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Neuromodulation: Technology at the Neural Interface (onlinelibrary.wiley.com) DOI: 10.1111/ner.12206 The Appropriate Use of Neurostimulation: Avoidance and Treatment of Complications of Neurostimulation Therapies for the Treatment of Chronic Pain Timothy R. Deer, MD1; Nagy Mekhail, MD, PhD2; David Provenzano, MD3; Jason Pope, MD1; Elliot Krames, MD4; Simon Thomson, MD5; Lou Raso, MD6; Allen Burton, MD7; Jose DeAndres, MD, PhD8; Eric Buchser, MD9; Asokumar Buvanendran, MD10; Liong Liem, MD11; Krishna Kumar, MD12; Syed Rizvi, MD12; Claudio Feler, MD13,14; David Abejon, MD15; Jack Anderson, MD16; Sam Eldabe, MD17; Philip Kim, MD18,19; Michael Leong, MD20; Salim Hayek, MD, PhD21; Gladstone McDowell II, MD22; Lawrence Poree, MD, PhD23,24; Elizabeth S. Brooks, PhD24; Tory McJunkin, MD25; Paul Lynch, MD25; Leo Kapural, MD, PhD26; Robert D. Foreman, PhD27; David Caraway, MD, PhD28; Ken Alo, MD29,30; Samer Narouze, MD, PhD31; Robert M. Levy, MD, PhD32; Richard North, MD33,34* 21 Address correspondence to: Timothy Deer, MD, Center for Pain Relief, 400 Court St, Ste 100, Charleston, WV 25301, USA. Email: [email protected] 22 23 24 1 www.neuromodulationjournal.com 25 26 27 28 29 30 31 32 33 34 For more information on author guidelines, an explanation of our peer review process, and conflict of interest informed consent policies, please go to http:// www.wiley.com/bw/submit.asp?ref=1094-7159&site=1 * Now retired from Johns Hopkins University. Sources of financial support: This project was supported by the International Neuromodulation Society and was partially funded by a series of unrestricted educational grants from Medtronic, Inc., St. Jude Medical, Inc., Boston Scientific Corp., Nevro Corp., and Spinal Modulation, Inc. No corporate entities had any direct input into the contents of this manuscript or the conclusions of the collaborators. © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 571 Center for Pain Relief, Charleston, WV, USA; 2 Cleveland Clinic, Cleveland, OH, USA; 3 Institute for Pain Diagnostics and Care, Ohio Valley General Hospital, Pittsburgh, PA, USA; 4 Pacific Pain Treatment Center, San Francisco, CA, USA; 5 Basildon and Thurrock University Hospitals, NHS Foundation Trust, Basildon, Essex, UK; 6 Jupiter Interventional Pain Management Corp., Jupiter, Florida, USA; 7 Houston Pain Associates, Houston, TX, USA; 8 Department of Anesthesiology, Critical Care, and Pain Management, General University Hospital, Valencia University Medical School, Valencia, Spain; 9 Anaesthesia and Pain Management Department, EHC-Hospital, Morges and CHUV University Hospital, Lausanne, Switzerland; 10 Department of Anesthesia, Rush University Medical Center, Chicago, IL, USA; 11 St. Antonius Hospital, Nieuwegein, The Netherlands; 12 University of Saskatchewan, Regina General Hospital, Regina, SK, Canada; 13 University of Tennessee, Memphis, TN, USA; 14 Valley View Hospital, Glenwood Springs, CO, USA; 15 Hospital Universitario Quiron Madrid, Madrid, Spain; 16 Arizona Pain Specialists, Scottsdale, AZ, USA; 17 The James Cook University Hospital, Middlesbrough, UK; 18 Christiana Hospital, Newark, DE, USA; 19 Bryn Mawr Hospital, Bryn Mawr, PA, USA; 20 Stanford University, Palo Alto, CA, USA; Department of Anesthesiology, Case Western Reserve University, Division of Pain Medicine, University Hospitals Case Medical Center, Cleveland, OH, USA; Integrated Pain Solutions, Columbus, OH, USA; University of California at San Francisco, San Francisco, California, USA Pain Clinic of Monterey Bay, Aptos, CA, USA; Arizona Pain Clinic, Scottsdale, AZ, USA; Carolinas Pain Institute at Brookstown, Wake Forest Baptist Health, WinstonSalem, NC, USA; College of Medicine, University of Oklahoma Health Sciences Center, Oklahoma City, OK, USA; Center for Pain Relief, Tri-State, LLC, Huntington, WV, USA; The Methodist Hospital Research Institute, Houston, TX, USA; Monterey Technical Institute, Monterey, Mexico; Center for Pain Medicine, Summa Western Reserve Hospital, Cuyahoga Falls, OH, USA; University of Florida College of Medicine, Jacksonville, FL, USA; School of Medicine, Johns Hopkins University, Baltimore, MD, USA; and The Neuromodulation Foundation, Inc., Baltimore, MD, USA DEER ET AL. Introduction: The International Neuromodulation Society (INS) has determined that there is a need for guidance regarding safety and risk reduction for implantable neurostimulation devices. The INS convened an international committee of experts in the field to explore the evidence and clinical experience regarding safety, risks, and steps to risk reduction to improve outcomes. Methods: The Neuromodulation Appropriateness Consensus Committee (NACC) reviewed the world literature in English by searching MEDLINE, PubMed, and Google Scholar to evaluate the evidence for ways to reduce risks of neurostimulation therapies. This evidence, obtained from the relevant literature, and clinical experience obtained from the convened consensus panel were used to make final recommendations on improving safety and reducing risks. Results: The NACC determined that the ability to reduce risk associated with the use of neurostimulation devices is a valuable goal and possible with best practice. The NACC has recommended several practice modifications that will lead to improved care. The NACC also sets out the minimum training standards necessary to become an implanting physician. Conclusions: The NACC has identified the possibility of improving patient care and safety through practice modification. We recommend that all implanting physicians review this guidance and consider adapting their practice accordingly. Keywords: Chronic pain, complications, guidance, neurostimulation, peripheral nerve stimulation, risk reduction, spinal cord stimulation Conflict of Interest: Dr. Deer holds minor stock options in Bioness, Inc., Spinal Modulation, Inc., and Nevro Corp. He is a paid consultant for St. Jude Medical, Inc., Spinal Modulation, Inc., Bioness, Inc., Nevro Corp. and Medtronic, Inc. He has patent relationships with Bioness, Inc., and Nevro Corp. He is an advisor for St. Jude Medical, Inc., Medtronic, Inc., Spinal Modulation, Inc., Bioness, Inc., Nevro Corp., Flowonix Medical, Inc., and Jazz Pharmaceuticals PLC. Dr. Provenzano is a paid consultant for Medtronic, Inc. and St. Jude Medical, Inc. Dr. Pope is a paid consultant for Medtronic, Inc., St. Jude Medical, Inc., and Spinal Modulation, Inc. He is a speaker for Jazz Pharmaceuticals PLC. Dr. Krames holds stock options with Nevro Corp. and Spinal Modulation, Inc. He is a minor stockholder with Medtronic, Inc. Dr. Thomson is a paid consultant for Boston Scientific Corp., British Standards of Industry, and Alcimed (on behalf of Johnson & Johnson). Dr. Raso is a paid consultant for St. Jude Medical, Inc., Boston Scientific Corp., and Medtronic, Inc. Dr. Burton is a paid consultant for Medtronic, Inc. Dr. De Andres has no conflicts of interest to report. Dr. Buchser is a paid consultant for Medtronic, Switzerland. His employer, EHC Hospital, Morges, Switzerland, has received fees for expert testimony that he provided for Medtronic. He has been reimbursed for travel costs by Medtronic, Switzerland. Dr. Buvanendran consults for Medtronic, Inc. Dr. Liem is a consultant for Spinal Modulation, Inc. He is a medical advisor for Boston Scientific Corp. and has received a research grant from Spinal Modulation, Inc. Dr. Kumar is a paid consultant for Medtronic, Inc., and serves on an advisory committee for them. He is also a consultant for Boston Scientific Corp. Dr. Rizvi has no conflicts of interest to report. Dr. Feler has no conflicts of interest to report. Dr. Abejon is a speaker for St. Jude Medical, Inc., Boston Scientific Corp., Medtronic, Inc., Nevro Corp., Cardiva Medical, Inc., and Prim SA. Dr. Anderson has no conflicts of interest to report. Dr. Eldabe is a paid consultant for Medtronic, Inc., Spinal Modulation, Inc. and Mainstay Medical Ltd. Dr. Kim has management/advisory relationships with Medtronic. Inc., Jazz Pharmaceuticals PLC, and Biotronik. He is also a paid consultant for these same companies. Dr. Leong has a management/advisory relationship with Jazz Pharmaceuticals PLC and Covidien Ltd. Dr. Hayek is an advisor for Boston Scientific Corp. and Medtronic. Inc. He is a paid consultant for Boston Scientific Corp., Globus Medical. Inc., Medtronic. Inc., and QiG Group LLC. Dr. McDowell is a paid consultant with Medtronic. Inc., and St. Jude Medical. Inc. Dr. Poree holds stock options in Spinal Modulation, Inc. He was a consultant for Medtronic, Inc. Dr. Brooks has no conflicts of interest to report. Dr. McJunkin has no conflicts of interest to report. Dr. Lynch has no conflicts of interest to report. Dr. Kapural is a paid consultant for Medtronic, Inc., St. Jude Medical, Inc., and Boston Scientific Corp. Dr. Foreman has received research funding from St. Jude Medical, Inc., and Boston Scientific Corp. He is a paid consultant for Boston Scientific Corp., St. Jude Medical, Inc., and Respicardia, Inc. Dr. Caraway owns stock options in Spinal Modulation, Inc. He has a management/advisory role with Medtronic, Inc., Spinal Modulation, Inc., Nevro Corp., Bioness, Inc. and Jazz Pharmaceuticals PLC. He has a paid consulting relationship with Medtronic, Inc., Spinal Modulation, Inc., Jazz Pharmaceuticals PLC, Nevro Corp., and St. Jude Medical, Inc. Dr. Alo is a paid consultant for St. Jude Medical, Inc. Dr. Narouze has no conflicts of interest to report. Dr. Levy holds stock options with Spinal Modulation, Inc. and Bioness, Inc. He is a paid consultant for St. Jude Medical, Inc., Medtronic, Inc., Spinal Modulation, Inc., Vertos Medical, Inc., Bioness, Inc., and Boston Scientific Corp. Dr. North’s former employers (the Johns Hopkins University and Sinai Hospital of Baltimore) received funding from industry (Boston Scientific, Inc.; Medtronic, Inc.; St. Jude Medical, Inc.), as does the nonprofit Neuromodulation Foundation, of which he is an unpaid officer. He has a consulting/equity interest in Algostim LLC. He has multiple patents in the field of spinal cord stimulation. INTRODUCTION 572 Spinal cord stimulation (SCS) and peripheral nerve stimulation (PNS) have become important tools in the medical algorithm of therapies to resolve symptoms from disease processes that involve the central or peripheral nervous systems. The need to better define the appropriateness of the use of these advanced tools has been identified by the International Neuromodulation Society (INS) and has led to the formation of the Neuromodulation Approwww.neuromodulationjournal.com priateness Consensus Committee (NACC) to evaluate the current literature and best practices to form expert opinions on the topic. The purpose is to give guidance to physicians and other healthcare providers on the appropriateness of these advanced treatments, with the goal of improving care for those afflicted with chronic diseases and pain. Spinal cord and peripheral neurostimulation techniques for the relief of pain and improvement in organ function have been practiced since 1967 (1). These neurostimulation techniques are safe, © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION reversible, and effective at relieving pain and improving function and overall quality of life. However, patient selection is of utmost importance to outcomes, and neuromodulation does have recognized risks and complications, although very rarely do complications result in long-term morbidity or mortality. Extensive published reviews suggest that approximately 30% to 40% of patients treated with SCS will have a complication requiring a revision (2–6). The majority of the complications resulting from SCS and PNS are minor and easily reversible with minor surgery and rarely affect patient morbidity or mortality significantly. Hardware-related complications are more common than biologic complications, with leadrelated complications, including migration and fracture, most frequent. Biological complications most commonly include superficial infection and pain over the implant. Devastating technical and biologic complications have both been reported, although these are becoming increasingly rare. The INS reviewed the initial development of medical-based consensus when forming the NACC. Using the template of the consensus and evidence synthesis as described by the Polyanalgesic Consensus Conference for intrathecal therapy, this model was employed for assimilating the evidence and consensus for neuromodulation strategies (7–9). The conference was formulated in association with INS and funded by unrestricted educational grants from Medtronic, Inc., St. Jude Medical, Inc., Nevro Corp., Spinal Modulation, Inc., and Boston Scientific Corp. No corporate entities had any direct input into the contents of the manuscript or the conclusions of the collaborators. Meetings were held throughout the development of the guideline both in round-table fashion and via teleconference. The literature was critiqued using the United States Preventive Services Task Force (USPSTF) criteria for evidence synthesis and level of certainty of net benefit on evidence strength (10) or the Centers for Disease Control and Prevention (CDC) evidence rankings (11). The Steering Committee for the NACC was appointed by the Board of the INS, and all expert participants for the research and formulation of opinion were appointed by the Steering Committee. This is the third of four companion articles addressing a wider analysis of the literature and the practice of neuromodulation for chronic pain. The INS also convened working groups to address the appropriate use of neuromodulation for the treatment of chronic pain and ischemic diseases (7), the treatment of pain of the head and face (8), and the future development and use of new technology, devices, and neural circuitry (9). Overuse, Underuse, and Misuse of Spinal Cord Stimulation The concepts of overuse, underuse, and misuse are increasingly used in discussions of health-care quality, safety, and value-based purchasing. The Institute of Medicine National Roundtable on Health Care Quality defined these terms in 1998 (12). • Overuse occurs when “a health care service is provided under circumstances in which its potential for harm exceeds the possible benefit.” Reducing overuse “improves quality (by sparing patients the unnecessary risk that attends to inappropriate health services) and reduces costs at the same time.” • Underuse is defined as “failure to provide a service that would have produced a favorable outcome for the patient.” • Misuse occurs when“an appropriate service has been selected but a preventable complication occurs and the patient does not receive the full potential benefit of the service.” www.neuromodulationjournal.com © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 573 Quantifying the overuse of neurostimulation is difficult. Since the initial introduction of SCS, there have been wide variations of its use in clinical practice. In the 1980s, SCS was limited to paddletype leads inserted through a laminotomy. In the late 1980s through the 1990s, increasing numbers of minimally invasive trials using percutaneous cylindrical leads were conducted in outpatient settings, either in hospital operating rooms or in outpatient surgery centers. Over the next decade, many, but certainly not all, percutaneous trials with cylindrical leads occurred outside of operating rooms in physicians’ offices (this is still the case today). Once these trials were moved out of operating-room settings, the procedures went unsupervised, and it is believed that some untrained, unqualified physicians started placing these leads strictly for monetary gain, a prime example of overuse. It is important to state that successful outcome for SCS, peripheral nerve field stimulation (PNfS), or combined SCS/PNfS is directly related to how the procedure is performed and on whom. As stated previously, patient selection is foundational to success. Poorly trained physicians have poor outcomes. Whether well trained or not, physicians have been reimbursed per contact on the lead, not by numbers of leads used. With PNfS or combined PNfS/SCS techniques (so-called hybrid SCS), untrained and unskilled physicians were able to collect large fees for low-risk and poor-outcome office procedures. In many cases, abuse occurred, leading to implants being placed regardless of medical need or physician training, and in many cases, physicians in the office setting would place four- or eight-contact leads epidurally or subcutaneously and bill up to $400 per contact for a brief procedure. This practice by the poorly trained and poorly skilled physician who does not understand appropriate patient selection can and does produce an unacceptably low trial-to-permanent-implant ratio and a high explant rate in those who are permanently implanted. Some of these physicians, who have no privileges at a surgical center or hospital for permanent implantation, have no interest in whether or not the patient proceeds to implant. The NACC supports the appropriate training of physicians who are implanters of neurostimulation devices and the use of neurostimulation by practitioners committed to the continuity of care through trial, implantation, and long-term management of patients. There are numerous examples of the underuse of neurostimulation devices. Not using neurostimulation early enough in severe, progressing complex regional pain syndrome (CRPS) exemplifies underuse. A number of authors suggest greater benefit and better functional outcomes with greater economic value if the application of neurostimulation occurs earlier rather than later (13– 16). Additionally, it has been well established that SCS may currently be underused for postlaminectomy syndrome (failed back surgery syndrome or FBSS) when compared with repeat spine surgery (5,16). Many interventional pain physicians are not trained to perform neurostimulation procedures or choose not to perform them, and many do not refer to those who do. This, together with the fact that many physicians other than pain physicians do not know about the benefits of stimulation procedures for pain or feel that the procedure is too costly and invasive for their patients, leads to underuse for patients who need neurostimulation. There also exists the notion in the pain management community that SCS is a procedure of last resort after all other treatments have failed (17). This mindset lingers despite many recent articles touting a change in the treatment algorithm of SCS for pain control and moving it to earlier consideration. The SAFE principles have been in the literature for years and have become the accepted algorithm (16). Pain is the transmission of a series of signals carrying data over a system of nerve synapses to and from the peripheral and central nervous systems. We lack a universally recognized objective DEER ET AL. Table 1. Recommendations of the Neuromodulation Appropriateness Consensus Committee (NACC) of the International Neuromodulation Society (INS) to Mitigate the Risks of, Improve the Safety of, and Improve Outcomes of Neuromodulation Procedures. 1. The NACC recommends that implanters of neuromodulation devices be properly trained and credentialed by either an accredited interventional pain medicine training program or an accredited surgical training program. 2. The NACC recommends that implanters be specially trained in the community standards for the management of preoperative, intraoperative, and postoperative care of the patient undergoing surgical procedures. 