Abstract
Low back pain is the most common pain symptom experienced by American adults and is the second most common reason for primary care physician visits. There are many structures in the lumbar spine that can serve as pain generators and often the etiology of low back pain is multifactorial. However, the facet joint has been increasingly recognized as an important cause of low back pain. Facet joint pain can be diagnosed with local anesthetic blocks of the medial branches or of the facet joints themselves. Subsequent radiofrequency lesioning of the medial branches can provide more long-term pain relief. Despite some of the pitfalls associated with facet joint blocks, they have been shown to be valid, safe, and reliable as a diagnostic tool. Medial branch denervation has shown some promise for the sustained control of lumbar facet joint-mediated pain, but at this time, there is insufficient evidence that it is a wholly efficacious treatment option. Developing a universal algorithm for evaluating facet joint-mediated pain and standard procedural techniques may facilitate the performance of larger outcome studies. This review article provides an overview of the anatomy, pathophysiology, diagnosis, and treatment of facet joint-mediated pain.
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Introduction
Low back pain is the most common pain symptom experienced by American adults and is the second most common reason for primary care physician visits [1]. One study reported that over one-quarter of the U.S. population had experienced an episode of low back pain in the three months prior to the survey [2]. Although the majority of episodes last less then 3 months, many patients experience recurrent attacks [3]. Those patients who go on to develop chronic low back pain (lasting greater than 3 months) account for an estimated $100–$200 billion dollars of healthcare spending per year [4]. Despite our enhanced understanding of pain neural pathways and improvements in imaging technology, diagnosing the exact etiology of low back pain and treating it continues to be a challenge.
There are many structures in the lumbar spine that can serve as pain generators and often, the etiology of low back pain is multifactorial. Since being described as a potential pain generator by Joel Goldthwait in 1911 [5], the facet joint has been increasingly recognized as an important cause of low back pain. The use of the term facet syndrome was first coined by Ghormely in 1933 [6]. A facet joint (also referred to as a zygapophysial joint) is located at the junction of the inferior articular process of a more cephalad vertebra and the superior articular process of a more caudal vertebra. It has been estimated that facet joint pathology is a contributory factor in 15–52% of patients with chronic low back pain [7–13]. However, it has also been reported that the prevalence of isolated facet joint pain may be as low as 4% [14].
Although the prevalence of isolated facet joint pain is debatable, the presence of facet joint arthrosis in different age groups is clear. Eubanks et al. examined prevalence rates of facet arthrosis on 647 cadaveric lumbar spines. Fifty-seven percent of samples between 20 and 29 years of age and 93% of the samples between 40 and 49 years of age had evidence of facet arthrosis. By the age of 60, 100% of the samples had prominent facet arthrosis. The highest prevalence and the greatest severity of arthrosis were found at L4–L5 [15].
Facet joint pain can be diagnosed and treated with facet joint injections and eventually, with radiofrequency lesioning of the medial branches. These are some of the most common interventional pain procedures performed with over 175,000 Medicare billings recorded in 2001 [16].
This review article will provide an overview of the anatomy, pathophysiology, diagnosis, and treatment of facet joint-mediated pain.
Anatomy
Previous studies have demonstrated that both the capsule [17, 18], and synovial folds [19, 20] of facet joints possess nociceptive nerve endings. Pain sensation from the capsule and synovium are transmitted through the medial branches of the dorsal ramus of spinal nerves. In addition, the medial branches also supply the multifidus muscle, ligaments, and the periosteum of the vertebral arches and spines [21, 22].
The facet joint in the lumbar spine is innervated by the medial branch of the dorsal ramus of the nerve exiting at the same level and also the medial branch of the nerve one level above. For example, when considering the L4–L5 facet joint, innervation is supplied by the medial branches originating from the L3 and L4 nerves. In this example, the medial branch from the L3 nerve supplies the inferior articular process of the L4 vertebrae. This is equivalent to the superior articulation of the facet joint. Likewise, the medial branch of the L4 nerve supplies the superior articular process of the L5 vertebrae, which also represents the inferior articulation of the L4–L5 facet joint.
