Anesthetic Risk, Quality Improvement, and Liability



Anesthetic Risk, Quality Improvement, and Liability


Karen L. Posner

Saint Adeogba

Karen B. Domino





In anesthesia, as in other areas of life, everything does not always go as planned. Undesirable outcomes occur regardless of the quality of care provided. An anesthesia risk management program can work in conjunction with a program for quality improvement to minimize the liability risk of practice, while assuring the highest quality of care for patients. Payers such as Medicare are increasingly depending on accreditation through bodies such as the Joint Commission to ensure that mechanisms are in place to deliver quality and safe care to all patients. In addition, there has been a move toward performance measurement linked to reimbursement. The legal aspects of American medical practice have also become increasingly important as the public has turned to the courts for economic redress when their expectations of medical treatment are not met.

This chapter discusses anesthetic mortality and morbidity, risk management, continuous quality improvement (CQI), performance measurement, and medical liability. The chapter provides background for the practitioner concerning the role of risk management activity in minimizing and managing liability exposure. Also described are the medical legal system, the most frequent causes of lawsuits for anesthesiologists, and appropriate actions for physicians to take in the event of a malpractice suit.



Anesthesia Risk


Mortality and Major Morbidity Related to Anesthesia

Estimates of anesthesia-related morbidity and mortality are difficult to quantify. Not only are there difficulties obtaining data on complications, but different methods yield different estimates of anesthesia risk. Studies differ in their definitions of complications, in length of follow-up, and especially in approaches to evaluation of the contribution of anesthesia care to patient outcomes. A comprehensive review of anesthesia complications is beyond the scope of this chapter. A sampling of studies of anesthesia mortality and morbidity will be presented to provide historical perspective plus a limited overview of relatively recent findings.

Early studies estimated the anesthesia-related mortality rate as 1 per 1,560 anesthetics.1 More recent studies using data from the 1990s and later estimate the anesthesia-related death rate in the United States to be <1 per 10,000 anesthetics.2,3,4,5,6 Some examples of modern estimates of anesthesia-related death from throughout the world are provided in Table 4-1.2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19 Differences in estimates may be influenced by different reporting methods, definitions, anesthesia practices, patient population, as well as actual differences in underlying complication rates. Nevertheless, it is generally accepted that anesthesia safety has improved over the past 50+ years.

Other complications related to anesthesia that have received relatively recent attention include postoperative nerve injury, awareness during general anesthesia, eye injuries and visual deficits, dental injury, and postoperative cognitive dysfunction in elderly patients (Table 4-2).20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42 The incidence of ulnar neuropathy has been estimated to be 47 per 10,000 patients (Table 4-2).21 Lower extremity neuropathy following surgery in the lithotomy position was observed in 151 per 10,000 patients (Table 4-2).22 Permanent neurologic injury following neuraxial anesthesia was estimated at 0 to 4.2 per 10,000 spinal anesthetics and 0 to 7.6 per 10,000 epidural anesthetics.20,24,25 Peripheral nerve injury following peripheral nerve blocks was estimated to occur at a rate of 1.7 to 4.2 per 10,000 anesthetics.23,24,26 Awareness during general anesthesia has been estimated to occur in 15 to 100 per 10,000 patients.27,28,29,30,31

Eye injuries are a risk of anesthesia, including corneal abrasions as well as more rare complications such as blindness from ischemic optic neuropathy or central retinal artery occlusion (Table 4-2).32,33,34,35,36,37,38,39 Corneal abrasion has occurred at a rate of 1.4 to 15.1 per 10,000 procedures.32,34,39 Ischemic optic neuropathy has been observed at 0.57 to 2.8 per 10,000 spine surgeries.32,35 Risk factors for ischemic optic neuropathy after spinal fusion have recently been identified and include a variety of patient, surgical, and anesthetic factors.43 Among these include use of a Wilson surgical bed frame, obesity, and long anesthetic durations. All can contribute to increased venous congestion in the optic canal and potentially reduce optic nerve perfusion pressure. There was insufficient evidence to conclude that intraoperative anemia or transient periods of hypotension were causative factors.

