of postoperative ileus.
General Principles of Acupuncture Analgesia
The practice of acupuncture requires certain skills, experience, and theoretical knowledge by the practitioner. Patients must also be carefully selected for acupuncture analgesia, taking into account the type of operation, the patient’s age and overall condition, and the results of test needling.
Acupuncture in general and acupuncture analgesia in particular are more effective in young adults than in elderly patients. Small children are usually poor candidates for acupuncture-assisted anesthesia and analgesia with needles simply because they are rarely willing to cooperate with the acupuncturist.
Acupuncture is not suitable for moribund patients preoperatively because it is generally much less effective on extremely sick patients.11
To obtain optimal results with acupuncture, it is necessary that the patient understands what acupuncture is, has a good attitude toward acupuncture, and has faith in the efficacy of the method. These patients are also highly susceptible to bias and placebo effect, which complicates acupuncture research.
It is often helpful to needle one or two acupuncture points before making a decision to use acupuncture. This test helps to ascertain that a patient responds to needling with a good De-Qi sensation, which is a good predictor of subsequent acupuncture efficacy. If De-Qi is not achieved, endorphins are less likely to be secreted. The ancient physicians always emphasized that to be effective, acupuncture must cause “Qi to be received.” Sometimes it is difficult or impossible to obtain De-Qi sensation. Such patients, typically approximately 10% of the population, do not elicit a physiologic response on acupuncture stimulation and are referred to as nonresponders.
There are certain rules and principles that are generally applied when selecting points for acupuncture treatment.120
First, appropriate meridians should be selected, and then appropriate points on these meridians should be stimulated. For example, for postoperative pain control, a meridian that passes through the surgical area or close to the surgical area is usually selected. Also, according to the “organ phenomena” concept of traditional Chinese medicine, the lung commands the skin. Consequently, stimulation of acupuncture points on the lung meridian can provide analgesia for surgical skin incisions. Similarly, the liver meridian commands the eyes, making the liver meridian ideal for ophthalmologic surgery.
Needling of points that easily produce a strong De-Qi sensation are therefore thought to provide better analgesia. Conversely, analgesia is often poor at needling points that produce weak De-Qi response or in which the sensation is difficult to obtain. Reactive points that are commonly selected include Zhusanli (ST 36; fig. 2
), Sanyinjiao (SP 6), Hegu (LI 4; fig. 3
), and Neiguan (P 6; fig. 9
When selecting acupuncture points, one must consider convenience as well as the patient’s comfort. Points located below the knee or elbow are usually selected during surgery.
Points located on the ear are often selected for acupuncture during the perioperative period. Locus points or surgical position points are most often selected. (According to ear acupuncture theory, locus points are the points that are projections of the surgical site on the ear.) After the locus point is identified, auxiliary points may be added. Auricular points that possess strong tranquilizing and analgesic effects, such as Shen Men, sympathetic, subcortex, and others, are often selected as auxiliary points for various types of surgery.28
Acupuncture is increasingly being incorporated into the healthcare system. Growing numbers of insurance companies now either provide coverage for acupuncture or are considering doing so. Acupuncture and related techniques are increasingly practiced in conventional medical settings, with more open attitudes toward them. Consequently, the number of patients willing to use these techniques—or even specifically request them—will likely increase. In fact, more than 50% of patients involved who participated in a recent study stated that they were willing to pay extra for use of the TENS technique for postoperative pain relief for future surgery.77
Despite more than 30 yr of research, the exact mechanism of action and efficacy of acupuncture have yet to be established. Furthermore, most aspects of acupuncture have yet to be adequately tested. Therefore considerable controversy remains about the role of acupuncture in clinical medicine.
Acupuncture does not seem to reduce the requirement for volatile anesthetic, at least not by a clinically important amount. Preoperative sedation seems to be a promising application of acupuncture in perioperative settings, but more studies are required before this technique can be recommended for routine use. In contrast, several high-quality studies have demonstrated substantial effectiveness of acupuncture for postoperative pain relief; however, this issue still remains controversial. Acupuncture may be effective for postoperative pain relief but probably requires a higher level of expertise and training of the acupuncture practitioner than is generally available. Enough evidence has also accumulated to introduce acupuncture and related techniques for treatment and prophylaxis of postoperative nausea and vomiting in routine clinical practice in combination with or as an alternative to conventional antiemetics. However, antiemetic acupuncture seems to be effective only when administered before induction of general anesthesia.
Some promising applications of acupuncture in the perioperative setting could be treatment of postoperative ileus, postextubation laryngospasm, and correction of hemodynamic instability. However, further research will be required to clarify the role of acupuncture in the treatment of these conditions.
The authors thank Nancy Alsip, Ph.D. (Outcomes Research Institute, Louisville, Kentucky), for editorial assistance.
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