3. The NACC recommends that, when possible, neuromodulation surgical procedures performed in operating room theaters be staffed by personnel specially trained in the understanding of the procedure and technologies used. 4. The NACC recommends that neuromodulation therapies be performed for neuropathic pain conditions prior to commencing long-term long-acting opioid maintenance. 5. The NACC recommends that patients being considered for neuromodulation procedures be treated in an interdisciplinary fashion with special attention paid to patients’ pain reduction and emotional and functional restoration. 6. The NACC recommends the use of selection criteria for neuromodulation procedures be based on pain characteristics, including pain location and intensity. 7. The NACC recommends that a psychological evaluation by credentialed psychologists or psychiatrists be performed prior to a trial of neuromodulation therapies to select psychologically appropiate candidates for the procedure. 8. The NACC recommends that patients’ wishes regarding cosmesis, choice of implant, and timing of surgery be considered as part of the preoperative and intraoperative planning. 9. The NACC recommends that prior to the day of trial or permanent implant, the implanter should fully explain to the patient the entire intended procedure, the risks attendant to the procedure, the benefits of the procedure, and the alternatives to the procedure, and receive consent to proceed with the procedure. 10. The NACC recommends that before trialing patients for neuromodulation procedures, the implanting physician discuss plans of the intended procedure with the patient’s non-pain-treating physicians. 11. The NACC recommends the use of an appropriate preoperative assessment checklist and laboratory testing prior to either a trial or permanent implant. 12. The NACC recommends that before implanting a permanent device, a trial for tolerability and efficacy be performed. 13. The NACC recommends that prior to implanting an epidural lead, whether percutaneously or surgically, the patient should be evaluated for risks of anticoagulation and steps be taken to mitigate those risks appropriately before attempting placement of the lead. 14. When placing epidural and subcutaneous leads, the NACC recommends that the procedure be performed in an accredited sterile environment, such as a hospital surgical suite or ambulatory surgery center, using meticulous sterile techniques. If an office setting is used, the facility should meet the same standards as an accredited hospital facility. 15. The ideal anesthesia strategy enables real-time interaction between implanter and patient, thereby allowing the patient to describe the area and intensity of intraoperative paresthesia. If this is not possible, general anesthesia may be considered with somatosensory evoked potential monitoring. 16. The NACC recommends that all patients undergoing either a spinal cord stimulation trial or implantation of a permanent device should receive perioperative antibiotics less than one hour before incision. 17. The NACC recommends that the implanting physician be involved in the preoperative and postoperative care of the patient when possible. 18. The NACC recommends that programming of the neuromodulation device be performed by trained health-care professionals or device company representatives with appropriate patient monitoring and vigilance. 19. The NACC recommends that physicians who offer neuromodulation therapies within their scope of practice employ quality control and quality improvement through monitoring of outcomes, success indicators, and complications of their practice. diagnostic or measurement tool for any type of pain, and the gold standard is the description of pain by the person experiencing it. This reality creates challenges in choosing the right type of therapy and applying it. Neurostimulation is valuable and effective, but for it to be a sustainable clinical tool, we must continue to generate data on quality, safety, and efficacy. Neuromodulation applied responsibly in properly chosen patients should have a low complication rate. Institutional educational requirements and interventional society and consensus guidelines, when followed, should protect patients against the misuse of the technology (16). 574 Analysis, Evidence, and Recommendations The concept of evidence-based medicine is defined as “the conscious, explicit and judicious use of the best current evidence in making decisions about individual patients” (18,19), which means that it is necessary to have credible scientific information available to apply appropriate treatment in clinical practice. Scientific evidence is achieved by analyzing the scientific rigor of available published studies. In today’s clinical practice, it is vital that our use of treatments and existing devices be based on medical evidence and, in cases where deficiency in the evidence exists, that clinical practice be improved by consensus opinion of experts in the field. The NACC recommendations suggested here represent the best availwww.neuromodulationjournal.com able evidence and consensus among the expert authors of this article. Table 1 lists the recommendations of the NACC regarding methods for mitigating risk, improving safety, and improving outcomes of neuromodulation. SAFETY OF NEUROSTIMULATION SCS is generally believed to be a safe procedure, primarily because it is considered minimally invasive and reversible. Unlike long-acting, high-dose, long-term opioid use, SCS is not associated with hormonal and immune system dysfunction, depression, weight gain, hyperalgesia, or the potential for dependence and/or addiction (20–24). Compared with spine surgery, SCS is intuitively safer, but data comparing the two modalities are not available in a synthesized form (5). Permanent neurological deficits and serious spinal cord lesions due to epidural hematoma have been associated with epidural electrode implantation (25–29), although this problem can occur with any epidural intervention. Older criteria for placement of an implantable neurostimulation device required failure or inadequate response to conservative medical management (CMM); thus, the data on comparative therapies are limited (17). The present accepted algorithm for the use of implantable neurostimulation devices for pain control, and the one © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION recommended by the NACC, has moved consideration of neurostimulation therapies from after to before that of the use of longacting opioid pain management or reoperation (5), though still after CMM failure (15,16). The best two examples of comparing neurostimulation therapies with CMM are the PROCESS study for patients with FBSS by Kumar et al. (30) and the CRPS analysis by Kemler et al. (31), both of which suggest superiority for neuromodulation therapies for pain control compared with CMM. Kumar et al. (32) have reported that long-term success is dependent on the underlying pain pathology being treated, with best outcomes reported in cases of refractory angina pectoris, CRPS, and FBSS, and worst results seen with postherpetic/intercostal neuralgia. Pain medicine physicians who are starting their neuromodulation practice would optimize their outcomes by restricting the patients who are trialed for SCS by disease states, with the strongest efficacy data existing for FBSS with predominant leg pain, CRPS, and peripheral vascular disease. FACTORS ASSOCIATED WITH FAILURE OR SUCCESS www.neuromodulationjournal.com The complications of SCS are numerous, and their incidence has been reported at 30% to 40% in multiple studies (40,41) (Table 2). Hardware-related problems such as lead failure and migration are more common than biological complications such as infection, pain, and wound breakdown (54,55). Infection is one of the major complications of SCS, with an incidence of 4% to 10%, and is a common cause for removal of the device and failure of therapy (56). A recent review has recommended an average 18% budgetary allocation per patient per annum for the maintenance of the therapy, including complication management (57). It is important to note that in device-based therapies, the experience of the implanter significantly affects the rate of complications. This has been successfully demonstrated in the case of cardioverter–defibrillator implantation and total hip replacement (58). In their Health Technology Assessment of the therapy, the UK National Institute of Clinical Excellence (NICE) concluded that among the total of 403 permanently implanted patients across all trials examined, four device removals were required (1%), all as the result of infection. Across trials, the percentage of implantations requiring surgery to resolve a device-related complication, including device removals, ranged from 0% to 38%, which may be due to differences in follow-up periods, populations, or clinical settings (59). SCS-related complications have been stratified using various categories. We will first examine patient-related complications that are associated with inappropriate diagnosis or anatomic targeting, the psychological status of the patient, the ability of the patient to comply with device use, and continuing maintenance. Next, we will examine device-related complications, the most common being lead-related complications, such as lead migration or fracture, extension-related complications, disconnection or misconnection, and implantable pulse generator-related complications such as battery depletion,“flipping,” and recharging difficulties. Technique or therapy-related complications include loss of paresthesia or painful or unpleasant paresthesia. These complications are less threatening and can usually be addressed by reprogramming, although, on rare occasions, they can result in therapy failure and device removal. Finally, we will address common biological complications such as deep and superficial infections, the development of hematoma or seroma over the device, and the more common complaint of pain over the implanted hardware. Less frequent biologic complications include dural puncture-related headaches and, more seriously, nerve damage, including spinal cord injury and paralysis (see Table 2). REDUCING THE RISKS OF COMPLICATIONS Rigorous preimplantation screening usually dictates the longterm success rate of SCS therapy. The NACC recommends institution of the following selection criteria for implantation of neurostimulation devices for pain control: • a well-defined, noncancer, physiologic (nonpsychiatric) cause of pain; if the pain is related to cancer treatment or surgical morbidity from tumor resection and the patient is stable, the use of neurostimulation may be considered • after failure of CMM for at least three to six months, but before a reoperation for back surgery, if the patient is neurologically stable • after failure of CMM in patients with mixed or neuropathic pain for at least three to six months, but before consideration of longacting opioid maintenance therapy © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 575 SCS is successful for the treatment of many chronically painful conditions, such as FBSS, chronic back pain, chronic neck pain, chronic radicular pain, chronic neuropathic pain, CRPS, and chronic pain from peripheral ischemia (7). SCS is also used for phantom limb pain, but the results have been mixed. Some authors have found that SCS provides minimal relief, with improvement for only 25% of patients (33,34). When treating chronic pain with neuromodulation devices, such as spinal cord stimulators, it is important to select the appropriate patients to achieve the best outcomes. Multiple indicators can help determine the effectiveness of neuromodulation with SCS; these include the experience of the implanter, the etiology of the patient’s pain, early treatment, the existence of comorbidities that might cause failure or lead to complications, and a wellperformed psychologic evaluation to rule out neuromodulation therapy for patients with psychologic cause for pain, underlying psychoemotional distress, or schizophrenia. Concurrent psychiatric illness negatively impacts success rates of interventional pain therapy (35). An estimated 20% to 45% of patients with chronic pain concurrently suffer from psychiatric illness (36). Specifically, individuals with significantly depressed mood and those with low energy levels were at higher risk of failing their SCS trial (37). In addition, somatization, anxiety, and poor coping were important predictors of poor outcome, according to a recent systematic review of 25 studies (38). However, negative outcomes with these psychiatric illnesses and SCS are no different from those with other surgeries, such as spine surgery or knee replacement. In addition, research has identified other factors that can determine treatment success or failure with SCS. A study involving 410 patients over a 22-year period determined that age, sex, laterality of pain, and number of surgeries before implant did not play a role in predicting the treatment outcome (32). However, the percentage of pain relief was inversely related to the time interval between pain onset and time of implantation, stressing the importance of early consideration of neuromodulation when using a treatment algorithm for pain control. Another study found SCS efficacy to be related to the time between patients’ first surgery in the region of their chronic pain and time of SCS implantation (39). If the patient had less than a three-year delay to implant, success was obtained 93% of the time compared with 9% when there was more than a 12-year delay. Expectation of therapy sustainability needs to be stressed to the patient. NATURE OF COMPLICATIONS DEER ET AL. Table 2. Management of Complications Related to Spinal Cord Stimulation. Complication Occurrence rate Diagnosis Management Prevention Mechanical complications Lead fracture or disconnect 5.9% (32) 9.1% (3) Stimulation pattern has changed. Compare current x-rays to hard x-ray copies of initial implant procedure. Macrofractures of the lead or lead disconnect from the IPG can often be seen on x-ray. Microfractures of the lead (i.e., internal fibers) cannot be seen on x-ray, but impedance testing is often indicative of a fracture. Impedance testing of electrodes should be performed for suspected macro- or microfractures. Stimulation pattern has changed. Compare current x-rays with hard copies of x-rays performed at time of implant. Likely requires disuse of lead and/or replacement of fractured lead; however, sometimes the lead can be preserved by programming “around” the microfracture. Lead fracture frequency can be reduced by using stress loops and appropriate anchoring techniques, by avoiding mobile structures such as joints, and by placing the IPG close to the permanent leads (35,42). Leads may have to be replaced or a paddle lead considered. The probability of lead migration can be reduced by using strain-relief loops near the anchor and generator site, as well as placing the tip of the anchor into the supraspinous ligament. The angle of lead entry, the placement of the battery, and suturing techniques can also affect lead migration (35). Mechanical locking anchors have been shown to secure the leads with a higher tensile strength, and adhesives have been reported to improve anchor clinical performance. The IPG should be placed near the permanent leads. Paddle leads have a lower incidence of lead migration than percutaneous leads. Limiting the patient’s movements (i.e., twisting, bending, lifting) in the postoperative period to allow for scarring of the lead in the epidural space will decrease the incidence of lead migration. Proper testing of device connections can reduce the chances of failure of the battery or IPG. Suture ligature can be placed around lead as it enters the silicone boot of the IPG. This complication can also be mitigated by following the device manufacturer’s recommendations, such as placing the IPG at the recommended depth (35). Lead migration 0–1.37% (43) 13.6% (3) Battery/IPG failure 1.7% (3) Battery failing to hold a charge or work properly. Compare current x-rays with those taken at time of implant. Ask patient about direct trauma to the battery. Battery/IPG failure may require device replacement. Check with manufacturer to rule out known problem with battery. 3.4% (3,32) 10% (44) Patient may complain of nausea, vomiting, fever, chills, and/or malaise, or may not. Physical examination may reveal redness (rubor), warmth (calor), swelling (tumor), pain (dolor), and purulent drainage from IPG site or other incisions. If infection is advanced, the patient may exhibit neurological changes. Consider CT scan with contrast. Consider CBC, blood cultures, wound cultures, ESR, and CRP. May also consider infectious disease consultation or appropriate surgical consultation as warranted. If infection is diagnosed or highly suspected, management usually includes opening the device pocket and removing the device. Cultures of fluid and tissue, along with the IPG, should be sent to microbiology and or pathology for identification of the responsible microbe. Treatment with antibiotics should be directed by the microbial report from culture. Many will consult infectious disease experts for further recommendations. Case reports (46) Patient may complain of itching, malaise, and/or pain. May assess with skin patch test, which can be obtained from device manufacturer. Allergic reactions can be misdiagnosed as infection. Blood work to rule out infection and allergy consult may be helpful. Device removal may be required. Biologic complications Infection Allergic reaction The risk of infection is elevated by immunosuppressive therapy or conditions (e.g., taking steroids, HIV, diabetes), prolonged hospital stay, undergoing multiple surgeries, perioperative transfusions, inappropriate or inadequate antibiotic therapy, poor ventilation of the operative suite, and improper skin preparation at the surgical site (35,42,45). Various patient comorbidities or characteristics also increase the probability of infection and might include, but are not limited to, the comorbid existence of diabetes, rheumatoid arthritis, malnutrition, obesity, and the use of alcohol or tobacco. Antibiotics preoperatively and postoperatively should be given as recommended by the operating facility’s infectious disease standards based on local bacteria and prevalent infections. Neuromodulation implants should be considered high risk for infection similar to a joint implant, and similar precautions should be taken (i.e., limit traffic through OR, thorough scrubbing of area, administer preop antibiotics, use copious irrigation). Administer skin patch test prior to implantation if high preoperative suspicion for allergic reaction exists. Patients can also have allergic reactions to any materials used in surgery (i.e., scrub solutions, sutures, medications, IPG, silicone, latex, other materials) and these sources should all be considered. 