Damage to teeth or dentures is perhaps the most common injury leading to anesthesia malpractice claims. Dental injury complaints are usually resolved by a hospital risk management department. Dental injuries after general endotracheal anesthesia were observed in 3.6 per 10,000 patients in the United States.40

Cognitive dysfunction is observed in many adult patients after major surgery, but only the elderly are at significant risk for long-term cognitive problems.44 The cause for postoperative cognitive dysfunction is unknown.


Risk Management


Conceptual Introduction

Risk management and quality improvement programs work hand in hand to minimize liability exposure while maximizing quality of patient care. Although the functions of these programs vary from one institution to another, they overlap in their focus on patient safety. They can generally be distinguished by their basic difference in orientation. A hospital risk management program is broadly oriented toward reducing the liability exposure of the organization. This includes not only professional liability (and therefore patient safety) but also contracts, employee safety, public safety, and any other liability exposure of the institution. Quality improvement programs have as their main goal the continuous maintenance and improvement of the quality of patient care. These programs may be broader in their patient safety focus than strictly risk management. Quality improvement (sometimes called patient safety) departments are responsible for providing the resources to provide safe, patient-centered, timely, efficient, effective, and equitable patient care.45


Risk Management in Anesthesia

Those aspects of risk management that are most directly relevant to the liability exposure of the anesthesiologist include prevention of patient injury, adherence to standards of care, documentation, and patient relations.

The key factors in the prevention of patient injury are vigilance, up-to-date knowledge, and adequate monitoring.46 Physiologic monitoring of cardiopulmonary function, combined with monitoring of equipment function, might be expected to reduce anesthetic injury to a minimum. This was the rationale for the adoption by the American Society of Anesthesiologists (ASA) of Standards for Basic Anesthetic Monitoring.a Detailed information on anesthesia monitoring techniques can be found in Chapter 25.

The ASA web site should be reviewed yearly for any changes in these standards. It would also be reasonable to review the Guidelines and Statements published on the ASA web site. It should be noted that, although membership in the ASA is not required for the practice of anesthesiology, expert witnesses will, with virtual certainty, hold any practitioner to the ASA standards. It is also possible that, as a risk management strategy, a professional liability insurer or hospital may hold an individual anesthesiologist to standards higher than those promulgated by the ASA.

Another risk management tool is the use of checklists to prevent errors. Since the first pilot’s checklists were developed for the military, checklists have been adopted by many industries wherein processes are too numerous and/or complex to rely on human memory. A checklist is a simple, yet powerful, tool that ensures no important detail is forgotten, and it removes variability, enhances consistency, and decreases likelihood of error. This patient safety tool helps to remind providers of key steps and thus works to facilitate a safe and effective health-care delivery.

Historically, checklists have been used in anesthesia for anesthesia machine checkout procedures. Information pertaining to anesthesia workstation pre-use procedures as well as safety considerations for workstations can be found in Chapter 24. Recently,


checklists for clinical care have been promoted to improve patient safety and medical management in various clinical settings, for example, central venous catheterization, intraoperative emergencies, and perioperative care. Catheter-related bloodstream infections were reduced significantly with the implementation of a standardized process that included a checklist for catheter placement and management.47 The ASA has recently developed a checklist for central venous catheter access.48 During simulated emergency scenarios, checklists have improved performance in the management of local anesthesia systemic toxicity49 and
improved management of intraoperative crises such as malignant hyperthermia or massive hemorrhage.50