As each medial branch passes inferiorly, it lies in a groove along the medial–posterior surface of the transverse process [23–26]. The medial branch courses over the transverse processes one level inferior to where it originates. This is related to the fact that there is a C8 nerve but no C8 vertebrae. For example, the C6–C7 facet joint is innervated by the medial branches of C6 and C7. However, the C7–T1 facet joint is innervated by the medial branches of C7 and C8. The facet joints of T1–T2 are innervated by the medial branches of C8 and T1. This pattern continues in the lumbar spine. Of note, the anatomy of the L5–S1 facet joint differs from its lumbar counterparts. It is innervated by the medial branch of L4 and the dorsal ramus of L5. The L5 dorsal ramus courses along a groove formed between the base of the S1 superior articulating process and the sacral ala [23, 26] (Fig. 1).
The articulating surface of the facet joints is covered by a layer of hyaline cartilage. Surrounding each facet joint is a thin fibrous capsule lined with synovial membrane. The joint capsule plays an important role in the degree of motion obtainable secondary to the ability of the capsule to resist flexion moments [27]. In comparison to cervical facet joint capsules, the lumbar capsules are shorter and more taught, resulting in a lesser degree of flexion obtained in the lumbar spine in comparison to the cervical spine. Experiments in which the joint capsules in the lumbar spine were excised resulted in increased lumbar range of motion in the sagittal plane [28].
The orientation of lumbar facet joints has important functional and clinical consequences. For example, facet joints oriented relatively more parallel to the sagittal plane, such as at L2–L3 and L3–L4, allow limited rotational movements and anatomically favor flexion and extension movements. In contrast, the L4–L5 facet joints, with increased coronal angulations, facilitate greater rotational movements [29–31].
Both facet joint orientation and facet joint tropism (an asymmetry in the angles of two facet joints at the same level) have been implicated as important variables leading to facet joint-mediated pain. Masharawi et al. examined facet joint morphology in 240 human cadavers. They noted facet joint tropism was much more common in the thoracic spine as compared to the lumbar spine [32]. This suggested that asymmetry of facet joints in the lumbar spine may be associated with pathology. However, Grogan et al. [33] examined 104 cadaveric facet joints for severity of cartilage degeneration and found no association with facet tropism. They reported that the factors associated with sclerosis and cartilage degeneration of the facet joint were not facet tropism, but rather advanced age, spinal level, and increasingly coronal joint angles. However, other studies have linked degenerative spondylolisthesis to facet joints that have an increased sagittal orientation [34, 35].
Facet joints may also serve important proprioceptive functions. This is based on the presence of low threshold, mechanoreceptors lining the facet capsule. These receptors are similar to mechanosensitive neurons involved in proprioception of other peripheral joints [36, 37].
Radiographically, the facet joint may be visualized more clearly with oblique views. With this radiographic angle, the classic “Scotty dog” is visualized, allowing for easier recognition of anatomic landmarks. To review, the nose is formed by the transverse process; the eye formed by the pedicle, the neck is the pars interarticularis, the ear is formed by the superior articular process and the front leg formed by the inferior articular process (Fig. 2).
The facet joint as a pain mediator
In 1963, Hirsch et al. [38] injected 11% hypertonic saline in the region of the facet joints and provoked low back and thigh pain. Subsequently, facet joint-mediated pain was confirmed with more specific studies involving direct intra-articular injections of hypertonic saline [39, 40]. In the study conducted by Mooney and colleagues, the intra-articular injection of saline was followed by the injection of local anesthetic. This obliterated the discomfort in all subjects tested [39]. Similar results were obtained with subsequent experiments that utilized intra-articular injection of contrast to provoke pain through distention of the facet joint capsule [41]. The results of these earlier studies have been reproduced through experiments involving stimulation of not only facet joints but also the medial branches [42].
The development of facet joint-mediated pain involves both biomechanical and inflammatory components. Multiple factors can destabilize the facet joint and its capsule.
Biomechanical model
Intervertebral disc degeneration has been reported to be a source of low back pain in adults [43]. Studies have linked pathological changes in facet joints with preceding disc degeneration [44–46]. The intervertebral discs support most of the weight during flexed postures but the facet joints bear an increasingly greater burden as the lumbar spine is ranged into extension. In addition to stabilizing the spine and guiding segmental motion, facet joints function as weight-bearing structures that support axial loading along with the intervertebral discs. Studies have shown that the facet joints can carry up to 33% of the dynamic axial load [47–49]. Disc degeneration with associated narrowing of the disc space alters the mechanical load distribution and may result in a degenerative cascade with increased mechanical stress on the facet joint and joint capsule. Within the active range of the lumbar spine, the paraspinal muscles act as the principal contributors to vertebral stability. However, both cyclic and sustained flexion movements decrease the reflexive muscle activity of the paraspinal muscles such as the multifidus muscle [50–57]. In theory, this may result in increased laxity across the facet joint leading to both decreased stability and increased stress on the facet joint capsule [55].