576 www.neuromodulationjournal.com © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION Table 2. Continued. Complication Occurrence rate Diagnosis Management Prevention IPG seroma 2.5% (47) Pain, swelling, redness, and/or pain at IPG site. CT scan with contrast. Some will order blood work to rule out infection. Risk of seroma can be mitigated by limiting the amount of aggressive blunt dissection, avoiding excessive cautery, creating a smaller IPG pocket, limiting dead space with a layered closure, and careful hemostasis (48). Also, based on expert opinion, the risk of seroma can be mitigated by preemption using an abdominal binder postoperatively for approximately 2 months. Epidural fibrosis Case reports (35) Stimulation pattern changes. Epidural hematoma 0.3% (35) New neurologic changes that might include paresthesias (with the device turned off), weakness, paralysis, or bowel or bladder changes. More subtle changes might include pain in a new area or worsening of existing pain. Emergency CT scan with contrast and appropriate emergent neurosurgical/spine surgeon consultation. When seromas develop, they can often be treated with abdominal binder and drainage in a sterile environment. Wound cultures can be sent for pathological analysis if infection is suspected. Though scarring is expected around SCS leads, it can alter electrical impedance, preventing therapeutic effect of the device despite otherwise intact hardware and continued coverage (41). Reprogramming of the device can often overcome the effects of epidural fibrosis. Though rare, epidural hematoma formation can result from an SCS trial or implantation. Effective treatment requires evacuation of the hematoma within eight hours of neurologic deficit (49). This is a true neurosurgical emergency and should be managed as one! See above (lead migration, epidural fibrosis, etc.) Changes in stimulation pattern. If not resolved by reprogramming, x-rays should be taken and compared with ones taken at time of implant. May require device replacement, lead revision, or removal. May be related to preexisting or new neurological abnormalities in patient. 2% (51) 0.3% (42) Presence of spinal fluid within the operative field during the procedure or leaking from closed incision after the procedure. Postoperatively, patient may complain of headache (positional headache is the classic presentation); however, some patients, especially the elderly, may not complain of headache in spite of the presence of CSF leak. Dural puncture is more likely in uncooperative patients, those who have previously had surgery at the site, those with spinal stenosis, and patients with a calcified ligamentum flavum (42). Suspected nerve or cord injury Case report (52) Compressive phenomena from leads along nerves or the spinal cord Case reports (53) Patient may complain of worsening pain, paresthesias, weakness, paralysis, or bowel or bladder changes. Complete a thorough neurological examination and emergent CT scan with contrast. Seek emergency neurosurgical and neurology consult. Patient may complain of worsening pain, paresthesias, weakness, paralysis, or bowel or bladder changes. Thorough neurological examination and emergent CT scan with contrast. Seek emergency neurosurgical and neurology consult. Conservative measures for dural puncture may be considered postoperatively (e.g., supine position, caffeine, IV fluids). Some implanters will abandon intraoperative procedure, while others will proceed (continuing at the same level or changing the level of entry). An epidural blood patch is controversial as it may become a nidus for infection (42). Some cases of mechanical damage to the spinal nerve or spinal cord from SCS implantation have been reported (52). Seek emergent neurosurgical and neurology consultation. Decompressive procedures that may include removal of the device leads and/or lamina, other bony structures, or disk may be required. An emergency neurosurgical or spine surgical consult should be obtained. Physiologic complications Stimulation change in coverage pattern or patchy stimulation Dural puncture Patients receiving anticoagulation therapy should be treated according to American Society of Regional Anesthesia 2010 guidelines (50). The use of general anesthesia during lead placement can increase the risk of this type of injury. Multiple attempts at placing needles, passing electrodes, or passing paddle leads increase risk of neurotrauma. Thorough review of preoperative imaging should be performed before SCS trial is initiated. Particular attention should be paid in patients with spinal stenosis. Patients with lumbar spinal stenosis might also have nonclinical thoracic spinal stenosis. CSF visualized 360° around spinal cord at the level of implant should be noted and, if not, consider spinal stenosis as a cause. www.neuromodulationjournal.com © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 577 IPG, implantable pulse generator; CBC, complete blood count; ESR, erythrocyte sedimentation rate; CRP, C-reactive protein; OR, operating room; CSF, cerebrospinal fluid; SCS, spinal cord stimulation. DEER ET AL. Table 3. Procedure Checklist. Preoperative medical issues Check for evidence of active dermal, dental, or urologic infections and treat. Order urinalysis before procedure. Address prior history of infection and make a plan for prophylaxis. Review MRI imaging of cervical, thoracic, or lumbar spine in past 12 months, depending on diagnosis and planned placement of stimulator tip. Discontinue anticoagulation with approval of treating physician for a length of time prior to procedure that is appropriate for the specific anticoagulant and surgical bleeding risk. The appropriate timing for discontinuation should be based on the medication half-life and whether the patient is taking the medication for primary or secondary prevention. Off nonsteroidal anti-inflammatory drugs for 1 week if desired Off acetylsalicylic acid for 7 days Off warfarin or fondaparinux for 5 days, clopidogrel for 7 to 10 days, ticlopidine for 10 to 14 days If patient was on warfarin, order prothrombin time testing for morning of the procedure. Review psychological evaluation. Obtain cardiac clearance in patients at risk for cardiac disease. Review trial films and operative notes in preparation for permanent implant. Evaluate the potential sites of implantation and battery pocket for infection or inflammatory process. If there are any potential technical or patient-specific concerns, communicate with the treating physician and/or the anesthesiologist prior to implant. Educate the patient/caregiver(s). Obtain insurance coverage and document medical necessity. Surgical considerations Assess health status the day of surgery. Have patient empty bladder preoperatively. Obtain baseline pain score. Review postoperative instruction sheet with patient/caregiver preoperatively. Check that adult driver has been arranged to take patient home. Order preoperative antibiotics and administer 30 to 60 min before incision or within 2 hours for vancomycin. Antibiotic doses should be based on the patient’s weight. Arrange for family to stay in postoperative area to observe programming and learn about recharging. Confirm follow-up appointment before discharge. • remedial surgical procedures not feasible or advisable or preferred • any major untreated or unstable psychiatric disorder as determined by a well-performed psychological screening; patients who are found to have significant somatization complaints should be excluded • discussion of therapy expectations • elimination of inappropriate drug use before implantation • absence of unresolved issues of secondary gain or litigation that could potentially be central to the propagation of the pain complaint • capacity to give informed consent for the procedure • possession of the cognitive ability to operate SCS equipment • preoperative MRI or CT myelogram of the spine (within 12 months) to rule out pathology that might confound diagnosis and/or compromise outcomes of SCS • life expectancy greater than 12 months • patient willingness and agreement to follow institutional protocol for follow-up visits. For patients selected for SCS, Table 3 presents a procedure checklist. PATIENT-RELATED COMPLICATIONS 578 In the properly selected patient, the result of neurostimulation is very promising. There are several common and preventable pitfalls the implanter should consider before the final step of implanting a permanent device. www.neuromodulationjournal.com • The type of pain should be considered; for example, the use of SCS to treat osteoarthritis is likely to fail. • The patient’s cognitive ability should be considered when choosing the device; for example, the implanter may choose a nonrechargeable implant if the patient has difficulty understanding the charging process. • The placement of the generator should be based on the patient’s ability to rotate the shoulder in order to access the site of implant. Other factors to be considered include bony landmarks, skin pathology, and garment preferences. • The patient, and caretakers when applicable, should be willing to participate in both preoperative and postoperative educational programs as recommended by the implanting doctor. DEVICE-RELATED COMPLICATIONS System Malfunction Despite recent improvements in SCS systems, complications from system malfunction have been a significant historical concern. In 2004, Cameron reviewed SCS complications over 20 years (1981– 2003) in 51 papers that totaled 2972 patients (3). Complications were categorized as either technical (lead migration, lead breakage, over- or understimulation, intermittent stimulation, hardware malfunction, loose connection, and battery failure) or biologic (infection, epidural hemorrhage, seroma, hematoma, paralysis, cerebrospinal fluid [CSF] leakage, pain over the implant site, allergic reaction, skin erosion, and other reaction specific to an implantable pulse generator [IPG]). The most common of these were lead migration (13.2%), lead breakage (9.1%), infection (3.4%), hardware © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION malfunction (2.9%), unwanted stimulation (2.4%), and battery failure (1.6%) (3). In 2012, Medtronic Neurologic Inc. (Minneapolis, MN, USA) published a similar review from their Implantable Systems Performance Registry (ISPR). This product report prospectively enrolled 1983 SCS patients from 43 domestic centers over seven years (June 2004 through July 2011). An adverse SCS event was defined as any related to a device, implant procedure, and/or therapy. A total of 973 events were reported, 30% (295) of which were categorized as product-performance-related and the remaining 70% (656) as not product-performance-related (60). The majority (96.3%) of product performance-related events involved the lead or extension (migration/dislodgment/fracture/high impedance), with the remainder (3.7%) primarily involving the IPG (undesirable stimulation change, difficulty charging or programming, and issues with the tract or pocket). The majority (90.2%) of non-product-performancerelated events involved the IPG and included expected battery depletion, ineffective therapeutic response, pocket site pain, infection and wound dysfunction, and undesirable changes in stimulation (60). Despite three decades of investment in electrode materials, anchoring systems, education, training, and platform technologies, the Cameron and ISPR reviews underscore the fact that SCS system malfunction remains a significant clinical challenge. SCS system malfunctions can now be generally classified as hardware failures (electrode breakage/migration and loose anchoring or connections) and battery failures (primarily programming issues and depletion). www.neuromodulationjournal.com Battery Failures Depending on the type of SCS system, power consumption of the battery or “battery depletion” is dependent on the model of the IPG, electrode location, hours of active therapy/use, and programmed parameters. The current types of implantable devices include external battery-powered radiofrequency (RF)-coupled devices; totally implantable, nonrechargeable IPGs; and totally implantable, rechargeable IPGs. The longest-lasting implants should theoretically be RF-coupled devices, as they couple a 9-V battery-driven external transmitter telemetrically to a subcutaneous receiver. Unfortunately, the therapy burden to the patient is often high because the external belt and frequent battery changes are cumbersome and limit the hours/day of active therapy/use. Painful subcutaneous receivers leading to complete system explantation have also been reported in 47% of 80 systems within three years (72). In the Alo series, chest wall hyperesthesia from electrode fracture and/or broken connection led to an inability to couple transmitter with receiver. This same phenomenon was also described by Heidecke et al. in 2000 (73). In contrast, fully implantable IPGs have no external belts, do not require battery changes, and have improved connections and a much lower rate of pain at the implant site—0.1% in the ISPR of Medtronic and 2.9% combined in the Matrix and Itrel 3 prospective studies (53). As such, IPGs have the potential for significantly more hours/day of active therapy and overall less therapy burden compared with RF. Nonetheless, all rechargeable and nonrechargeable IPGs ultimately require battery explantation and/or replacement. As most nonrechargeable IPG platforms were just being introduced when the ISPR began its enrollment, it is one of the first reports to track depletion rates of both rechargeable and nonrechargeable IPGs. Interestingly, the 35% expected battery depletion rate for the combined ISPR (234/656 non-product-performance, ISPR events) compares favorably with the 43.7% battery-depletion rate described by Abejon et al. in a study of nonrechargeable IPGs only, which terminated just before the ISPR began (74). Finally, when a battery requires replacement before the expected date (determined by the use parameters), it is considered an unexpected battery failure. Unexpected battery failure of a fully implantable IPG occurred in 32 (1.7%) of the 900 cases reviewed by Cameron through 2004, although 22 of 32 of those occurred after more than the expected three-year battery duration (3). The ISPR did not specifically report on the rate of premature depletion for either rechargeable or nonrechargeable fully implantable IPGs. The remainder of the SCS system malfunctions described in the literature are numerous but much less frequent than the hardware and battery failures just outlined. Reported complications include bacterial infection (including methicillin-resistant Staphylococcus aureus or MRSA), subcutaneous or epidural hematoma, skin erosion, aseptic meningitis, headache, asthenia, dizziness, muscle spasms, postdural puncture headache (related to the needle, guide wire, leads, or surgery), electromagnetic interference (external or deviceto-device), neurologic injury, device-tissue reaction, erythema, erosion, and allergy (3). Despite recent improvements in SCS platforms, complications from system malfunction remain an evolving concern. While lead © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 579 Hardware Failures Lead and/or extension migration (or breakage) may result in a loss of paresthesia and pain relief. If reprogramming cannot recapture paresthesia/pain overlap, then reoperation to replace the lead over the spinal target/level that produces paresthesia/pain overlap may be needed. On the topic of reprogramming, North et al. and Alo et al., in separate articles, have described the improved paresthesia recapture of multichannel systems and reduction in reoperation rates (61–63). Specifically, North’s group noted that surgical revisions were required for 16% of single-electrode multichannel devices and 23% of single-electrode bipolar systems, while Alo’s group reported even fewer revisions when dual-electrode multichannel systems were applied (3.7%). Subsequently, others have published similar dualelectrode findings (64). Andersen also reported a lesser reoperation rate for single-electrode quadripolar (11%) vs. single-electrode monopolar (23%) systems when treating angina (65). Changes in stimulation paresthesia (e.g., uncomfortable intensity, character, or pattern) may occur as the result of postural changes that alter electrode position within the epidural space relative to the spinal cord or because of changes in tissue impedance around the electrodes (66–69). These changes in electrode position within the epidural space relative to the spinal cord can cause patientperceived painful stimulation, ineffective stimulation, or loss of stimulation over time and may contribute to therapy failure. Cameron and Alo reported on the postural effects in patients in whom a percutaneous SCS electrode was implanted (67). They described differences in perceived stimulation thresholds between the cervical and thoracic spine when lying, sitting, or standing. These statistically significant changes were the result of spinal cord movement and the thickness of the CSF layer at the level of the implant. Lower described thresholds were due to both smaller CSF layers and the electrode being close to the spinal cord (67). The further contributions of tissue impedance to changes in perceived intensity were in part detailed by Alo et al. (69). If changes in posture or tissue impedance produce significant increases in intensity or intolerable dysesthetic or motor sensations, therapy failure rates may increase (70). In an attempt to offset spinal cord movement in real time, an adaptive electrode position-sensing system has recently been introduced (71). DEER ET AL. Table 4. Troubleshooting Implantable Pulse Generator Problems. Problem Possible solution Generator depth too deep Generator upside down or flipped Surgical revision Surgical revision; consider anchoring at time of implant Replacement of external generator Patient education External programmer malfunctioning Patient inability to understand or maintain the device Loss of communication leads Impedance measurement; probable surgical revision fractures and migrations have benefitted from improved anchoring and implant advances, the longevity of rechargeable batteries and new electrode geometries remain significant unknowns. In an era of evidence-based medicine, increasing pressure from regulators and third-party administrators will focus on the historical and future costs associated with SCS system malfunction (56,75). Communication and Generator Problems The placement of an IPG is an essential part of the procedure to create a neurostimulation system. Unfortunately, in some cases external telemetry devices cannot communicate with the implanted programmable IPG, leading to treatment failure of the system. Table 4 lists some common causes of IPG problems and potential solutions. Percutaneous vs. Paddle Electrodes A percutaneous electrode offers relatively easy access to multiple spinal levels and thus facilitates paresthesia mapping. A surgical plate/paddle electrode, however, might be required for screening if a percutaneous catheter electrode cannot access the epidural space satisfactorily, for example in a patient who has undergone a previous laminectomy or posterior fusion at the level of insertion. There is no inherent difference in the fracture rates for these two types of electrodes (7). Device–MRI Compatibility 580 Background The clinical use of MRI for anatomic diagnosis and, therefore, management of various disease states is well established and is the standard of care worldwide for imaging in many medical conditions. Not surprisingly, utilization of MRI has increased tremendously in the past 10 years, although often inappropriately (76). Thus, when considering the use of SCS to treat chronic pain or other indications, a potential limitation for neuromodulation is the lack of sanctioned MRI compatibility with these devices. All neurostimulator manufacturers have labels warning that exposing a patient with an implanted neurostimulation system or component to MRI may potentially injure the patient or damage the system. The intrinsic hazards of MRI exposure to patients with an SCS system result from one or more of the main components of the MRI environment (77,78): the static magnetic field, the static magnetic field spatial gradient, the gradient magnetic field, and RF energy produced by the MRI. The