Fossil evidence of trepanning suggests that man has used high threshold physical techniques in the treatment of disease since Neolithic times (Martin, 2000; Parry, 1936). Bone etchings from China dating back to 1600 BC are said to provide some of the earliest evidence of acupuncture techniques. Older still are the sharpened stones called Bian shi, although it is questioned whether or not these were actually instruments of acupuncture (Bai & Baron, 2001). Harder evidence—in a softer format—comes from the silk scrolls found in Han Tomb No. 3 (dated to 168 BC) at Mawangdui, Changsha, China, in the early 1970s. These manuscripts describe an early meridian system with 11 rather than 12 paired meridians and the use of moxibustion, which is a treatment involving the application of heat by burning the herb Artemisia vulgaris. The pericardium meridian is missing (Chen, 1997) from these early manuscripts. There is also an emphasis on information derived from tactile examination of the living body (Hsu, 2005) rather than from dissection postmortem. However, there is no description of acupuncture needling in these manuscripts (Bai & Baron, 2001). The discovery of Ötzi, the Tyrolean iceman frozen from 3200 BC, suggests the use of a therapeutic needling technique with a needle made from bone, which may have developed in Europe (Dorfer et al., 1999). It seems clear that acupuncture-like therapies have developed independently in different civilisations around the world; this is probably due to late evolutionary features in the mammalian nervous system, combined with intelligence, and the consequent use of tools in humans.

Children learn at a very early age to rub energetically directly over the site of acute pain to reduce the noxious sensation. In the case of a more chronic discomfort from aching, ‘knotted’ muscle, we tend to massage the local tissues more deeply and vigorously even though doing so may temporarily exacerbate the discomfort. This is likely to be conditioned behaviour resulting from the analgaesic effect of somatic sensory stimulation. With the development of stone tools, it is easy to hypothesise a progression of therapeutic techniques that resulted ultimately in piercing the skin and muscle at a site of chronic pain. It may be that successful treatment of myofascial pain by piercing the body at the site of tenderness not only encouraged the practice, but also lead to the recognition of areas of the body that were most likely to harbour these tender points. In some parts of the world, people developed superficial techniques of scratching or cauterising the skin, whereas in the Far and Middle East the technique of acupuncture developed (Cummings, 2004).

Traditional Acupuncture

The development of acupuncture points probably resulted from clinical observation that certain places in the body were more likely to harbour tender points than others and that treating these points by pressure or piercing could relieve pain and various other nonpainful symptoms. Early physicians would have also noted that careful examination of the body surface revealed tender points in healthy subjects. Consistent patterns of pain referral from myofascial trigger points and the relief resulting from needling these and other muscle points would have lead them to make links between some of the points. Radiation patterns of painful medical conditions such as sciatica, other radiculopathies, and possibly the consistent rashes of herpes zoster would have added to the impression that the established points were connected. These hypotheses do not explain the location of all acupuncture points, nor the paths of all the meridians, but there is clearly considerable overlap between myofascial trigger points and acupuncture points (Melzack et al., 1977) and between the pain referral patterns of the former and meridians (Dorsher, 2009). Although these potential correlations have caused great debate, the theoretical backgrounds of these concepts are clearly distinct.

The Chinese and others probably used acupuncture pragmatically for centuries before it became systematised within a documented form of medicine some 2000 years ago (Veith, 1972). The theories developed were influenced by rational observations imposed upon a limited clinical knowledge base and in the philosophical framework of Taoism. The tendency towards syncretism resulted in the adoption and inclusion of many different theories; over the centuries this has resulted in the development of a complex system of medicine. Traditional Chinese medicine can be initially unpalatable to the skeptical Western scientist. However, on closer inspection it reveals that it is built on a series of logical assumptions, and, although some of these are clearly wrong, many may still represent valid clinical observations.

Western Medical Acupuncture

Western medical acupuncture is a term with a variety of potential meanings. The most literal interpretation invokes thoughts of geographical boundaries, but the term was probably introduced to distinguish a developing system of needle therapy with a basis in Western medical science from its traditional philosophical roots that happened to be in the East. Filshie and Cummings (1999) interpret ‘Western medical acupuncture’ as the scientific application of acupuncture as a therapy after orthodox clinical diagnosis. It is important to note that the scientific evaluation of acupuncture is not restricted to the West (Han & Terenius, 1982) and therefore adherence to a geographical definition is inappropriate. Probably a more accurate description of ‘Western medical acupuncture’ (WMA) is a modern scientific approach to therapy involving dry needling of tissues that has been developed from the introduction and evaluation of traditional Chinese acupuncture techniques in the West (Cummings, 2004).