The role of the facet joint capsule in stabilizing the motion characteristics of these joints cannot be understated. Studies have suggested that disc degeneration results in increased range of axial rotation [58–61]. It has been postulated that the increase in axial rotation and subsequent instability place additional stressors upon the facet joint capsules leading to a molecular response, which results in fibrocartilaginous metaplasia in the capsules of facet joints. Boszczyk et al. [62] reported hypertrophic and fibrocartilaginous changes in the facet joint capsules of patients who had undergone lumbar fusion for degenerative instability.
Chemical model
Changes in load distributions can lead to osteoarthrosis, osteophyte formation, and inflammation [43]. The cartilage and synovium of facet joints are sources of inflammatory cytokines [63]. It has been proposed that painful symptoms may arise not only from mechanical stress discussed previously, but also from the associated inflammatory response involving cytokines such as tumor necrosis factor alpha, interleukin-6, interleukin 1 beta [63, 64], oxygen-free radicals such as nitric oxide [65, 66], and inflammatory mediators such as prostaglandins [63, 64, 66]. Interestingly, some have suggested that inflammatory cytokines originating from inflamed synovium may spread to adjacent nerve roots and produce radicular lower extremity symptoms [63, 67–70].
As with other diarthrodial joints, the cartilage of facet joints may also be sex-hormone sensitive [71]. Estrogen has been associated with chondrodestruction [72], although controversy exists as to its actual role in the development of osteoarthritis [73–76]. However, Ha et al. [77] have found a statistically significant association between the increased expression of estrogen receptors on the articular cartilage of facet joints and the severity of facet arthritis.
Diagnosis
When evaluating a patient with low back pain, the initial differential diagnosis can be broad. While certain symptoms in a patient’s history may suggest systemic disease, neoplasm, or acute nerve compression, the history cannot always differentiate the specific etiology of low back pain. Up to 85% of patients with low back pain do not obtain a specific diagnosis even after work up [78–80]. The diagnosis of facet joint-mediated pain is no exception. The history, physical examination and imaging studies cannot consistently identify facet joint pain [14, 81–86].
A prospective statistical study by Jackson et al. [85], which included 390 patients and examined 127 variables, was not able to identify clinical facet joint syndromes or find predictors of who may respond better to facet joint injections. Furthermore, although pain referral patterns have been identified, investigators have been unable to correlate specific patterns with individual levels [87, 88]. Mooney and Robertson [39] injected hypertonic saline into the facet joints of both symptomatic and asymptomatic patients and noted pain referral patterns that were indistinguishable from pain patterns associated with other etiologies (Fig. 3).
While changes in facet joint architecture can be detected with imaging studies, correlation between radiologic findings and symptoms has also proven unreliable [82]. Although Laslett and colleagues reported clinical guidelines that may be helpful in predicting patient response to facet joint blocks, the study results have not been replicated thus far. At this time, accurately diagnosing facet joint-mediated pain by noninvasive techniques remains a challenge [89].
Currently, the principal method of diagnosing facet joint-mediated pain as the cause of low back pain is through the use of controlled local anesthetic blocks of either the medial branches or the facet joint itself. Both of these techniques have been shown to be equally efficacious [10, 82, 88, 90–92]. These procedures employ the use of local anesthetics with varying durations of action. For example, a short acting local anesthetic such as lidocaine is injected in either the intra-articular facet joint or upon the medial branches. The patient is observed for pain relief that is consistent with the duration of action of the local anesthetic. Days to weeks after the initial diagnostic block, a second block is then employed with a local anesthetic that has a different duration of action such as bupivacaine. Again, the patient is observed for pain relief that is appropriate to the biological properties of the anesthetic. This second injection is referred to as the confirmatory injection. The value of adding a confirmatory block was demonstrated by Schwarzer et al. [7], who by using the protocol outlined above, noted a false positive rate of 38% when a single block was used for the diagnosis of facet joint-mediated pain.