absorption of RF radiation constitutes the specific absorption rate (SAR), typically indicated in units of watts per kilogram (W/kg). When interacting with an implanted medical www.neuromodulationjournal.com device, these magnetic fields can induce a rotational force (torque) upon the device, which may result in tearing of the surrounding tissues. Moreover, rotation to align the object with the field, translational force exerted upon the device, and acceleration of the object into the bore of the magnet (the so-called “missile effect”) may also cause tissue damage. Additionally, current induction due to the rate of change of the magnetic flux density over time (tesla [T]/sec) may result in device malfunction or failure, and RF-induced currents may cause device heating and thermal or electrical burns to the patient. Less concerning, but still important, are the effects of the medical device on the operation of the MRI scanner, which may result in poor-quality images due to excessive electromagnetic emission. In the presence of an IPG or lead in or near the imaging field of view, image degradation is to be expected (distortion, artifacts, etc.). Although ex vivo (79–81) and in vivo (77) MRI compatibility of SCS systems have been tested on 1.5-T and 3-T MRI scans, according to the most recent Food and Drug Administration (FDA)-recognized terminology (82), an implantable SCS system cannot be considered as “MRI safe” because some of its parts cannot be classified as nonconducting, non-metallic, and non-magnetic. However, prior to the recent FDA approval of an MRI-compatible SCS system, the FDA had only approved safety language for Medtronic SCS systems for MRI examinations of the head only, using an RF transmit/receive head coil, under very specific conditions with MRI parameter adjustments. Recently, Medtronic received approval in Europe and the USA for the first implantable neurostimulation system for use for the treatment of leg and/or chronic back pain designed to be compatible with full-body MRI scans under specific conditions. With this new system, unwanted movement of the entire device is reduced by the minimal presence of ferrous material. The lead is shielded, reducing the risk of thermal tissue damage by dispersing RF energy along its entire length, and a filter in the IPG shunts RF energy from the lead to the outside of the neurostimulator, protecting internal circuitry from damage (83). Discussion Safety is paramount when using MRI in patients with implanted SCS systems because the interaction of MRI and SCS is complex. Evaluating the potential risk of exposing a patient with conventional SCS systems to the MRI environment must include consideration of magnetic field interactions, heating, induced electrical currents, implant damage, and functional/operational disruption. Many factors affect the heating profile for a given device, including • the electrical characteristics of the particular neurostimulation system • the field strength of the MR system • the orientation of the IPG • the presence of an extension cable • the location of the leads in relation to the site of imaging • the type of RF coil used (transmit/receive body coil, transmit body coil with receive-only head coil, transmit/receive head coil) • the anatomic region being scanned • the amount of RF energy delivered • how the SAR is calculated for a given MRI system MRI safety criteria, defined by using a particular neurostimulation system and/or utilizing a given MRI system configuration, may not be readily applied to other neurostimulation systems (84). Currently, more universal and appropriate measures are required in order to guide MRI safety recommendations for neurostimulation across different systems and platforms (85). The interaction between the MRI system and configuration used and the SCS system is not only a safety issue, it may also cause MR image quality corruption. The size of the artifact for an implant or © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION device may affect the diagnostic utility of MRI. Information is typically provided in the SCS device label that characterizes the size and shape of the artifacts associated with certain pulse sequences. Therefore, it may be necessary to optimize MRI imaging parameters for the presence of an SCS implant. www.neuromodulationjournal.com Device Removal There are many reasons for device removal, including persistent or overwhelming infection, therapy failure, persistent pain over hardware, skin erosion, and necessity of an MRI. Device removal is not reported in all SCS studies. The review by Turner et al. reported a device removal incidence of 11% with a median figure of 6% and a range of 0% to 47% (54). The authors did not elaborate on the causes for device removals. Brazzelli et al. noted a device-removal incidence of 9% for sacral neuromodulation (SNS) (94). Verrills et al. described two cases (2%) of hardware failure and removal in PNfS (95). TECHNIQUE-RELATED COMPLICATIONS Appropriate Training and Mentorship The NACC recommends that improvement of outcomes for implanted neurostimulation devices must include setting higher standards for the training and quality of potential implanters. Implanters should have undergone training in a recognized, highvolume center with proper credentialing. During formal training the implanter should ideally perform a minimum of 10 cases as the primary implanter and under supervision. Appropriate training should include patient selection and contraindications to intended procedures, the anatomy of the intended implant area, complication identification and management, and collaboration with colleagues. The implanter should be comfortable with troubleshooting during the implantation procedure and with the methods and techniques used to achieve proper stimulation, while maintaining patient and implanter safety. The implanter should be able to recognize and treat hardware-related and biological complications and should be able to recognize the benefits and pitfalls of various commercial leads and lead types and their specific indications. It is obvious that only neurosurgeons should perform intracranial procedures and only trained surgeons should perform surgical laminectomies for implantation of SCS systems. High cervical SCS should be performed only by those with extensive experience with SCS system implantation via a percutaneous or open surgical approach. Although implanters may choose to implant trial extracranial systems in an office setting, they must obtain privileges to perform implantation in an accredited hospital setting, properly certified surgical center, or similar facility. This recommendation varies from country to country, but the NACC recommends that any physician who cannot receive privileges to do these implants in a hospital of good standing should cease from implanting. The NACC does not recommend performing permanent implantation of any of these devices in the office setting. © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 581 Recommendations MRI should not be considered for patients with neurostimulation systems that are not MRI-compatible if other potentially safer diagnostic methods, such as CT, radiography, or ultrasound, will provide adequate diagnostic information. It should be noted that the risk of developing cancer from CT scan radiation is rare, although important public health implications in the future may exist (86–88). However, given that radiation-induced cancer is greatly reduced among those requiring CT after age 60, this may not be clinically significant. In light of the relatively high lifetime risk of requiring advanced imaging and of concerns related to the risk of CT scanning, all patients, and especially those with multiple medical risk factors that would lead to use of such imaging (e.g., those at increased risk for stroke), should be informed about the MRIcompatible alternative SCS system. Several authors have designed strategies to offer a measure of safety for MRI explorations in patients with conventional SCS systems when MRI is required. These strategies involve the patient (information, capacity to report complications), the MRI system (tesla and SAR specifications), the neurostimulation system (programming and pre- and postradiological exploration adjustments) (77), and the presence of a health-care provider with expertise in programming the system during the examination (89). Patients who require MRI over other imaging modalities (e.g., those with malignancy that requires MRI monitoring, demyelination diseases, or specific biliary problems) should be told by the implanting physician that there exists an MRI-compatible alternative system. If MRI imaging is essential in patients with MRI-incompatible SCS systems, the amplitude should be set to 0 V/mA and output turned off. The approach to the MRI bore and activation of the MRI magnet should be done slowly and under careful supervision. The SAR rating must be the lowest possible value and never more than 0.9 W/kg. Perhaps the most feared physical risk associated with MRI exploration in patients with an SCS is heating of the generator and/or tip of the lead and the electrodes due to the variable magnetic fields and pulsed RF fields elicited by MRI signals (90). This generated heat may result in heat-induced lesions, such as burns at the site of implanted components. A burn from magnetic- induced currents to the lead tip could result in neurologic disaster. In general, scientific guidelines provided either by radiologists or implanting physicians consider the use of MRI in patients with an implanted SCS system to be a relative contraindication. Besides injury to the patient, a second major problem with MRI utilization in patients with an SCS device is direct damage to the device itself. While there have been series of cases reported without problems, concerns remain. Field strengths as low as 10 G may be sufficient to cause deflection, programming changes, or closing of switches. Therefore, in a patient with an SCS system, the initial recommendation is to utilize other imaging modalities if at all possible. If MRI is required, the advice of a radiologist should be sought and, depending on imaging site and sequencing, imaging may be possible. Nevertheless, MRI compatibility of implantable SCS devices has been examined previously in vitro, and the devices were shown to be safe and therefore were labeled as MRI-conditional (82). The application of a strict protocol, based on safety criteria previously established in relation both to the MRI technique (91) and to programming of the neurostimulation system (90,92), results in low patient morbidity. For several years, various centers have performed a variety of MRI examinations with few reported complications (93). With the elimination of ferromagnetic components and new specific designs and structures, SCS systems will become increasingly safe. At the same time, the power of the magnets of the MRI will be increasing and technologies evolving. (Current MRI-compatible systems were tested using 1.5-T scanners, not the commonly employed 3-T scanners.) Therefore, the NACC proposes an evolutionary strategy, adapted to the evolution of the technology itself. In conclusion, current recommendations for safety and quality imaging in the performance of MRI are summarized in Table 5. If an MRI is attempted, the ordering physician and radiologists should carefully weigh the risk-to-benefit ratio and discuss it with the patient and the family. Careful and deliberate education is a critical part of this decision. DEER ET AL. Table 5. Neuromodulation Appropriateness Consensus Committee Recommendations for Quality Magnetic Resonance Imaging (MRI) in a Patient With a Neurostimulator That Is Not MRI-Compatible. In some settings, implanting physicians have opted to order MRI in patients with entire systems or components that have not been labeled as compatible (these include most currently implanted systems). The NACC does not endorse this decision, but is providing guidance to those who choose that path. Patient • If possible, do not sedate the patient and monitor so that the patient can provide feedback of any problems during the MRI examination. • The implantable pulse generator side of patient’s skin should not be in contact with the inner bore of the magnet. • Carefully position the body part relative to the transmit coil. • Report to the radiologist the specific type of neuromodulation system implanted. • The patient should be responsible and educated about the spinal cord stimulation system and able to communicate any problems to a health-care professional. Problems may include “heating,” paresthesias, or pain. Radiologist • Monitor the patient both visually and audibly. • Follow manufacturer/device-specific protocols for the following: o Field strength and radiofrequency wavelength o Type of transmit radiofrequency coil o Amount of radiofrequency field pulsed during imaging (= energy delivered) o Amount of specific absorption rate and technique to calculate o Gradient magnetic field (pulsed during imaging) induced currents due to dB/dt Implanting physicians • Patients should be told that an MRI-compatible SCS system alternative exists, and the physician should comment on the benefits and limitations of acceptable, existing systems and weigh the MRI issue compared with other factors that may impact outcomes. • Inform the patient of all of the risks of undergoing an MRI examination with conventional spinal cord stimulation systems. This should include the fact that many implanting doctors do not perform MRI in these patients. • Test for possible open circuits that might exist by measuring impedance on all electrodes. If a broken lead wire is suspected, do not perform an MRI examination as higher-than-normal heating may occur. • Implanted system leads or wires should not form large-radius wire loops. • Specify when ordering an MRI the type and electrical characteristics of neuromodulation system complications. • Personnel experienced in programming must be available before, after, and preferably during the MRI. Perioperative Preparation Before implanting a device, the physician should consider the amount of anatomical space within the epidural space required for the lead or leads. Patients with lumbar or cervical spinal stenosis may have asymptomatic thoracic spinal stenosis as well. In awake patients for whom a percutaneous lead placement is planned, the ability to access the patient’s response during the implant procedure is essential. In cases where the clinician is unable to converse with the patient or where concerns about spinal stenosis exist, the clinician should order an appropriate imaging study to assess spinal diameter before implantation of either the trial or permanent lead. Imaging options include MRI, CT, and CT myelogram. If at reading the MRI or CT no CSF can be seen around the cord, an implant should not be done without prior surgical decompression of the stenosis. 582 Surgical Technique: Insertion, Anchoring, and Suturing Hardware failures due to anchoring or tunneling technique have been an issue since SCS systems were introduced in the 1960s. Despite the application of many different tunneling and anchoring tools, lead migration and fracture rates remained high into early 2006 (6). At that time, multiple soft silicone or hard plastic devices were still in use, none of which was consistently reliable over the preceding four decades. Out of frustration and necessity in early 2000, Alo et al. began using a figure-eight silk suture“drain stitch”strain-relief loop directly between the electrode and the subcutaneous tissue (96,97). That simple technique unexpectedly eliminated lead fractures and migrations from the authors’ clinical practice, which had previously exceeded 20%. This experience led to a bench evaluation by Kreis et al., who studied the integrity of the electrode–suture interface under high-power microscopy (98). Specifically, a total of 56 www.neuromodulationjournal.com surgeon’s knots or “drain stitches” were tied around 28 electrodes under tension and then evaluated for evidence of microscopic insulation or contact disruption. With none of the electrodes showing disruption and the initial concern of iatrogenic fracture mitigated, Kreis et al. began uniformly applying and monitoring the technique clinically with similar results to Alo et al. Anatomic variations of this technique were subsequently developed by Mironer et al. and more recently by Bowman et al. (99,100). A key factor for decreasing lead migration is choice of suture. Many implanters use a nonabsorbable braided polyethylene terephthalate suture (i.e., Ethibond, Ethicon Inc., Johnson & Johnson, Somerville, NJ, USA) rather than silk for both strength and visibility (because of its blue color). Greenwald et al. demonstrated that all sutures decreased in strength, strain, and toughness over time except for Ethibond, with silk losing the greatest strength and toughness (101). Although silk is often classified as a nonabsorbable suture, it nonetheless degrades in tissue at a variable rate. In concert with the aforementioned, a formal clinical evaluation of specific electrode failure modes was carried out by Rosenow et al. in 577 systems (6). The breadth of this study subsequently led to a modeling evaluation of electrode insertion angles (skin and sublaminar), tunneling tools, and anchor engineering assessments (102). This evaluation by Henderson et al. emphasized the need for implanters to apply a shallow needle insertion angle at the skin and sublaminar entry points, as well avoiding electrode kinking at the fascial plane. This insertion and suturing strategy, which was not previously addressed by the soft silicone or hard plastic anchors, seemingly abated fracture, migration, and subsequent failure. Shortly thereafter, “slip lock” anchoring devices with improved holding forces were introduced, which minimize electrode fatigue and markedly reduce migration and fracture rates (103–105). Lead migration and anchoring techniques will be addressed later in this article. © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION Anesthesia Local anesthesia supplemented by conscious sedation is used for the majority of cases involving SCS cylindrical lead implantation. The use of local anesthesia at the time of implant enables the implanter to interrogate the patient about the location of stimulation-induced paresthesia coverage. This is important to ensure an accurate overlap between the dermatomal distribution of pain and the paresthesia. Failure to check paresthesia coverage results in less than satisfactory pain relief. Where the cooperation of the patient is lacking, general anesthesia may be considered. In such a case, the implanter may use somatosensory evoked potentials (SSEPs) to verify if stimulation-induced paresthesia will cover the distribution of pain upon patient awakening. Placement of surgical leads can be accomplished using local analgesia with conscious sedation but has the drawback of patient discomfort during the laminotomy procedure. As a result, some implanters prefer to place laminotomy leads using epidural anesthesia (106,107). Other surgeons use general anesthesia, which may require the use of SSEPs. Kumar et al. have demonstrated that spinal anesthesia for lead implantation overcomes the problem of painproducing laminotomies in the awake patient, yet does not block the perception of stimulation-induced paresthesias. These authors have performed more than 200 cases successfully using spinal anesthesia in the last three years without adverse outcomes. It should be noted that spinal anesthesia will inhibit the