Table 4-1. Estimates of Anesthesia-Related Death




















































































































Reference Country Time Data Sources/ Methods Rate of Death
Flick et al.4 USA 1988–2005 Perioperative cardiac arrest in pediatric patients at a tertiary referral hospital
(n—92,881 anesthetics)
Anesthesia-attributed deaths—0.22/10,000 anesthetics
Biboulet et al.7 France 1989–1995 ASA 1–4 patients undergoing anesthesia
(n—101,769 anesthetics); cardiac arrest within 12 h postanesthesia
(n—24)
Anesthesia-related death—0.6/10,000 anesthetics
Newland et al.2 USA 1989–1999 Cardiac arrests within 24 h of surgery
(n—72,959 anesthetics) in a teaching hospital
Death related to anesthesia-attributable perioperative cardiac arrest—0.55/10,000 anesthetics
Eagle and Davis8 Western Australia 1990–1995 Deaths within 48 h or deaths in which anesthesia was considered a contributing factor
(n—500 deaths)
Anesthesia-related death—0.025/10,000 anesthetics
Lagasse3 USA (a) 1992–1994
(b) 1995–1999
(a) Suburban teaching hospital (n—115 deaths; n—37,924 anesthetics)
(b) Urban teaching hospital (n—232 deaths; n—146,548 anesthetics)
Anesthesia-related death:
(a) 0.79/10,000 anesthetics
(b) 0.75/10,000 anesthetics
Khan and Khan9 Pakistan 1992–2003
(a) 1992–1998
(b) 1999–2003
University hospital. Deaths within 24 h of anesthesia
(n—111,289 anesthetics)
3.14/10,000 anesthetics;
deaths totally attributable to anesthesia 0.35/10,000; anesthesia partially responsible for death 0.7/10,000
(a) 0.68/10,000 anesthetics
(b) 0.18/10,000 anesthetics
Ahmed et al.10 Pakistan 1992–2006 Perioperative cardiac arrest in pediatric patients at a university hospital
(n—20,216 anesthetics)
Deaths primarily anesthesia-related 0.49/10,000 anesthetics
Davis11 Australia 1994–1996 Deaths reported to the committee
(n—8,500,000 anesthetics)
Anesthesia-related death—0.16/10,000 anesthetics
Morray et al.5 USA 1994–1997 Pediatric patients from 63 hospitals
(n—1,089,200 anesthetics)
Anesthesia-related death—0.36/10,000 anesthetics
Kawashima et al.12 Japan 1994–1998 Questionnaires to training hospitals
(n—2,363,038 anesthetics)
Death totally attributable to anesthesia—0.21/10,000 anesthetics
Arbous et al.13 Holland 1995–1997 All deaths within 24 h or patients who remained unintentionally comatose 24 h postanesthesia
(n—811 in 869,483 anesthetics)—64 hospitals
Anesthesia-related death—1.4/10,000 anesthetics
Braz et al.14 Brazil 1996–2005 Tertiary general teaching hospital
(n—53,718 anesthetics)
Anesthesia-related death—1.12/10,000 anesthetics
Totally attributed—0,56/10,000
Partially attributed—0.56/10,000
Lienhart et al.15 France 1999 Nationwide survey of anesthesia-related deaths Death totally related to anesthesia—0.069/10,000
Death partially related to anesthesia—0.47/10,000
Kawashima et al.16 Japan 1999 Questionnaires to training hospitals
(n—793,840 anesthetics)
Death totally attributable to anesthesia—0.13/10,000 anesthetics
Irita et al.17 Japan 1999–2002 Deaths as a result of life-threatening events in the operating room
(n—3,855,384 anesthetics) in training hospitals
Death totally attributable to anesthetic management—0.1/10,000 anesthetics
Li et al.6 USA 1999–2005 Deaths with anesthesia-related complication codes from death certificate data
(a) Population data from census records
(b) National hospital discharge survey data (inpatients)
Anesthesia-related deaths
(a) 1.1/million population/year
(b) 8.2/million hospital surgical discharges
Charuluxananan et al.18 Thailand 2003–2004 Perioperative deaths within 24 h of surgery—20 hospitals
(n—163,403 anesthetics)
Death directly related to anesthesia—1.7/10,000
Death partially related to anesthesia—4.0/10,000
Gibbs19 Australia 2003–2005 Deaths reported to Anesthesia Mortality Committees
(n—5,983,704 anesthetics)
Anesthesia-related deaths 0.19/10,000