More recently the definition of WMA has been reconsidered and redefined (White, 2009): ‘Western medical acupuncture is a therapeutic modality involving the insertion of fine needles; it is an adaptation of Chinese acupuncture using current knowledge of anatomy, physiology, and pathology, and the principles of evidence based medicine’.

Galileo established the modern scientific method in the 17th century when he introduced systematic verification through planned experiments to the existing ancient methods of reasoning and deduction (MacLachlan, 1999). This system was adopted by the scientific community throughout the globe, and, with the addition of statistical analysis, it remains established practice today. The ethical practice of medicine requires the practitioner to understand and use scientific method; however, there is great debate over the use of certain methods of testing efficacy when applied to potentially complex interventions such as acupuncture.

The therapeutic effects of acupuncture needling are mediated through stimulation of the peripheral nervous system and so can be abolished by local anaesthetic (Chiang et al., 1973; Dundee & Ghaly, 1991). In particular, stimulation of Aδ or type III afferent nerve fibres has been implicated as the key component in producing analgesia (Chung et al., 1984). The therapeutic effects of needling can be divided into three categories based on the area influenced: local, segmental, and general.

Trigger Point Needling

The mechanism of action of direct needling in the deactivation of trigger points is undetermined. Despite the fact that a causal relationship has not been established between direct needling of trigger points and improvement in symptoms, a discussion of the potential mechanisms involved may still be useful in developing future research questions. Simons and colleagues (1999) commented on the results of two trials that compare direct dry and direct wet needling of trigger points (Skootsky et al., 1989; Hong, 1994) and conclude that the critical therapeutic factor in both techniques is mechanical disruption by the needle. The common factor is certainly needle insertion into the trigger point; however, Hong (1994) highlighted the importance of stimulating a local twitch response in achieving an immediate effect and, with Simons, cites evidence that the local twitch response is mediated by a segmental spinal reflex (Hong & Simons, 1998). Fine and colleagues (1988) performed a rigorous experimental study in which trigger points were subject to direct wet needling and clearly demonstrated that an opioid mechanism was involved in trigger point pain relief. In light of this evidence it seems likely that the needle works more often through sensory stimulation than through mechanical disruption; this would be consistent with the mechanism of action of acupuncture analgesia (Han & Terenius, 1982; Han, 2004; Zhao, 2008; Han 2010). Having said that, techniques vary considerably, and it is possible that the more vigorous and fast insertion trigger point needling has a direct mechanical effect on endplates, muscle spindles, or fibres themselves. Readers are referred to Chapter 2 of the current textbook for physiological mechanisms of trigger point dry needling.

The principal methodological difficulties in clinical trials that study the efficacy of acupuncture are concerned with controls and blinding (Lewith & Vincent, 1998; White et al., 2001b; Cummings & White, 2016). For a placebo control to be credible the subjects receiving it must believe that they have had an active treatment, identical to, or at least equivalent in potency to, the active intervention. Ideally, for any needling therapy the control should involve an inactive form of needling, but it seems clear that a needle placed anywhere in the body is likely to have some neurophysiological effect (Lewith & Machin, 1983)—perhaps as a result of the noxious stimulus (Le Bars et al., 1979) of a needle piercing skin, or perhaps related to context-driven and interactional effects including target-directed expectation (Benedetti et al., 1999) and complex conditioned responses (Lundeberg & Lund, 2008).

An innovation in needle design (Streitberger & Kleinhenz, 1998; Kleinhenz et al., 1999) appeared at first to overcome the problem of needle penetration of skin by using a blunt needle that slid up into the coiled metal of the handle. This device was credible to the subject, but in order to simulate needle retention in the body, it needed to be attached to the skin. This was done by inserting it through an adhesive plaster dressing over a small plastic ring placed over the point. In practice, however, the blunt needles pushed with enough force to get through the plaster and also occasionally penetrated the skin surface (Konrad Streitberger: personal communication, 2001). The Park sham device, which consists of a plastic guide tube of adjustable height with a sticky base, was developed as an alternative method of holding the sham needle in place (Park et al., 2002); however, the subject could be unmasked if a needle fell out of the device. A convincing control procedure should result in blinding of the subject, but it is almost impossible to blind an experienced therapist who is performing both real and sham needling techniques. A common way of reducing bias in this situation is to use a blind assessor. A nonpenetrating needle device that blinds the practitioner as well as the subject has been developed and validated (Takakura & Yajima, 2007, 2008). However, it seems that simple nonpenetrating sham acupuncture procedures such as blunted cocktail sticks tapped on the skin can be highly effective in clinical trials (Cherkin et al., 2009), and so the measured efficacy of true acupuncture over sham techniques in clinical trials is often small and not statistically significant.