perception of painful stimuli but not the paresthesia felt on stimulation of the dorsal columns. The threshold amplitude for spinal anesthesia is 2 mA higher than that required for local anesthesia (108). Preoperative Education and Postoperative Care Patient education helps set realistic expectations for SCS therapy and helps engage the patient, family, and caregivers in the therapy. A discussion of the intended procedure should address the patient’s cosmetic concerns. Preoperative instruction may include a description of neurostimulator components, the goals of therapy, the purpose of the trial, the implant procedure, the possible risks and complications, and the importance of follow-up care. A written list of preoperative patient responsibilities can reinforce verbal instructions. This list may cover the date, time, and location for the procedure and reminders to obtain previous imaging studies, to require the patient to stop specific medications before trial and implant, to call to cancel the procedure should the patient become ill or choose not to undergo the procedure, to bathe with appropriate prep material before surgery, and to arrange for transportation to and from the surgical suite. Postoperative care/discharge instructions can be distributed on the day of the trial or implant. The patient/ caregivers should know how to contact the physician or clinic if questions arise or complications occur. SPECIFIC COMPLICATIONS www.neuromodulationjournal.com © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 583 Lead Migration Lead migration is by far the most common complication of spinal and peripheral nerve stimulation (Table 6). The majority of the instances of lead migration require minor reoperation to relocate the lead to its original position, and most will incur the cost of a new lead. Lead migration rates vary greatly between studies, with some quoting figures as high as 60% to 100% but the majority quoting figures of 10% to 25% for SCS. This variation can be explained by varying implanter experience, differing clinical context of the therapy, and varying clinical practices. It has been suggested that lead migration following surgical paddle lead implantation is less common than with percutaneous cylindrical leads and that location of the lead in the spine may influence the rate of migration, with higher rates occurring where the lead is implanted in a highly mobile area of the spine (3). However, evidence to the contrary also exists (5,116). Most reviews do not differentiate between vertical (craniocaudal) and lateral (horizontal) lead migration. In a 20-year literature review of SCS, Cameron (3) reported 361 lead migrations in 2753 patients, an overall migration rate of 13.2%. In two systematic reviews of 18 studies of SCS for FBSS and eight studies of SCS for CRPS, Taylor et al. (109,113) reported lead-related complications to be 27% and 20%, respectively. There was no breakdown of these numbers as to lead fractures or lead migrations. In a retrospective review of 410 patients over a 22-year period, Kumar et al. (32) reported lead migrations in 88 patients (21.4%), of which 40 leads were repositioned and 48 replaced. In a more recent retrospective review of 707 patients, Mekhail et al. (56) reported an initial lead-migration rate of 0.7% during the trial period, but a subsequent 22.6% eventually developing lead migration. Turner et al. (54) systematically reviewed 22 studies of SCS; they did not report a rate of lead migration but instead reported a 23.1% mean rate of stimulator revision for reasons other than battery change (median value 21.5% and a range of 0% to 80%). In their discussion, the authors acknowledged that the majority of these occurrences were related to lead migration; however, it is not possible to estimate how many of these events were related to lead malfunction instead of migration. The authors did not elaborate on the numbers of patients requiring revisions. In the PROCESS study (44) at 24 months, nine lead migrations had occurred in six of 42 (14%) patients. All six patients required surgery to reposition the leads. In a further randomized controlled trial (RCT) comparing SCS to reoperation, North et al. (5) reported three of 33 (9%) patients requiring lead revision due to migration or malposition. It is important to note that some of the patients in this study received surgical plate leads. These are reported to be associated with lower migration rates compared with the more commonly used cylindrical percutaneous leads (110,116), although work by Rosenow et al. suggested the converse (6). In a systematic review of seven RCTs and 47 case reports of SNS for functional urinary bladder stimulation, Brazzelli et al. (94) concluded that the rate of lead migration in this therapy was 16% despite the use of tined leads. In the largest of case series reporting on the use of PNfS for pain relief, Sator-Katzenschlager et al. (114) and Verrills et al. (95) reported rates of lead migration of 13% and 2%, respectively. The large difference in lead migration between these two studies may well relate to the multicenter nature of the first study compared with the second, which reports on the results of a single-center practice. A lead migration rate as high as 100% was reported in a case series of occipital nerve stimulation (ONS) at three years, with the rate being 60% at the end of one year (117). Lead migration occurred in 12 of 51 subjects (24%) in the ONSTIM study of ONS (112). The high percentage of lead migration for ONS may be due to anatomic location (head vs. thoracic placement), neck mobility, or poor anchoring technique. For conventional thoracic placement of SCS leads in the hands of experienced implanters, a lower incidence is accepted as standard. Lead migration can occur due to poor anchoring technique and/or failure of the anchor. SCS leads can migrate longitudinally (cephalocaudad in an axial direction) or transversely (laterally) in the epidural space. Lead migration occurs most commonly in the cephalocaudad plane. Lateral or transverse migration is believed to be relatively less common than vertical migration, and the mechanism is less well understood (32,102). DEER ET AL. Table 6. Reported Rates for Complications of Spinal Cord Stimulation. Publication Therapy type N Lead migration (%) Cameron 2004 (3) Review Taylor et al. 2006 (113) Systematic review Taylor et al. 2005 (109) Systematic review Kumar et al. 2006 (32) Retrospective analysis Mekhail et al. 2011 (56) Retrospective analysis Turner et al. 2004 (54) Systematic review Kumar et al. 2008 (44) Randomized controlled trial North et al. 2005 (5) Randomized controlled trial Total SCS SCS 2753 13.6 Lead fracture (%) Brazzelli et al. 2006 (94) Systematic review Saper et al. 2011 (112) RCT Schwedt et al. 2007 (117) Retrospective analysis Paemeleire et al. 2010 (111) Retrospective analysis Sator-Katzenschlager et al. 2010 (114) Retrospective analysis Verrills et al. 2011 (95) Retrospective analysis SNS ? ONS 75 24 2 ONS 15 60–100 0 Not reported ONS 44 30 0 Not reported 4.5 PNfS 111 13 5 Not reported 6 PNfS 100 2 2 Not reported 1 9.1 Pain over implant (%) 0.9 Infection (%) 3.4 SCS (CRPS) 554 20 Not reported Not reported 4 SCS (FBSS) 3427 27 Not reported Not reported 6 SCS 410 21.4 5.9 None reported 3.4 SCS 527 22.6 6 None reported 4.5 SCS 830 23.1 10.2 SCS 42 14 7 12 SCS 45 9 0 None reported 5308 Range 9–27 Mean 17.5 CI 14.5–20.49 16 Range 0–10.2 Mean 4.775 CI 3.55–5.97 0 5.8 4.6 10 Range 0.9–12 Mean 6.233 CI −0.871–13.2 24 6 6 Range 3.4–10 Mean 5.23 CI 4–6.4 5 4 Not reported SCS, spinal cord stimulation; CRPS, complex regional pain syndrome; FBSS, failed back surgery syndrome; SNS, sacral neurostimulation; ONS, occipital nerve stimulation; PNfS, peripheral nerve field stimulation; RCT, randomized controlled trial. During SCS implantation, percutaneous leads are typically secured at the lead-exit site, either the deep fascia or the supraspinous ligament. Contrary to the aforementioned evidence, concern should still be exercised before placing a suture or a ligature directly around the lead, as it may damage the internal components of the leads and is not recommended by manufacturers, although a small short-term in vitro study suggested minimal if any damage (98). Lead anchors have been developed to protect the lead components while securing the percutaneous leads to paraspinal structures such as deep fascia or the supraspinous ligament. However, the implanter needs to keep in mind a number of factors that can result in lead migration. 584 Needle Placement The introducing needle for percutaneous SCS leads should be placed using a paraspinous approach and a shallow entry angle. This places the exiting lead body away from the anatomic midline between the spinous processes and helps avoid friction or damage to the leads by the moving spinous processes. The needle tip, although entering the fascia from a paramedian position, should enter the epidural space in the midline. Along with a shallow entry angle, this ensures appropriate midline lead placement in the posterior epidural space and minimizes lateral lead migration while optimizing current delivery to the dorsal columns. A shallow entry angle also maximizes the bend radius on the lead as it enters the deeper paraspinal structures, thereby decreasing the risk of lead migration (98). www.neuromodulationjournal.com Anchoring Technique A number of anchors have been developed to secure the leads safely. Silicone anchors with suture sleeves are supplied by all manufacturers in their SCS lead kits. These anchors are low-profile and soft, which makes them advantageous in thin patients. Although they may provide robust anchoring, the strength/durability of the anchored lead is totally dependent on the surgical technique and skills of the implanting physician. Enhanced silicone anchors with titanium sleeves have been developed. These anchors are radiopaque, facilitating their identification should a lead revision be needed. However, the holding strength of the anchor on the lead is still highly dependent on the implanter’s skills. Both types of silicone anchors require placement of retention ties around the anchor sleeve in order to secure the lead to the anchor, creating a single unit; the lead and the anchor become one. Mechanical anchors have been developed to bypass the necessity of tying the anchor to the lead, but they are touted to also provide superior holding force. There are no studies that have validated the claim that these mechanical anchors lead to a decreased rate of migration. The sequence of securing the anchor to the fascia and then the lead to the anchor is largely implanter-dependent. It is recommended that the “system” be anchored to the supraspinous ligament or to deep fascia using nonabsorbable braided nylon sutures through the suture sleeves of/or just around the anchor. Alternatively, some surgeons secure the lead and anchor to the patient with the first stitch, all at once, so as not to cause the electrode to migrate © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION Table 7. Commercially Available Anchoring Mechanisms. Clik Swift Lock Twist Lock Injex Boston Scientific 2011 Silicone Hex wrench Not known $375 a pair St. Jude Medical 2010 Hard plastic Twist apart Not known $350 a pair Medtronic 1998 Hard plastic Untwist Shown by Kumar 2006 (55) Included in lead kit Medtronic 2012 Silicone Cut with special tool Not known Not known Appearance Company Year of FDA approval Material Release mechanism Damages lead Cost even before implantation. Surgical paddle leads are typically anchored either to the dura or to the ligamentum flavum. Using an anchor for surgical paddle leads placed at the fascial layer has been shown to result in lead fracture upon thoracolumbar spine flexion, as the lead is taut between two fixed rigid points (102). Should an extension be needed, anchoring the connector next to the lead anchor is recommended. Strain-Relief Loop A strain-relief loop placed at the epifascial level distal to the anchor for both percutaneous and paddle leads has been recommended to provide slack and decrease the risk of lead migration (4,102). Implantable Pulse Generator Position The distance between the midline anchor and an IPG implanted in the gluteal region elongates by 9 cm upon thoracolumbar spine flexion (4). Placing the IPG in the abdominal wall results in a minimal excursion of 0.2 cm upon walking and 1.7 cm with twisting (4). Alternatively, the IPG may be placed just to the side of the midline incision, except in thin patients or those with increased paraspinal muscle bulk (118,119). In an abstract presented at the 2006 North American Neuromodulation Society meeting, Pyles and Khodavirdi describe this technique being used in six patients (119). Moreover, these authors mention one of the major advantages of the technique as being decreased probability of lead migration due to elimination of lead traction that might have resulted from placement of the IPG at a site distant from the anchoring point (119). No lead migration occurred with off-midline placement of the IPG in a series of 26 implanted patients described in an abstract from the INS annual meeting in 2011 (118). However, the IPG moved toward midline in one patient, necessitating revision. www.neuromodulationjournal.com Aberrant Stimulation Aberrant stimulation can be defined as painful, unhelpful, or otherwise unwanted stimulation, often a change from the expected stimulation. Aberrant stimulation results from multiple causes, with three mechanical or physiologic events explaining most situations. The first is lead migration, a mechanical event, and thus recruitment of additional and unhelpful neural tissues, often with the loss of © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 585 Anchoring Mechanisms The anchors that have been used to secure percutaneous leads have historically been constructed of materials such as silicone or hard plastic (Table 7). Silicone anchors are secured to leads by nonabsorbable ties and then to deep fascia with similar sutures. Hard plastic anchors, on the other hand, are secured to leads by using a twist-locking mechanism and are then secured to deep fascia with nonabsorbable sutures. Kumar et al., in a combination literature review and expert panel consensus statement in 2007, showed that silicone anchors attached to deep fascia, with the nose of the anchor pushed through the fascia, were superior in preventing lead breakage compared with the only hard plastic anchor available then (4). Moreover, this hard plastic mechanical anchor, FDA-approved for use since 1998 (120), has been associated with lead breakage as well as localized pain (102). A Swift-Lock mechanical anchor (St. Jude Medical, Plano, TX, USA) has been in use since February 2010. This anchor is unidirectional, with a longer, nozzle-like soft end intended to be the proximal end of the anchor pointing toward the spine. This anchor has a mechanical twist-locking mechanism. The Clik anchor is a mechanical anchor released in March 2011 (Boston Scientific Neuromodulation, Valencia, CA, USA). This lead anchor combines the advantages of the silicone anchor with the locking feature of hard plastic anchors. It consists of a set screw that can be tightened with a hex wrench, resulting in an audible and tactile click to confirm the lock. The same wrench/screw-locking mechanism is used to connect leads to the generator. The Clik is bidirectional and the titanium set screw anchor housing makes it radiopaque, facilitating localization should a lead revision be necessary. A Pellethane (Lubrizol Corp., Cleveland, OH, USA) sleeve covers the inner lumen of the anchor and distributes the force from the engaged set screw over a larger area, protecting the lead. A silicone overmold encases the screw system to enhance patient comfort. Additionally, the set screw can easily be unscrewed to manipulate the lead if necessary, unlike other locking anchors that are difficult to unlock once locked. The Injex anchoring system (Medtronic Neurological, Minneapolis, MN, USA) is the latest mechanical anchor to enter the market. It uses a unique compression-fit anchor design that maintains lead integrity by allowing the lead wires to float without undue restraint. A handheld dispenser propels the silicone rubber anchor over the lead while the tool is pushed against fascia at the lead-exit site. The lead is then anchored to the fascia or supraspinous ligament using ties (the manufacturer recommends against using polypropylene suture material on silicone). A special anchor-removal tool with a stainless steel slitting blade is required once the anchor is deployed to free the lead or replace the anchor, if desired. To date, there are no studies that support the notion that the newer mechanical anchors cause less lead breakage or localized pain. Prospective studies on lead migration would be useful to determine the utility of such products. However, lead migration may be dependent on the surgeon’s skills and experience more than the anchor itself. Thus, aggregate studies would be more useful than analysis of a single implanter’s results with the newer anchors. DEER ET AL. stimulation of effective neurons. The second situation occurs as a function of costimulation of intended and unintended neurons, a physiologic event. The third situation results from the momentary migration of an electrode relative to its intended target, a mechanical event, as seen with rotation of the neck in cervical stimulation, or when the patient changes position and the spinal cord moves relative to the fixed position of the electrode (67,68,121). Significant literature exists regarding lead migration and is covered elsewhere in this paper. Costimulation of targeted and untargeted neurons can often be mitigated or improved upon with programming changes, such as narrowing of pulse width and or reduction of amplitude to reduce the chronaxie–rheobase strength–duration curve (122,123). Programming of the electrodes to produce relative hyperpolarization of collateral nerves (guarding) can also confer benefit. If programming cannot reduce unwanted neural recruitment, then improvements in the proximity of the electrode to the intended neural target may help. This may require electrode repositioning or revision, based on the circumstances. Improvements in hardware and the ability to more discretely depolarize or more adequately anodally guard unwanted nerves will improve this side effect (124,125). Changes in stimulation conferred by changes in position occur because the anatomic location of the electrode changes in relation to the neural substrate, often secondary to the thickness of dorsal CSF (68,126,127). Remedies include choosing a different location for stimulation, such as moving proximally in the cervical cord from mid-cervical to high cervical position or changing from a cylindrical lead to a thicker and wider paddle lead. Because paddle leads are typically thicker, solutions to positioning with thoracically placed cylindrical leads may also include use of a paddle lead. Use of specialized position-sensing accelerometers has also been beneficial (128,129). 