Although the value of a confirmatory block is recognized, the definition of a successful block is controversial. In the above study by Schwarzer et al. [7], a 50% or greater reduction of pain was accepted as a positive block. A 50% or greater improvement in pain as criteria for a successful diagnostic medial branch block has also been used by other investigators [93–98]. Studies that employed diagnostic intra-articular blocks as apposed to medial branch blocks have also used similar criteria of 50% or greater improvement of pain [99, 100, 107]. However, others have suggested that a more strict definition of a confirmatory block is necessary to avoid performing radiofrequency denervation on patients who may have low back pain of other etiologies. When more strict criteria are used, the specificity of a diagnostic block may improve.
Other investigators have employed more stringent criteria as the marker for a positive diagnostic medial branch block. For example, in a 10-year clinical audit examining the efficacy of radiofrequency denervation, Gofeld and colleagues [101] accepted a positive response to diagnostic medial branch blocks only if the patient experienced at least a 70% reduction in pain scores. In a study assessing the efficacy of facet joint anesthesia, Revel et al. [102] considered a positive result only if there was a 75% or more relief of pain. More recently, Dreyfuss and colleagues [106] excluded patients from subsequent radiofrequency denervation if they did not experience at least 80% improvement in pain scores. In a randomized double blind trial examining cervical facet joint-mediated pain by Lord et al. [108], patients were required to experience complete 100% pain relief to be considered as having had a successful diagnostic block.
In a review of the evidence based procedural guidelines that included three randomized controlled trials and two systematic reviews, Hooten et al. [103] proposed the use of 80% or more relief of pain as the standard for accepting a diagnostic medial branch block as successful. This criteria, however, was challenged by a multi-center retrospective clinical data analysis of 262 patients with chronic low back pain who had undergone lumbar radiofrequency denervation. The study group was divided into two groups of patients. The first group included patients who had experienced greater than or equal to 50% but less than 80% pain relief after diagnostic medial branch blocks. The other group represented patients that obtained equal to or greater than 80% pain relief. There was no significant difference between success rates of subsequent radiofrequency lesioning in these two groups [104].
By utilizing more strict criteria for diagnosing facet joint pain, we limit the number of false positive results. However, as the authors of the above study suggest, the use of more strict criteria may be counterproductive and may lead to the withholding of a potentially therapeutic treatment from patients with treatable facet joint-mediated pain.
As we have illustrated, there is a lack of consensus regarding the definition of a successful diagnostic block. Similarly, there is no universally accepted method of how best to perform these procedures. Although intra-articular facet joint injections are generally considered to be more technically challenging, both medial branch blocks and facet joint injections have their share of technical complications. Furthermore, even the use of local anesthesia with both of these procedures has been called into question. Some physicians will administer a local anesthetic to the muscle and fascia in addition to subcutaneous local anesthesia. This technique is simply an attempt to improve patient comfort by anesthetizing the tissue through which the needle will track. A larger number of false-positive results have been reported with this technique [10, 105]. It is for this reason that some support the use of local anesthetic only superficially or of omitting the use of local anesthetic altogether. It is also important to recognize that in addition to the potential confounders outlined in this review, these methods are only as reliable as the ability of the patient to accurately report their symptoms.
With respect to medial branch blocks, most centers utilize a multiple needle approach whereby separate needles are used for each medial branch that is anesthetized. More recently, however, a new technique involving a single needle has been proposed [109]. Although further studies are needed, initial analysis of this single needle technique suggests similar accuracy to that of the multiple needle approach in ability to anesthetize the medial branch with the advantages of increased efficiency and less patient discomfort [110]. It has also been recognized that when performing medial branch blocks, subtle differences in needle position can have important diagnostic consequences. In a cadaveric study, Dreyfuss et al. [111] reported evidence of local anesthetic spread to other structures such as the intervertebral foramina as well as consistent spread to the posterior muscles of the back. Local anesthetic spread to other potential pain generators may decrease the diagnostic utility of these injections. Of note, in this study, when the needle tip was positioned at a point along the inferior aspect of the transverse process, aberrant flow was minimized. This suggests that when appropriate technique is utilized, spread of anesthetic can be avoided and diagnostic utility may be enhanced.