Evidence for Needling in Myofascial Pain

A systematic review published in 2001 of 23 randomised controlled trials conclusively shows that, when treating myofascial pain with trigger point injection, the nature of the injected substance makes no difference to the outcome and that there is no therapeutic benefit in wet over dry needling (Cummings & White, 2001). These conclusions were supported by all the high quality trials in the review. The review did not find any rigorous evidence that needling therapies have a specific effect in myofascial pain, as authors Cummings and White (2001) concluded:

This review has not been formally updated, but from the author’s knowledge of the literature published since 2001, there would be no substantial change to the conclusions. A further review with meta-analysis including only trials of dry needling was inconclusive, although the results were compatible with a treatment effect of dry needling on myofascial trigger point pain (Tough et al., 2009). Another review including meta-analysis with an anatomically limited focus (upper quadrant) was positive for dry needling (Kietrys et al., 2013).

Acupuncture involves the insertion of needles (usually stainless steel) into the body. Although it is often perceived by the general public as ‘natural’ and ‘safe’, along with many complementary therapies, it is neither natural nor completely safe. As with any needling therapy, the serious risks are associated with the transmission of blood-borne infection and direct trauma. Rampes and Peuker categorise adverse events associated with acupuncture as follows (Rampes & Peuker, 1999):

1. 1. Delayed or missed diagnosis
   
2. 2. Deterioration of disorder under treatment
   
3. 3. Pain
   
4. 4. Vegetative (autonomic) reactions
   
5. 5. Viral or bacterial infections
   
6. 6. Trauma of tissues and organs
   
7. 7. Miscellaneous

If acupuncture is performed as a therapy by a regulated healthcare professional within his or her sphere of competence, the first two categories will be avoided.

Persistent pain attributed to acupuncture treatment is rare, but temporary exacerbation of the presenting complaint for a day or so is common (MacPherson et al., 2001a, 2001b; White et al., 2001a). Pain lasting up to 180 days after needling has been reported in a prospective study of over 2 million treatment sessions, apparently due to nerve damage (Witt et al., 2009). The author has heard verbal reports of persistent neuropathic pain around needle insertion points after acupuncture; however, these events are likely to be very rare because filiform acupuncture needles do not have a cutting edge. Although in the past nerves were directly targeted at some acupuncture points, contemporary practice in the West tends to avoid direct needling of nerves (White et al., 2008b).

Autonomic reactions include syncope and sedation. Syncope can be largely avoided by treating patients while lying on an examination couch; however, very occasionally a profound sinus bradycardia will result in loss of consciousness of a patient who is lying down. Sedation is relatively common and occurs in perhaps 20% of patients after their first two treatments. In maybe 5% of patients there is always some degree of sedation associated with acupuncture treatment. Sedation is rarely seen as adverse event by the patients and is only of concern in terms of driving home or operating machinery after treatment.

Infections associated with acupuncture treatment are rare but can be serious (White, 2004). Worldwide, hepatitis B would be the most common infection related to acupuncture, but this is now very rare in the West as a result of the use of sterile disposable needles and clean techniques.

Traumatic complications of acupuncture needling are avoidable, but on occasion they have been fatal. The most frequent of the serious traumatic adverse effects is pneumothorax, which is estimated (from prospective studies) to occur between 1:200,000 (White, 2004) and 1:1 million (Witt et al., 2009) treatment sessions. The drawback with these estimates is that they include all acupuncture session, not just those in which there has been needling over the thorax.

Point Selection

The two main themes in Western medical acupuncture are dry needling of trigger points and segmental acupuncture (Cummings, 2016). The latter is defined as the technique of needling an area of the soma innervated by the same spinal segment as the disordered structure under treatment (Filshie & Cummings, 1999). Based on neurophysiological and clinical evidence (Chapman et al., 1977; Lundeberg et al., 1987, 1989; Sato et al., 1993; Bowsher, 1998; Ceccherelli et al., 1998; White, 1999), the main principle in point selection is to stimulate the soma as close as is practical to the seat of the pathology or at least within the same segment. Local trigger points, tender points, or acupuncture points are chosen, and often these will overlap so that the key point to stimulate is a trigger point, which is tender by definition, at the site of an acupuncture point. The figures in this chapter illustrate commonly used acupuncture points and trigger points represented by body region (Figs. 14.1–14.10 and Tables 14.1–14.5). If the key element of the somatic pathology is a myofascial trigger point, this is arguably the only point that it is necessary to treat. In most other cases the analgesia afforded by local needling may be enhanced by using one or more points at a distance from the pathology in addition to the relevant local points. Distant points are chosen because they stimulate the appropriate segment or because they are conveniently located and known to generate strong needling sensation (heterosegmental acupuncture). In individual cases, point selection may be modified by the need to avoid local conditions (e.g., skin infection, ulceration, moles and tumours, varicosities) or to avoid regional conditions such as hydrostatic oedema, lymphedema, anaesthetic or hyperaesthetic areas, or ischaemia. As a general rule, therapeutic needling should be performed in healthy tissue.