586 Pain Related to Device Components Patients implanted with neuromodulation devices often report pain related to the site of device components, such as pain around the IPG site or pain over the lead-anchor site or lead-extension junctions. In SCS studies the incidence of component pain is variable (Table 6); for example, Kumar et al. (44) reported an incidence of 12% (5 of 42 patients) in the PROCESS study, with one patient requiring reoperation. This high incidence, however, may be related to the large size of the IPG used in the study (Synergy, Medtronic, Inc.). By contrast, North et al., Kumar et al., and Mekhail et al. (5,32,56) reported no cases of device-related discomfort. Cameron et al. (3) reported 24 cases of device-related discomfort from a total of 2753 (0.9%). Turner et al. found a higher incidence, with a mean 5.8% of patients across 20 studies reporting pain over the implant, a median value of 0%, and a range of 0% to 40% (54). Regarding ONS, Saper et al. (112) reported two cases of pain over the IPG site and one case of burning pain over the lead/extension site (6%). By contrast, Paemeleire et al. (111) reported no cases of pain over the implant site. Device-related discomfort appears to be far more common in SNS. Brazzelli et al. (94) reported a 24% incidence of pain over the lead or IPG site. This may well relate to the location of the lead and IPG implant in the presacral and buttock area, where subcutaneous fat may be less dense than in the anterior abdominal wall, where many SCS devices are implanted. In cases considered for revision, including placement of paddle electrode in cases of lead migration, the clinician may consider another percutaneous trial to guide the revision surgery. This is an www.neuromodulationjournal.com especially important consideration when doubt exists about the best location for the paddle. Best practice mandates careful communication between the trialing clinician and the surgeon performing the paddle placement. The stimulator company representative can also assist in transmitting images and facilitating this communication. BIOLOGIC COMPLICATIONS Infection Background Approximately 22% of all health-care-associated infections are surgical-site infections (SSIs), and the majority of SSIs are thought to be acquired during surgery (130,131). In addition, most SSIs originate from the patient’s own bacterial flora (11,45,132). For example, >80% of health-care-associated Staphylococcus aureus infections are endogenous (133). SSIs associated with implantable pain devices may result in high levels of morbidity and devastating clinical consequences, including the costly (to the patient and to society) removal of equipment. There have been reports of MRSA cultured from the CSF of patients who underwent the placement of a stimulator lead and paralysis from an epidural abscess following SCS infections (134,135). In general, direct expenses attributed to an SSI may result in a doubling of total medical inpatient costs. Significant policy and treatment measures have been advocated for the reduction of SSIs. Infection rates associated with SCS systems vary (Table 6) and have been reported in the range of 3.4% to 4.6% from two large systematic reviews (3,54). Kumar et al. (41), in a multicenter RCT comparing SCS with CMM for neuropathic pain, reported an 8% infection/wound breakdown rate. Biological complications are most prevalent within the first three months postimplantation. The three major types of infection related to SCS implantation include superficial infections, deep infections, and epidural abscesses. Superficial SSIs involve the skin and subcutaneous tissue surrounding an incision and are defined as infections occurring within 30 days after the operation (11). A deep incisional infection related to surgery involves the deep soft tissue, including muscle and fascia. When an implant is involved, the responsible timeframe for a deep infection is up to one year postsurgery (11). Turner et al. (54) reported that a majority of infections associated with SCS systems are superficial infections (4.5% superficial SSIs and 0.1% deep SSIs). Follett et al. (136) reported that a majority of infections occur at the generator site (54%) and that infection rates are lower at the SCS electrode implant site (17%) and with lumbar incision (8%). The most commonly reported organisms were Staphylococcus species at 48%. Preoperative Practices During the preoperative stage, focus should be placed on the recognition of known risk factors for the development of SSIs and ways to modify these factors. Patient risk factors associated with a higher level of infection include altered immune response (e.g., HIV/ AIDS and corticosteroid use), diabetes, obesity, remote infection, tobacco use, and carriers of staphylococci (131,132). Prior to surgery, all remote infections should be treated. In addition, glucose control should be optimized (CDC Recommendation Category IB) and patients should be encouraged to discontinue tobacco use (CDC Recommendation Category IB). When hair removal is required at the surgical site, it should be done with electrical clippers immediately before surgery (CDC Recommendation Category 1A). Preoperative screening and decolonization for S. aureus nasal carriers (both methicillin-sensitive S. aureus and MRSA) with mupirocin nasal ointment and chlorhexidine soap has been reported to reduce the risk of hospital-associated S. aureus infection (11,133). © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION Prophylactic antibiotic therapy (CDC Recommendation Category IA) should be utilized and has been shown, in both animal and clinical studies, to reduce the risk of SSIs (47,55,137). Furthermore, antibiotic prophylaxis has been shown to be an effective intervention for preventing postoperative wound infection, independent of surgery type, resulting in an approximately 50% reduction in the incidence of wound infections (138). Multiple factors are involved in optimal antimicrobial prophylaxis, such as agent selection, timing and route of administration, duration, renal function, and appropriate dosing. Failure to optimize antimicrobial therapy has been shown to increase the risk of infection by two- to six-fold (139). Intravenous antibiotics should be administered within one hour before surgical incision or within two hours before surgical incision with vancomycin. Although great emphasis has been placed on the appropriate timing of the administration of antibiotic prophylaxis prior to incision, weight-based dosing is another factor that plays a role in the efficacy of therapy. In order for antimicrobial prophylaxis to be effective in the prevention of SSIs, serum and tissue levels must exceed the minimum inhibitory concentration (MIC) for the organisms likely to be encountered during the operation (140,141). For antimicrobial prophylaxis for SCS cases, a single dose of a cephalosporin is recommended. The current preoperative dosing of cefazolin, based on weight, is 1 g for individuals weighing less than 80 kg, 2 g for individuals 81 to 160 kg, and 3 g for individuals >160 kg (140). For individuals with a beta-lactam allergy, clindamycin (600 to 900 mg based on weight) or vancomycin (1 g) may be used. Vancomycin should not be used routinely (CDC Recommendation Category IB). Indications for vancomycin use include a beta-lactam allergy, MRSA colonization, institutionalized patients (nursing home, long-term care facilities, etc.), or if a surgical procedure is being performed in a facility with a recent outbreak of MRSA (142). No advantages have been documented for post-SCS implantation antibiotic use (143). In addition, in other surgical specialties, prolonged antibiotic use in the postoperative period has not been shown to improve outcomes and in some studies resulted in poor outcomes (144,145). www.neuromodulationjournal.com IA IB II No recommendation/ unresolved issue Strongly recommended for implementation and supported by well-designed experimental, clinical, or epidemiological studies. Strongly recommended for implementation and supported by some experimental, clinical, or epidemiological studies and strong theoretical rationale. Suggested for implementation and supported by suggestive clinical or epidemiological studies or theoretical rationale. Practices for which insufficient evidence or no consensus regarding efficacy exists. fibroblasts and keratinocytes (45). Some empirical recommendations might also include using pop-off sutures, so that skin is not reentered for multiple stitches, and silver-impregnated sutures that have some antiseptic properties (149). Postoperative Practices Surgical incisions should be protected with an occlusive sterile dressing for 24 to 48 hours (CDC Recommendation Category IB) (48,150,151). Although dressings are often left in place for longer periods of time, extended dressing use has not been shown to limit SSI rates (48). If dressing changes are required, handwashing (CDC Recommendation Category IB) and sterile technique are recommended (CDC Recommendation Category II) (11). Discussion SSIs are associated with significant morbidity and costs; therefore, appropriate steps should be taken to limit SSIs when performing SCS implants. If an infection is suspected, then a diagnostic workup should be initiated. Superficial infections often present with erythema, tenderness, and possible purulent drainage (42). Laboratory tests, including white blood count, C-reactive protein, and erythrocyte sedimentation rate, may help define an SSI. In certain cases, infections isolated to the superficial tissues can be treated effectively with antibiotics. During conservative treatment, it is important to monitor for any signs of infection spreading to deeper structures. If the infection has spread to deeper structures, surgical incision and drainage, often with the removal of the device, is the recommended treatment (42). Cultures should be obtained to define antibiotic treatment. In addition, a consultation should occur with an infectious disease specialist. Radiographic imaging assists in determining whether the infection has spread to the neuraxis. The MRI is performed following device removal. Reimplantation with a new device should not occur until the infection has been effectively treated and the infectious disease specialist has provided medical clearance. Recommendations and Evidence for Prevention and Treatment Studies examining infection-control policies specifically for SCS systems are limited; therefore, extrapolation of best practices often occurs from other surgical fields (140,152). The CDC has published evidence-ranked recommendations for the prevention of SSIs (Tables 8 and 9) (11). Skin Erosion Skin erosions are typically a consequence of superficial lead placement and are more a consequence of PNS or PNfS, usually © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 587 Intraoperative Practices Appropriate preparation technique and agent selection for skin antisepsis is an important measure for the prevention of an SSI (CDC Recommendation Category IB). Povidone–iodine- and chlorhexidine-based solutions are two agents commonly utilized for skin preparation (146). These products are often combined with isopropyl alcohol, which is an effective bactericidal agent that disorganizes cell membrane lipids and denatures cellular proteins. Isopropyl alcohol has been shown to increase the antimicrobial activity of both products. In clinical studies chlorhexidine-based products were superior to povidone–iodine-based products (147,148). Darouiche et al. (147) examined the SSI rates of patients who underwent surgery in six hospitals and were assigned either to chlorhexidine–alcohol or povidone–iodine skin preparation. The overall rate of SSIs was significantly lower in the chlorhexidine– alcohol group than the povidone–iodine group (9.5% vs. 16.1%), respectively. Other intraoperative steps that should be taken include maintaining positive pressure ventilation in the operating room (CDC Recommendation Category IB), keeping the operating room doors closed (CDC Recommendation Category IB), and limiting traffic (CDC Recommendation Category II) (11). Tissue should be handled gently, and efforts should be made to minimize devitalized tissue and eradicate dead space at the surgical site (CDC Recommendation Category IB) (11). Wound irrigation assists in the removal of foreign material, debris, and blood clots. The addition of antibiotics to the irrigation solution has not been shown to positively influence infection rates (45,142). In addition, added antibiotics may be toxic to Table 8. Evidence Rankings From the Centers for Disease Control and Prevention (11). DEER ET AL. Table 9. Infection Control Measures Recommended by the Centers for Disease Control and Prevention (11). Recommendations Evidence rankings Preoperative measures Optimize glucose control Discontinue tobacco use If hair is removed, use electric clippers immediately before surgery Use prophylactic antibiotic therapy Vancomycin should not be used routinely Intraoperative measures Use appropriate preparation technique and agent selection for skin antisepsis Maintain positive pressure ventilation in the operating room (OR) Keep the OR doors closed during procedure Limit OR traffic Handle tissue gently and eradicate dead space Postoperative measures Use occlusive sterile dressing for 24–48 hours postoperatively If a dressing change is required, use: Handwashing Sterile technique IB IB IA IA IB IB IB IB II IB IB IB II centering on the distal end of the lead (4). Skin erosion of leads or hardware is an uncommon complication of SCS; overall, Cameron reported a 0.2% incidence of skin erosion (3). This is in contrast to PNfS, where Verrills reported an incidence of 7% for hardware erosion in 100 cases (95). IPG battery erosion or dehiscence can be reduced by appropriate placement away from mobile or osteal locations and by careful layered closure with avoidance of suture lines over the implanted device. Management of skin erosion complications differs for SCS and PNS/PNfS systems, concerns being stratified by the development of the surgical emergent epidural abscess, a serious infection of septic joints, or the easily treatable superficial cellulitis. The NACC recommends the following regarding skin erosions as a result of device implant: If a deep infection occurs that involves the device pocket, the SCS device must be removed, regardless of whether there are systemic infection symptoms or not, and salvage attempts are discouraged. After removal of an infected device, whether symptoms of epidural infection exist or not, radiographic diagnostic tests such as MRI or CT should be performed to rule epidural abscess in or out. After wound cultures are taken, immediate treatment for infections must be employed. If reimplantation is planned, appropriate measures to ensure adequate risk reduction and repeat dehiscence are suggested. Peripheral systems may be explanted and reimplanted as described, or salvage of the existing system may be attempted. Commonly, peripheral systems have been adopted because of CMM failure, and in the case of headache, many patients elect to trial salvaging methods (153). Introduction of equipment designed specifically for the periphery may aid in reducing complications (154). 588 Seroma A seroma is a collection of serosanguinous fluid within a developing pocket or a surgically created pocket that is likely due to frictional forces of two tissue planes and excessive surgical trauma, www.neuromodulationjournal.com with an overall surgical risk of 2.5% (47). Seromas can form when dead space is not adequately closed, and they are common after breast surgery and reconstruction, as well as abdominoplasty. Furthermore, populations with poor wound healing, such as patients with diabetes or small-vessel diseases and smokers, are certainly at a higher risk for the development of seroma. Seroma risk reduction includes preoperative patient preparation, such as treating comorbidities like diabetes by optimizing glucose control. Intraoperative risk management procedures should include limiting aggressive blunt dissection, reducing excessive electrocautery, maintaining and achieving careful hemostasis, and performing a layered closure to limit dead space. Gentle pressure, such as the utilization of an abdominal binder overlying the surgical site, is advocated to minimize seroma formation. See recommendations for seroma in Table 2. Treatment of seroma as a complication of implantable technologies is largely anecdotal. Treatment centers on fluid removal, either episodic or with indwelling postoperative drains. The fear of pathogen introduction is critical and should govern the algorithmic risk– benefit assessment for invasive treatment. Caustic agents may be introduced to promote scarring, although graded evidence for this practice is lacking. If a seroma persists over a length of time in spite of all good intentions to treat, it may be advisable to reoperate and reduce dead space that exists by paying attention to appropriate closure techniques. Neurologic Injury Neurologic injury is by far the most serious complication of SCS implantation. Such injury can result from direct trauma to nerves and spinal cord caused primarily by complications of the procedure, whether during the placement of a needle or of a percutaneous lead or paddle leads. Meyer et al. reported a case of quadriplegia following inadvertent intramedullary percutaneous lead placement in a patient under general anesthesia (52). In a MAUDE (FDA Manufacture and User Facility Device Experience) database review, Levy et al. recently investigated neurologic injury following traditional paddle lead placement (155). During a three-year period, 44,587 paddles were implanted in as many patients. Neurologic complications occurred in 260 patients, for a rate of 0.58%. Motor dysfunction without epidural hematoma occurred at a rate of 0.13% for paddle leads introduced by laminotomy (43). Neuraxial Hematoma Epidural hematoma formation following the placement of SCS leads, whether percutaneous or surgical, is a rare occurrence. In a series of 509 plate electrodes, Barolat (156) reported one case of epidural hematoma resulting in paraplegia. In a 20-year review of the literature, Cameron estimated the risk of epidural hematoma development at 0.3% and paralysis at 0.03% (3). Levy and colleagues reported on a sample of 44,587 cases, among whom 0.25% had major neurologic deficit (155). Sixty-one of the 111 cases (0.14%) had limited motor deficit, six had autonomic changes (0.013%), 46 had sensory deficits (0.10%), and 21 had CSF leakage due to dural puncture. Sixteen epidural hematomas with limited motor deficit, 15 hematomas without motor deficit (0.034%), and 52 hematomas with major motor deficits (0.12%) were reported in the same series (155). Franzini et al. suggested increased postoperative vigilance in high-risk patients for epidural hematoma following spinal surgery. High-risk patients included those of male gender, with a male-tofemale risk ratio of 4:1, and patients in the fifth or sixth decade of life © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION www.neuromodulationjournal.com Figure 1. Epidural hematoma in a patient who took aspirin before or during SCS trial and Excedrin the morning after his leads were removed. A T5 to L1–2 hematoma (a [white arrows] in the sagittal view, b in the axial view) was evacuated. but the patient suffered permanent weakness in one leg. Case courtesy of Dr. Poree. Used with permission. evaluating the other published guidance already noted and determining which guides best serve the implanting physician and neurostimulation patient. Safety for patients who are anticoagulated requires that the patient safely tolerate anticoagulation cessation. The recommendation to abstain from reinitiating anticoagulants during the duration of the trial is the fear of the inadvertent removal of the leads while anticoagulated. This concern must be balanced against the risk of thrombotic events and may influence the length of the trial. Deer and Pope retrospectively reviewed continuation or initiation of anticoagulation for the permanent