Treatment
Although numerous studies have examined conservative management for low back pain, at the present time, there are no published investigations of conservative management specifically targeted to facet joint pain. However, most experts would agree that the general principles for treatment of nonspecific benign low back pain may be applied. A thorough history and physical exam is always recommended for diagnostic triage. Initial imaging is not necessary unless a specific etiology is strongly suspected or in the presence of “red flag” signs [112]. The use of a multidisciplinary approach is recommended for pain management as it has been associated with improved outcomes [113]. In terms of medications, simple analgesics such as acetaminophen and nonsteroidal anti-inflammatory drugs (NSAIDs) constitute first-line therapy. Acetaminophen has a more favorable side-effect profile since it has not been associated with cardiovascular or gastrointestinal side-effects. However, with chronic use, hepatic injury is a concern. Studies in patients with osteoarthritis of the knee and hip have previously found that NSAID’s provide better analgesia in comparison to acetaminophen [114, 115]. Both benzodiazepine and non-benzodiazepine skeletal muscle relaxants may also provide symptomatic improvement in acute low back pain. However, there is significant controversy regarding the use of controlled substances in the treatment of chronic low back pain [116]. Anticonvulsants such as gabapentin have classically been used for the treatment of neuropathic pain conditions such as diabetic peripheral neuropathy and postherpetic neuralgia [117, 118]. Gabapentin has been evaluated in trials evaluating chronic lumbar radiculopathy [119, 120], and lumbar spinal stenosis [121]. However, these studies were small and had several shortcomings. Studies examining use of gabapentin for facet joint-mediated pain have not been performed. The use of antidepressants, specifically tricyclic antidepressants have shown moderate symptom reduction in patients with chronic low back pain [122, 123]. Again, as with anticonvulsants, trials examining antidepressants specifically for facet joint-mediated pain have not been performed. Although many various adjuvant pain medications have been used to treat radicular and chronic low back pain, there have been no studies to date examining the efficacy of these drugs in patients with documented facet-mediated low back pain.
Interventional treatment: radiofrequency denervation
When suspicion of facet joint-mediated pain is supported by two successful diagnostic blocks, consideration of facet joint denervation may be appropriate. First described by Shealy in 1975 [124], radiofrequency denervation is a procedure that involves lesioning the medial branches with a combination of electric and magnetic fields. If these nerves become insensate from the process, they cannot relay pain from the facet joints. Radiofrequency ablation of the medial branches is now a commonly used procedure to provide more long-term relief of facet joint-mediated pain.
As with diagnostic medial branch blocks with local anesthetic, the technique and protocol employed for radiofrequency lesioning can have significant impact on the success of the procedure. An example of this was highlighted by Bogduk and colleagues in 1987 [125]. Prompted by reports of poor clinical outcomes with radiofrequency lesioning, they reported on the shape and size of lesions made by the radiofrequency electrodes. It was discovered that lesioning occurred around the distal shaft of the electrode rather than directly at the tip. The consequence of this finding is that suboptimal lesioning occurs if the electrode is oriented directly on the nerve in a perpendicular position. This prompted a revision in the accepted technique to incorporate the placement of the electrode parallel to the targeted medial branch.
Radiofrequency denervation has been shown in some studies to provide significant pain reduction in patients with chronic low back pain for 6 [126] to 12 months [93, 106]. However, other studies have shown little benefit to this procedure. In either case, it is important to consider any design flaws and limitations of these studies. For example, Gallagher et al. [126] examined 41 patients with chronic low back pain who underwent either radiofrequency ablation or a sham treatment. The exact definition of a successful single diagnostic intra-articular injection was not adequately described. Nevertheless, there was a significant difference in outcomes observed between the radiofrequency group and sham group at 1 month. However, this was seen only in the patients who had displayed a good response to the diagnostic blocks. The precise procedure for radiofrequency ablation was also not well described.
Van Kleef et al. [93] described 31 patients who had responded positively (≥50% improvement) to a single diagnostic medial branch block and were randomly assigned to either a radiofrequency group or a control group. The control group underwent the identical procedure as the radiofrequency group except for the use of radiofrequency current. One-year follow-up showed statistically significant difference between the treatment and control groups, with higher number of successes (defined as at least 2 point reduction in VAS and 50% pain reduction) recorded in the treatment group. Unfortunately, there were some important limitations. Only a single diagnostic procedure leading to 50% or greater pain relief was employed. There was also a small sample size perhaps leading to sampling error.