Table 14.1

Face, Head, and Neck

Face
Yintang	Midpoint between the eyebrows		D Vi M VII S Vi
	Angulation: oblique inferior	Target: procerus or periosteum
	Headache, hayfever, relaxation
Taiyang	1 cun posterior to the midpoint between the lateral end of the eyebrow and the lateral canthus of the eye		D Vii M Viii S Vii
	Angulation: perpendicular	Target: temporalis
	Headache, eye symptoms
GB14	1 cun above the middle of the eyebrow, directly above the pupil when the eyes are looking straight ahead		D Vi M VII S Vi
	Angulation: oblique inferio	Target: frontalis
	Headache, eye symptoms
LI 20	In the nasolabial groove, level with the widest part of the ala nasi		D Vii M VII S Vii
	Angulation: superiorly along groove	Target: facial muscles
	Hayfever, nasal symptoms
ST6	1 fingerbreadth anterior and superior to the angle of the jaw, on the prominence of masseter		D C2/C3 M Viii S Viii
	Angulation: perpendicular	Target: masseter
	Dental pain, facial pain
ST7	In the depression anterior to the temporomandibular joint and below the zygomatic arch		D Viii M Viii S Viii
	Angulation: perpendicular	Target: lateral pterygoid
	Dental pain, facial pain
ST8	0.5 cun superior to the upper line of origin of the temporalis muscle, directly above ST7 and ST6 on a vertical line 0.5 cun posterior to Taiyang		D Vi/Vii M Viii/VIIS Vi/Vii
	Angulation: perpendicular	Target: epicranial tissues
	Headache
SI18	Directly below the lateral canthus of the eye in the depression at the lower border of the zygomatic bone, just anterior to the attachment of masseter		D Vii M Viii/S Vii
	Angulation: slightly superior	Target: connective tissue space
	Facial pain, trigeminal neuralgia
LI18	Between the sternal and clavicular heads of sternocleidomastoid (SCM), level with the laryngeal prominence (the tip of the Adam’s apple)		D C2/C3 M XI/C2/C3 S n/a
	Angulation: posterior	Target: fascial plane in SCM
	Pain from sternocleidomastoid—headache or facial pain CAUTION: note the proximity of the carotid artery
Head and Neck
GB20	Below the occipital bone, in the depression between trapezius and sternocleidomastoid and above splenius capitis		D C2/C3 M C1/C2 S C1/C2
	Angulation: towards opposite eyebrow	Target: semispinalis capitis
	Headache, neck pain, and stiffness CAUTION: note the position of the vertebral artery
Head and Neck
BL10	1.3 cun lateral to the spinous process of C2, between C1 and C2		D C3 M C1 to C5 S C2/C3
	Angulation: towards lamina of C2	Target: obliquus inferior
	Neck pain and stiffness CAUTION: note the position and depth of the spinal cord and vertebral artery
GB21	Midway between GV14 and tip of the acromion at the highest point of trapezius		D C3 M C3/C4S n/a
	Angulation: tangential to ribs, posteriorly	Target: upper trapezius
	Headache, neck pain and stiffness, anxiety CAUTION: note the proximity of the pleura between the 1st and 2nd ribs
TE15	Midway between the points GB21 and SI13 at the superior angle of the Scapula (SI13—tender depression superior to medial end of scapular spine)		D C3 M C3/C4 S n/a
	Angulation: perpendicular	Target: trapezius
	Shoulder pain, neck pain and stiffness CAUTION: note the proximity of the pleura in slim patients
GV14	Between spinous processes C7 and T1		D C4/C5/T1 M C8S C8
	Angulation: transverse	Target: interspinous ligament
	Spinal neck pain, headache of cervical origin
SI14	3 cun lateral to spinous process of T1		D C3/C4 M C3/C4/C5 S C5
	Angulation: tangential towards scapula	Target: levator scapulae
	Shoulder pain, neck pain and stiffness CAUTION: do not needle deeply unless confident of angulation relative to scapula
BL11	1.5 cun lateral to the lower border of the spinous process of T1		D C4/T1 M C4/C5 S T1/T2
	Angulation: oblique towards spine	Target: rhomboid minor
	Neck pain and stiffness, dyspnoea CAUTION: do not needle deeply unless confident of angulation relative to pleura
BL45	3 cun lateral to the lower border of the spinous process of T6		D T5/T6 M T6/T7 S T6/T7
	Angulation: oblique towards spine	Target: iliocostalis thoracis
	Dorsal back pain, dyspnoea CAUTION: do not needle deeply unless confident of angulation relative to pleura

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