implant and found no neuraxial bleeding complications, although, formally, the question of safety still remains (166). Warfarin inhibits vitamin K-dependent coagulation factors, and cessation within the first one to three days often does not result in © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 589 (25). Neurologic deficits presented more commonly with progressive motor and sensory deficit than with severe radicular pain and back pain. More recent case reports describe hematomas with implantation of either paddle or percutaneous leads in patients taking anticoagulant/antiplatelet medications or not and as the potential result of lead migration (27,29,155,157–159). For example, Giberson and colleagues recently published two cases of patients who developed spinal epidural hematomas following removal of percutaneous SCS trial leads (159). Both of these patients took aspirin either before or during their trial period. In the first case, upon removal of the patient’s trial leads, the patient reported taking Excedrin (acetaminophen, aspirin, and caffeine) that morning, despite instructions to avoid any nonsteroidal antiinflammatory drugs (NSAIDs). The patient almost immediately developed severe back pain and lower extremity weakness and was transported to the nearest emergency department. An MRI revealed an epidural hematoma from T5 to L1–2 that required a multilevel laminectomy for evacuation (Fig. 1). The patient, however, was reluctant to have this surgery, and it was not performed for two days after his admission. The patient suffered from permanent weakness in one leg. The second patient ceased lowdose aspirin (81 mg) and all other NSAIDs one week before trial (159). Shortly after the trial leads were removed, this patient developed lower thoracic burning pain as well as paraparesis and spasms. The patient was directed to the nearest emergency department, where an emergent MRI revealed a T8-to-L3 epidural hematoma (Fig. 2a,b). A multilevel laminectomy and hematoma evacuation was performed the same day with complete resolution of the patient’s symptoms. The patient went on to have a permanent SCS implant that provided excellent pain relief (Fig. 2c,d). Obvious concerns exist regarding bleeding into the spinal canal when patients are anticoagulated and require neuraxial instrumentation for neurostimulation. The fact that there are no published guidelines regarding anticoagulated patients and SCS has prompted many implanters to adopt and accept guidelines for the anticoagulated patient undergoing regional anesthesia. However, the applicability of these guidelines to anticoagulated patients undergoing neuraxial implants is being questioned. The American Society of Regional Anesthesia (ASRA) guidelines (50) for neuraxial analgesia are commonly followed to reduce the risk of neuraxial hematoma formation following SCS lead placement. The ASRA guidelines stratify perioperative thromboembolism with bleeding in anticoagulated patients as a risk, and despite this, spinal hematomas following neuraxial interventions continue to occur (25,26,160–164). Recently, Manchikanti et al. published a bestevidence synthesis of anticoagulation management in the setting of neuraxial chronic pain procedures and largely concurred with the ASRA guidelines (165). Bleeding risk is highest during placement and removal of the device, and it is crucial in the patient who is anticoagulated to consult with the prescribing provider to determine the patient’s suitability for anticoagulation cessation and the need for bridging before the temporary or permanent system placement. Because most trials are performed on an outpatient basis and because a controlled inpatient environment to ensure patient compliance and postoperative surveillance is absent, patients undergoing outpatient procedures may be at greater risk of sequelae to a developing epidural hematoma than those admitted to a hospital for observation after their implant or trial. Table 10 lists suggested perioperative anticoagulation management practices for dorsal column SCS. These recommendations have occurred based on DEER ET AL. Figure 2. This patient ceased low-dose aspirin and all other NSAIDs one week before the trial began. The patient suffered an epidural hematoma, shown sagittally (a) and axially (b), compressing the spinal cord and extending from T8 to L3. The patient later had permanent implantation of a 2 × 4 paddle lead at T9 (c, black arrow) and two quadripolar subcutaneous leads at L4 (d, white arrows). Case courtesy of Dr. Poree. Used with permission. 590 normal coagulation. It is the recommendation of the NACC that warfarin be stopped five to seven days before the intended surgery. Preoperative international normalized ratio (INR) testing should be performed, and if the INR is >1.5, the procedure should not be performed. Because enoxaparin (Lovenox), a low-molecular-weight heparin, has a short half-life, it is commonly used as a bridging agent in the outpatient setting when patients cannot tolerate anticoagulation cessation for long periods. The use of enoxaparin invariably requires a therapeutic, not prophylactic, dose. In this setting, stopping warfarin and initiating enoxaparin therapy to “bridge” anticoagulation until the warfarin is gone and then stopping the enoxaparin for 24 hours before surgery is commonly performed. For the SCS trials, comparatively, a patient would be off anticoagulants for five days as opposed to 11 days following a three-day trial. The antiplatelet thienopyridine derivatives clopidogrel and ticlopidine inhibit adenosine diphosphate (ADP)-induced platelet aggregation. As these medications differ in their pharmacokinetics and require vastly different cessation times prior to platelet and coagulation normalization, they are listed separately. www.neuromodulationjournal.com The glycoprotein (Gp) IIb/IIIa receptor antagonists inhibit platelet–fibrinogen and platelet–VWbF aggregation. Normal platelet activation typically occurs within eight hours (eptifibatide, tirofiban) to 48 hours (abciximab) following reintroduction. The NACC’s increased suggested cessation time of three days before surgery reflects the accommodation for a more invasive procedure than those presented in the ASRA guidelines. Direct thrombin inhibitors are becoming more popular for the treatment of atrial fibrillation. These anticoagulants (dabigatran etexilate and rivaroxaban) inhibit thrombin and factor Xa. The halflife varies for each but can be up to 17 hours for dabigatran following multiple doses and 12 hours for rivaroxaban. The half-life of each drug depends on renal function. Since few data currently exist regarding bleeding risk with dorsal column stimulation, the NACC recommends a cautious approach to cessation of these agents. Although historical recommendations suggest there is not a higher rate of bleeding following perioperative neuraxial interventions with patients continuing aspirin or NSAIDs, there is now a growing consensus within the neuromodulation community to stop aspirin and NSAIDs seven days prior to SCS trial and implant. The NACC believes that further investigation is needed to identify the appropriate length of the NSAID-free period prior to implant. The experts of the NACC have suggested that the use of low-dose aspirin may be reasonable as it has been stated that the risk of bleeding is less than that with a 325-mg dose. This has not been proven, so no consensus can be published at this time. It is the recommendation of the NACC that the implanting doctor should encourage the patient to discuss the risk-to-benefit ratio of stopping aspirin with the physician who recommended the therapy (cardiologist, neurologist, primary care). Commonly, anticoagulant combination therapy is employed and requires further consideration and discretion prior to neuraxial surgery. The implanters’ concerns regarding cessation of combination therapy or monotherapy should be communicated to the patient after consultation with the cardiologist or primary care physician, with thoughtful consideration given to the potential risks from stopping such medications. Clearly, cardiac thrombotic risk assessment is important to gauge candidacy for the therapy; however, as data emerge regarding the use of SCS for angina and the potential improvement in functional measures, this topic will need to be revisited. There is a paucity of data regarding the performance of peripheral neuromodulation therapies such as PNS, SNS, and PNfS when patients are anticoagulated or when it is appropriate to stop anticoagulation medications prior to performing these procedures. To date, neurologic complications for these peripheral procedures in anticoagulated patients have not been reported. Since peripheral compartments for SNS and PNS are not rigidly contained, and there are no compartments surrounding peripheral nerve fields as when PNfS is performed, hematoma formation is less catastrophic than when neuromodulation procedures are performed within the spinal space. As previously stated, information can be borrowed from the regional anesthetic literature. The ASRA guidelines suggest adherence to the neuraxial guidelines written for deep regional peripheral interventions (50). Dural Puncture Accidental dural puncture can and occasionally does occur when performing epidural needle placement for lead positioning, which can result in postdural puncture headache (PDPH) symptoms as well as CSF leakage into the wound. The incidence of dural puncture © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION Table 10. Anticoagulation Management Practices for Spinal Cord Stimulation as Recommended by the Neuromodulation Appropriateness Consensus Committee. Anticoagulant Recommendation for trial Recommendation for permanent implant Warfarin Discontinue 5–7 days before, INR < 1.5; if bridging required, refer to bridging medication; continue cessation during duration of trial, resume 24 hours following trial lead removal. Hold therapeutic dose of LMWH 24 hours before procedure; hold for duration of trial; resume 24 hours following lead removal. High-risk patients for cardiac events—discontinue at least 5 days before; low risk 7–10 days before; hold for duration of trial; resume 24 hours following lead removal. Discontinue 7–10 days prior to procedure, hold for duration of trial, resume 24 hours following lead removal. Discontinue 14 days prior to procedure, hold for duration of trial, resume 24 hours following lead removal. Discontinue for 3 days prior to procedure, hold for duration of trial, restart 24 hours following lead removal.‡ Discontinue 7 days prior to procedure, hold for duration of trial, restart 24 hours following lead removal.§ Discontinue 5–7 days before, INR < 1.5; if bridging required, refer to bridging medication; resume 24 hours postoperatively. Enoxaparin (LMWH) Clopidogrel (ADP receptor antagonists) Effient (ADP receptor antagonist) Ticlopidine (ADP receptor antagonists) Abciximab, eptifibatide, tirofiban (platelet GPIIb/IIIa receptor) Dipyridamole, aggrenox (aspirin/dipyridamole) (phosphodiesterase inhibitors) Naproxen, ketorolac, ibuprofen, etodolac, etc. (nonsteroidal anti-inflammatory drugs)§ Aspirin§ Herbals (ginseng, ginkgo, garlic) Pradaxa (dabigatran etexilate), Xarelto (rivaroxaban) (direct thrombin inhibitors) Heparin IV* Heparin SQ† Discontinue 7 days prior to procedure, hold for duration of trial, reinitiate 24 hours following lead removal. Hold therapeutic dose of LMWH 24 hours before procedure; resume 24 hours following surgery. High-risk patients for cardiac events-discontinue at least 5 days before; low risk 7–10 days before; resume 24 hours following surgery. Discontinue 7–10 days prior to procedure, hold for duration of trial, resume 24 hours following lead removal. Discontinue 14 days prior to procedure; resume 24 hours following surgery. Discontinue for 3 days prior to procedure, hold for duration of trial, restart 24 hours following the surgery.‡ Discontinue for 7 days prior to procedure, hold for duration of trial, restart 24 hours following the surgery.§ Discontinue 7 days prior to procedure, hold for duration of trial, reinitiate 24 hours following the surgery. Discontinue 7 days prior to procedure, hold for duration of trial, reinitiate 24 hours following lead removal. Discontinue 7 days prior to the procedure, hold for duration of trial, reinitiate 24 hours following lead removal. Discontinue 5 days prior to procedure, hold for duration of trial, reinitiate 24 hours following lead removal. Discontinue 7 days prior to procedure, hold for duration of trial, reinitiate 24 hours following surgery. Discontinue 7 days prior to the procedure, reinitiate 24 hours following surgery. Discontinue 5 days prior to procedure, hold for duration of trial, reinitiate 24 hours following surgery. NA NA NA NA *Requires inpatient hospitalization and monitoring, suggesting a special need or indication for neurostimulation, and should be assessed on case-by-case basis. † Peaks at 2–4 hours after administration; typically thrombotic prophylaxis as inpatient and may require platelet assessment if more than 4-day dosing. Please refer to American Society of Regional Anesthesia guidelines and determine on a case-by-case basis. ‡ Typically contraindicated 4 weeks following surgery. If reinitiated, careful follow-up and vigilance is suggested (50). § Current recommendations (50) suggest variable stoppage is necessary based on clinical context and on the specific half-life of the nonsteroidal antiinflammatory drug in question. The half-life determines the time required for discontinuation in order to limit the drug’s effect on platelet function. INR, international normalized ratio; ADP, adenosine diphosphate; LMWH, low-molecular-weight heparin; NA, not applicable. www.neuromodulationjournal.com focus of the patient’s complaints. The PDPH may not leave sufficient time to assess candidacy for the permanent system and efficacy of the trial (167). Care must be taken when performing the blood patch to match the volume of autologous blood injected to the level of puncture, with smaller volumes required for more cephalad punctures in the thoracic and cervical spine (168). Immunologic Reactions Contact dermatitis, allergy, and foreign-body reactions to implanted SCS devices have been described in case reports (46,53,169). Ochani et al. (46) described a case of suspected allergic reaction six weeks following cervical and lumbar SCS placement for CRPS for atypical face pain after facial trauma. The patient presented with dysesthesia, erythema, and burning overlying the device. An infection workup was negative. Patch dermatologic allergy testing revealed sensitization to platinum, silicone, and polyurethane. Stimulator removal resolved the complaints. © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 591 has been estimated at 0% to 0.3%. The incidence of CSF leak following traditional paddle lead placement was reported to be 0.05% (3,155). Risk factors for dural puncture include previous surgery at needle entry into the epidural space, a calcified ligamentum flavum, spinal stenosis at the site of needle entry into the epidural space, and an uncooperative patient. Patients who develop PDPH after placement or attempted placement of an SCS lead may suffer from a positional headache, diplopia, tinnitus, neck pain, photophobia, and fluid accumulation at the lead-anchoring site. Although dural puncture headache commonly resolves within a week in the majority of patients, some may require more interventional strategies for resolution of the headache. Autologous epidural blood patch has been utilized both prophylactically and therapeutically in cases where dural puncture occurs. If the SCS trial is complicated by dural puncture and resultant PDPH, results of the trial for efficacy of stimulation may be complicated by the headache, as that occurrence may now become the DEER ET AL. McKenna et al. reported on a patient with a skin reaction overlying the IPG site one month following the stimulator placement (169). Although the patient was found to be allergic to nickel, the authors of this case report described the reaction as an isomorphic response to the expansion of underlying tissues, rather than nickel allergy. Lennarson et al. (53) reported on a case of a giant cell mass as a result of a foreign-body reaction to the lead following explant that was compressing the spinal canal, necessitating multilevel cervical laminectomy, excision of the giant cell reaction mass, and fusion. Gadgil and colleagues (170) reported on two cases of contact dermatitis with implanted SCS IPG units. Successful treatment involved revising the IPG and sealing it in a pouch of polytetrafluoroethylene. Urologic Complications Renal failure, micturition inhibition, and other urologic complications have been reported as complications to SCS (171–173). Loubser et al. (173) described the case of a patient with partial T12–L1 spinal cord injury who had an SCS implanted to treat his neuropathic/central pain. As a result of high therapeutic amplitudes required to produce desired paresthesias, the patient developed urethral sphincter spasm, preventing self-catheterization. The author suggested routine urologic functional testing be incorporated during the trial period. Larkin et al. reported a case of acute renal failure secondary to a trial for SCS and related the mechanism of the renal failure to the secondary sympatholysis effects of SCS, although this conclusion has been highly debated (172). More recently, a case of micturition inhibition complicating SCS was reported by Grua et al. (171). Their patient had cauda equina syndrome from an angioma at T12, and the percutaneous SCS lead was placed with the tip positioned left of center at T12. The patient reported complete resolution of his pain, but urge incontinence occurred and reoccurred with initiation of stimulation after a 30-day interval. The authors postulated that the autonomic effects of stimulation may have unbalanced the signals, altering urinary function. Gastrointestinal Complications Sporadic cases of gastrointestinal complications associated with SCS have been reported (174,175). Kemler et al. (174) described a case of relapsing colitis caused by SCS. The patient had an SCS system with the lead placed at C4 and the IPG placed in the left lower abdominal quadrant for upper-extremity CRPS. The patient’s ulcerative colitis relapsed and remitted twice as the device was employed and discontinued, respectively. The authors postulated that the mechanisms of action of this effect of SCS may have been an electromagnetic effect on the colon, aberrancy of the GABAergic system, or an electrical effect on intestinal circulation. Thakkar et al. (175) described two cases of patients who experienced gastrointestinal challenges exacerbated by SCS, including nausea, diarrhea, worsened gastrointestinal reflux, and flatulence. The authors suggested that the sympatholytic effect of SCS leading to unopposed parasympathetic tone was the cause for this patient’s gastrointestinal symptoms. Stimulation Tolerance 592 Background Neurostimulation therapy has expanded in indications, modalities, and number of implants worldwide; the last now number over www.neuromodulationjournal.com 25,000 per year (176,177). Although SCS systems are safe, the existing literature reveals a high complication rate ranging from 34% to 42% (167), despite system improvements and technological advances. As stated previously, complications have been divided into biological and hardware-related, with hardware complications occurring in between 24.4% and 50% of cases vs. 7.5% of cases for biological complications (6,55). Other complications cannot