A subsequent study by Leclaire et al. [127] involved 70 patients, all of whom had experienced what investigators termed “significant” improvement in low back pain for at least 24 h after a single diagnostic facet joint injection of both lidocaine 2% and triamcinolone. The patients were randomized into control and treatment groups, who received identical procedures with the exception that the control group did not experience lesioning with heated probes. There was no significant difference in any of the outcome measures at 12 weeks, which included functional disability according to the Roland-Morris or Oswestry scales, or pain according to the VAS scores. Although this was one of the larger studies examining radiofrequency denervation, it is also important to note that in this study, only one diagnostic block was performed and there was no set definition of what was accepted as a successful diagnostic block. Only “significant pain relief” was described. Furthermore, the description of the radiofrequency technique is incomplete and it is unclear whether the probe was positioned parallel or perpendicular to the medial branch.
A more recent study by van Wijk [107] represents the largest randomized double blind study examining the efficacy of radiofrequency ablation to date. Eighty-one patients were randomized to radiofrequency ablation or a sham procedure after facet joint pain was confirmed with a two level intra-articular facet joint block. There was no difference in the combined primary outcome (VAS, analgesic intake, and physical activity) measure at 3 months. VAS scores improved in both the treatment and control groups but there was no statistically significant difference between groups. In this study, the authors used a 50% improvement in pain for determining a successful diagnostic facet joint block. However, although the authors recognize that uncontrolled diagnostic blocks may have false-positive effects with a low predictive value, controlled diagnostic blocks were not performed.
Dreyfuss et al. [106] examined the efficacy of lumbar medial branch neurotomy with a thorough and comprehensive protocol, including stringent inclusion and exclusion criteria. Facet joint pain was subsequently confirmed with both diagnostic and confirmatory blocks of the medial branches utilizing an 80% or greater pain relief criteria for inclusion. Care was taken to ensure that the radiofrequency electrode was positioned parallel to the medial branch. Unique to this study is that 6 weeks after neurotomy, patients underwent an electromyogram to determine the presence or absence of denervation potentials. Eighty-seven percent of patients obtained at least 60% relief of pain and 60% of patients obtained at least 90% relief of pain at 12 months. Although technically sound, this study was limited by its lack of a control group.
Although the study examined cervical facet joint pain rather than lumbar facet joint pain, it is important to consider the study by Lord et al. [108] who presented one of the most rigorous protocols to date. This randomized, double-blind controlled trial included patients who had cervical pain after motor vehicle crashes that had undergone successful diagnostic controlled blocks. In order to proceed to radiofrequency ablation, facet joint pain had to be confirmed with not two but three diagnostic blocks of the medial branches employing 2% lidocaine, 0.5% bupivacaine, or saline under strict double blind conditions. The study patient was accepted for radiofrequency lesioning of the medial branches only if they experienced 100% pain relief with the local anesthetic block and no relief when normal saline had been injected. The median time for return of at least 50% of preoperative pain level was found to be 263 days in the active-treatment group and 8 days in the control group (P = 0.04).
Conclusions
Despite some of the pitfalls associated with facet joint blocks, they have been shown to be valid, safe, and reliable as a diagnostic tool [128]. Medial branch denervation has shown some promise for the sustained control of lumbar facet joint-mediated pain, but at this time, there is insufficient evidence that it is a wholly efficacious treatment option. This may be simply because we do not have enough highly-powered randomized controlled studies to support its use. Developing a universal algorithm for evaluating facet joint-mediated pain and standard procedural techniques may facilitate the performance of larger outcome studies. Implementing guidelines for the comprehensive reporting of both patient selection and the various aspects of radiofrequency techniques as outlined by Geurts et al. [129] will in turn, allow us to form more powerful evidence-based conclusions.
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Binder, D.S., Nampiaparampil, D.E. The provocative lumbar facet joint. Curr Rev Musculoskelet Med 2, 15–24 (2009). https://doi.org/10.1007/s12178-008-9039-y
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DOI: https://doi.org/10.1007/s12178-008-9039-y