be included in the cited categories, because real incidence and underlying physiopathology are not well known. One of them is the so-called stimulation tolerance, which, although apparently related to hardware, cannot be clearly classified. The term stimulation tolerance was coined by Kumar’s group after a retrospective study in 160 patients with nine years between the first and the last implant (55). Stimulation tolerance to SCS is defined in patients where pulse amplitude must be increased to achieve the same analgesic level over time, sometimes even losing the efficacy of the technique (167). This complication affects the long-term efficacy of the system, provided that it keeps functioning properly and the lead position is correct. The onset of this complication cannot be predicted; it appears in the course of patients’ follow-up, affecting 29% of patients (55). Possible causes for stimulation tolerance include neuroplasticity of pain transmission pathways in either the dorsal root ganglion, the spinal cord, the thalamus, or the brain cortex. Some authors consider that these losses or changes in stimulation efficacy, and therefore the appearance of systemic tolerance, may be attributed to cellular or fibrotic changes in the tissues around the stimulating electrodes (3). None of these explanations could be demonstrated in postmortem analysis or surgical examinations. A plausible and possible cause for stimulation tolerance is psychological or psychiatric affective factors (32,178,179). Evidence No scientific evidence exists regarding efficacious treatment for patients developing stimulation tolerance to SCS. Expert opinion suggests that the most reasonable course is to institute a neuromodulation holiday and stop stimulation for several weeks. Only Kumar and colleagues have addressed management of this complication. Discussion Management of stimulation tolerance could be approached by altering stimulation program parameters, provided that the system is working properly and achieving an appropriate level of paresthesia coverage. From the very beginnings of the therapy, experts have advocated adjusting frequency (180). The electric parameters suitable for manipulation are 1) pulse amplitude, which is determined by the patient’s stimulation thresholds; 2) pulse width, which has been traditionally used to perform fine adjustments in the stimulation levels, but has recently gained relevance at high values, which seem to recapture different spinal fibers at different depths; and 3) pulse frequency (181). Frequency is the only parameter that affects stimulation quality, eliciting a pounding feeling at low settings and a tingling sensation at higher settings (180). On the other hand, frequency is the only parameter that is kept fixed in some pathologies, such as urinary/ fecal incontinence or deep brain stimulation (DBS). Because of evidence that frequency matters clinically, stimulation frequency for the control of pain has garnered more attention recently. New high-frequency (HF) systems, such as the Senza HF-10 device (Nevro Corp., Menlo Park, CA, USA), approved for clinical use in Europe and Australia and in clinical trials in the USA, and the Neuros stimulation device (Neuros, Cleveland, OH, USA) for postamputation pain, produce similar or even better relief than © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 RISK REDUCTION IN NEUROSTIMULATION traditional devices at kilohertz frequencies, without producing the paresthesia sensations produced by conventional neurostimulators. Some authors have experimented with systems that combine standard frequencies with high-rate bursts (182–184) and have demonstrated acceptable clinical results. Nevertheless, although the safety of HF systems has been confirmed in a follow-up period of more than one year (181), no conclusions can be drawn regarding systemic tolerance, as this complication was not analyzed in the studies. As far as burst stimulation is concerned, De Ridder et al. demonstrated that when compared with tonic stimulation or placebo, burst stimulation of the spinal cord was more selective in the activation of the dorsal anterior cingulate and right dorsolateral prefrontal cortex of the brain (184), which may be beneficial if one of the causes for the development of stimulation tolerance is thalamic and cortical neuroplasticity. As in the case of HF (kilohertz) stimulation, burst stimulation also features absence of paresthesia, which may be useful for avoiding the onset of tolerance (183). Most transcutaneous electrical neurostimulators (TENSes) are capable of providing “modulated” stimulation, that is, cyclic and progressive variation of one or more parameters over time, which seems to be useful for preventing tolerance (185). The most common types of TENS modulation include high/low frequency, combined frequency/pulse width, and combined pulse amplitude/ pulse width cycles. This stimulation modality was incorporated in TENS more than a decade ago but is not yet available in implantable systems. Recommendations There are no clear recommendations for the prevention or management of stimulation tolerance in the existing literature. Only a few attempts have been made to improve these patients’ condition. In their review, Kumar et al. propose two types of treatment for stimulation tolerance: 1) provide the patient a “stimulation holiday” by turning the system off during a six-week period or 2) use pharmacological treatment with amitryptyline or L-tryptophan (55). Neither maneuver was effective—only two of 16 patients recovered the system’s efficacy after the six-week stimulation holiday. As we have seen, modulation of frequencies as performed with TENS may solve the complication of stimulation tolerance. Woods considered the possibility of using high stimulation frequencies to overcome systemic tolerance, although no significant improvement could be documented (167). In patients who lose efficacy from conventional SCS at approximately 50 Hz, a switch to 10 kHz frequency produces improvement in pain control (181). In the opinion of the NACC, a future method to prevent the development of neuromodulation stimulation tolerance will most likely be related to manipulation of frequencies. Future implantable systems will probably offer the possibility of choosing between paresthesia and paresthesia-free stimulation and modulation capabilities to prevent or alleviate this therapy-limiting complication. FACTORS AFFECTING COMPLICATION RATES www.neuromodulationjournal.com Hardware Appropriateness for the Procedure Hardware for peripheral and SCS techniques has evolved significantly over the past four decades. While we continue to await the introduction of custom-made hardware for particular techniques, such as ONS and PNfS, such devices already exist for SCS and SNS. For SCS, the hardware has evolved from monopolar leads through quadripolar leads to the current state-of-the-art, 16-contact leads. Early reports of complications, particularly the need for lead replacement, show a statistically lower rate in patients with quadripolar leads (11%) than in those with monopolar electrodes (45%) (p < 0.003) (65,66). As there was no difference in the frequency of electrode migration between the two types of electrodes, proper paresthesia coverage was most often recaptured by reprogramming with the multipolar leads (65). North et al. (61) reported SCS treatment in 62 patients with chronic pain. They found that surgical revision was necessary in 23% of the cases in which simple bipolar leads were placed to obtain optimal paresthesia coverage. Surgical revision, however, was required in only 16% of those cases with multichannel devices. Finally, the introduction of rechargeable pulse generators may well reduce the need for battery replacements in a population of neurostimulation patients, particularly for indications that require high current consumption, such as peripheral arterial disease (190). However, this fact remains to be established over the long term. IMPROVING OUTCOMES The high incidence of complications with neurostimulation, albeit mostly benign, detracts from the value of the therapy, as it leads to poorer outcomes and increased health-care expenditures. Minimizing complications would be expected to result in improved outcomes and more therapeutic successes. Understanding the root causes of complications constitutes the foundation for preventing and minimizing untoward events. Improvements in several variables for neuromodulation procedures would lead to lower complication rates: 1. Patient selection. Perhaps the most critical factor for minimizing complications is proper patient selection, which entails careful selection of neurostimulation candidates based on clinical © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 593 Lead Location Different rates of lead migration have been observed when the use of SCS was examined for differing indications. For example, locating the lead in the relatively immobile thoracic spine for indications such as refractory angina was associated with low lead migration rates. In a review, Taylor et al. (186) reported a combined rate of lead migration or fracture of 7.8% (10 of 128 patients), which is much lower than the rates the same author observed for CRPS (20%) and FBSS (27%). We may conclude that the position of the lead in a nonmobile area of the spine has a limiting effect on the rate of migration. Technique Familiarity and Surgeon Experience Other implant disciplines have demonstrated a clear link between the level of experience of the operating surgeon and the rate of complications related to the implant procedure (187,188). This is clearly the case for neuromodulation procedures as well. Early work by Schwedt et al. (117) on ONS was associated with a much higher rate of complications relative to later reports by Paemeleire et al. and Saper et al. (111,112). A recent cohort study by Turner et al. (189) utilized inexperienced implanters and consequently reported higher complication rates, as well as the occurrence of rare life-threatening complications. Furthermore, early SCS work by Andersen et al. (65) for refractory angina treatment reported a high incidence of lead migration (23%) compared with a more recently reported incidence of 7.8% (186). We can, therefore, conclude that novel techniques in spinal and peripheral nerve stimulation are usually associated with a higher rate of complications, particularly lead-related complications, and that as surgeons gain experience in a particular implant technique, the complication rate decreases over time. DEER ET AL. 2. 3. 4. 5. 6. 7. criteria and thorough psychological screening and judicious medical optimization of patient comorbidities (38,191–193). Physician training and credentialing. Currently no mandated standards of training exist for many procedures in neuromodulation. There are also gaps in credentialing, with lack of official credentialing and standardizing bodies (194,195). Restricting neurostimulation implants to more experienced physicians may limit complications and improve patient outcomes (152). Improving equipment. Over the past 40 years, progressive improvements have occurred in neurostimulation equipment. Recent advances in anchoring devices and techniques, as well as improvements in lead technology, have reduced lead fracture and lead migration rates (30,196). Better dissemination and application of lessons learned from studies and registries. Continuously innovating with new products geared to current indications as well as emerging applications, such as peripheral nerve stimulation and field stimulation. Developing guidelines based on best available evidence and expert consensus. Periodically reassessing such practice guidelines and their effects. CONCLUSIONS 594 Spinal cord and peripheral nerve stimulation therapies are safe and reversible therapies. These effective therapeutic techniques result in a range of minor complications. Hardware-related complications are more common than biological complications, with leadrelated complications most frequent. Biological complications include the most common complications such as infection and pain over the implant. Serious adverse events such as neurological damage are uncommon. The rate of complications is governed by factors such as the lead position in the spine or periphery, the experience of the surgeon, and the availability of custom-made equipment for the technique. It is clear that novel techniques are associated with a higher incidence of hardware-related complications than established techniques. Neurostimulation is a rapidly evolving field where technological advances may play a critical role in patient outcomes. A limited number of patients with similar clinical conditions exist for particular neurostimulation applications, and among these patients, significant clinical and technical variabilities also may exist, making robust studies of neuromodulation therapies difficult. Therefore, regarding neuromodulation therapies, clinical evidence may often lag behind clinical experience. Practice guidelines, therefore, are necessary to help guide physicians regarding their clinical decisionmaking, their assimilation of expanding knowledge, and their understanding of novel clinical applications. Evidence-based guidelines follow strict sequential processes in common clinical entities (197). However, in many clinical settings, development of such guidelines is significantly limited by evidence; thus, consensus guidelines become necessary to guide clinical practice (198). Modern EBM incorporates a merger of published evidence and expert clinical opinion in such situations. A consensus of thought leaders may provide not only a framework for clinical practice but may also ensure patient access to needed care. A frequent assessment and reassessment of the adaptation and implementation of such guidelines will continue to be necessary. There should also be a periodic evaluation of potential effects www.neuromodulationjournal.com of these guidelines on patient outcomes and risk mitigation to assess their ultimate utility. Note The Boston Scientific Precision Spectra SCS System has received Food and Drug Administration approval for MRI-conditional head scans. The ImageReadyTM Guidelines and Patient Eligibility Checklist are available from the company. St. Jude Medical is planning MRI compatibility submissions in the European Union in 2014. Authorship Statements Dr. Deer served as primary author, project organizer, and editor; Drs. Pope, Krames, Mekhail, Buchser, North, Provenzano, and Leong served as primary authors and editors. The remaining authors contributed sections of the manuscript or provided critical reviews. Opinions expressed herein are not necessarily shared by all authors. 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COMMENTS This is an extraordinary consensus document that will guide best practice for many years to come. Paul Verrills, MBBS Melbourne, Australia *** The NACC under the leadership of Dr Tim Deer has brought together both critical literature review and many multiples of lifetime clinical practice to bear on the issue of avoiding and treating complications in © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598 597 140. Alexander JW, Solomkin JS, Edwards MJ. Updated recommendations for control of surgical site infections. Ann Surg 2011;253:1082–1093. 141. Forse RA, Karam B, MacLean LD, Christou NV. Antibiotic prophylaxis for surgery in morbidly obese patients. Surgery 1989;106:750–756, discussion 756–757. 142. Matar WY, Jafari SM, Restrepo C, Austin M, Purtill JJ, Parvizi J. Preventing infection in total joint arthroplasty. J Bone Joint Surg Am 2010;92 (Suppl. 2):36–46. 143. McDonald M, Grabsch E, Marshall C, Forbes A. 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J Pain Symptom Manage 1985;13:251–252. 174. Kemler MA, Barendse GA, van Kleef M. Relapsing ulcerative colitis associated with spinal cord stimulation. Gastroenterology 1999;117:215–217. DEER ET AL. neurostimulation. I have always felt that the low hanging fruit in medicine is to attempt to bring up the rear rather than push the frontier forward an inch. By that I mean that improving both median performance and lowest quartile performance in outcomes yields the biggest improvement for the smallest financial outlay compared to trying to invent the next biggest breakthrough. I recommend Atul Gawande’s books Complications, Better and Checklist to truly understand this. This paper aims to do just that not only for the experienced implanter but also as a “Neurostimulation Primer” for the non-expert physician. It serves as a template that can be added to or modified as additional literature or clinical experience evolves. In the absence of suitable literature to conduct a meta-analysis of RCTs then this stands as the most appropriate way to reduce both complications and costs across practices, states and countries. It is not to say that individual recommendations cannot be adjusted or countermanded but it reasonable to ask that individuals do so by presenting their own evidence to substantiate that practice. I would encourage readers to consider doing so via publication of their techniques and results so that we may add to the canon of published clinical experience and thus all benefit from the broadest data set possible. The authors are to be commended for this impressive initial report from the NACC and the International Neuromodulation Society for initiating discussion in this area. Marc Russo, MBBS Newcastle, New South Wales, Australia *** This NACC paper is an outstanding summary of the current knowledge surrounding neuromodulation risks and risk mitigation approaches. The last NACC recommendation should have suggested requisite familiarity with the suggestions within this very document. *** We have to laud the authors for their thoughtful recommendations that are important in many aspects that reflect the actual practice in neuromodulation. The last ten years neuromodulation therapy has evolved from an exceptional therapy to a more common and accessible one. Bringing this therapy to a larger volume necessary to serve the patient population who might benefit from it brings also new challenges. Quality assurance in health care delivery is certainly one of them. We must recognize and identify the specific required neurostimulation training for physicians and their assistants but also monitor their outcomes and complications. This is an engagement to be taken by the physicians as well as administrators of the health care provider. Reviewing and adopting the recommendation will hopefully strengthen the value of the therapy and will bring a better cost-utility of what it is already known as effective. In the context of the rapidly changing advanced technologies it is not always possible to elaborate definitive (often long and expensive) randomized-controlled studies (which can be futile as the technology used can be obsolete by the end of the study). Expert consensus is therefore greatly needed to identify best practices. Complementary to their opinions would be to have clinical registries that could relate strengths and weakness of usual practice and can be analyzed and adapted to the rhythm of the evolving technologies. Neuromodulation is certainly here to stay if we can provide an adapted retroaction to monitor the benefit for the patient and the health care system. Michel Prudhomme MD, PhD Quebec, Canada Comments not included in the Early View version of this paper. William Porter McRoberts, MD Fort Lauderdale, FL, USA 598 www.neuromodulationjournal.com © 2014 International Neuromodulation Society Neuromodulation 2014; 17: 571–598