Table 4-2. Rates of Selected Anesthesia Complications














































































































































































































































































































Complication Reference Country Time Specific Complication Results
Nerve injury Brull et al.20 Various 1987–1999 Radiculopathy or peripheral neuropathy after spinal anesthesia 3.78/10,000 spinal anesthetics
        Radiculopathy or peripheral neuropathy after epidural anesthesia 2.19/10,000 epidural anesthetics
        Permanent neurologic injury after spinal anesthesia 0–4.2/10,000 spinal anesthetics
        Permanent neurologic injury after epidural anesthetic 0–7.6/10,000 epidural anesthetics
      Varies Transient neurologic deficit after interscalene block 2.84/10,000 anesthetics
  Warner et al.21 USA 1995 Ulnar neuropathy in adults following noncardiac surgery (n—1,502) 47/10,000
  Warner et al.22 USA 1997–1998 Lower extremity neuropathy in adult patients ≥18 under general anesthesia (GA) while in lithotomy position (n—991) 151/10,000
  Welch et al.23 USA 1997–2007 Peripheral nerve injury within 48 h of sedation or anesthesia
(n—380,680)
2.9/10,000
  Auroy et al.24 France 1998–1999 Serious peripheral neuropathy related to regional anesthesia Non-obstetric spinal blocks (SBs)
(n—35,439): 3.4/10,000
          obstetric SBs
(n—5,640): 3.5/10,000
          Upper limb peripheral nerve blocks (PNBs)
(n—23,784): 1.7/10,000
          Lower limb PNBs
(n—20,162): 4/10,000
  de Sèze et al.25 France 2000 Incapacitating neurologic complications lasting ≥3 months after central neuraxial blockade Non-obstetric SBs
(n—67,884): 0.15/10,000
Non-obstetric epidural blocks (EBs)
(n—65,464): 0.015/10,000
         
          obstetric EBs
(n—116,639): 0.09/10,000
  Barrington et al.26 USA 2006–2008 Late neurologic complications after PNB or plexus block
(n—7,156 blocks)
4.2/10,000 PNBs
Awareness Errando et al.27 Spain 1995–1997 and 1998–2001 Awareness during GA (n—3,921) 99.5/10,000
  Sandin et al.28 Sweden 1997–1998 Awareness associated with GA
(n—11,785)
15.3/10,000 procedures
  Sebel et al.29 USA 2001–2002 Awareness in patients ≥18 years old in seven academic medical centers (n—19,575) 12.8/10,000
  Avidan et al.30 USA 2005–2006 Single-center prospective study in patients ≥18 years old
(n—1,941)
20.6/10,000
  Xu et al.31 China NA Multicenter cohort study of awareness after GA with muscle relaxants
(n—11,101)
41.4/10,000
Vision loss and eye injuries Chang and Miller32 USA 1983–2002 Vision loss due to perioperative ischemic optic neuropathy (ION) associated with spine surgery
(n—14,102)
2.8/10,000
        Corneal abrasions 1.4/10,000
  Warner et al.33 USA 1986–1998 New-onset visual loss or visual changes lasting >30 days after noncardiac surgery
(n—125,234)
0.08/10,000 patients
  Roth et al.34 USA 1988–1992 Eye injury after nonocular surgery
(n—60,965)
5.6/10,000
        Corneal abrasions 3.4/10,000
        ION 0.16/10,000
  Patil et al.35 USA 1993–2002 Visual loss or disturbances after spine surgery
(n—4,728,815)
Any visual disturbance: 9.4/10,000
ION: 0.57/10,000
Central retinal artery occlusion: 0.10/10,000
  Holy et al.36 USA 1998–2004 Retrospective chart review for ION
(n—126,666)
ION: 1.3/10,000
  Shen et al.37 USA 1996–2005 Vision loss in surgery Overall: 2.35/10,000
          Cardiac surgery: 8.64/10,000
          Spinal fusion: 3.09/10,000
          Cholecystectomy 0.66/10,000
          Appendectomy: 0.12/10,000
  Warner et al.38 USA 1999 New-onset blurred vision lasting ≥3 days
(n—410,189 patients)
4.6/10,000
  Martin et al.39 USA 2005 Postoperative corneal injury
(n—84,796)
Baseline
15.1/10,000
      2006–2007 Performance initiative postoperative corneal injury 7.9/10,000
      2007–2008 Follow-up postoperative corneal injury 4.7/10,000
Dental injury Warner et al.40 USA 1987–1997 Dental injuries within 7 days of anesthesia that required intervention
(n—4,537)
2.2/10,000
        Dental injury under GA with tracheal intubation
(n—2,805)
3.6/10,000
  Newland et al.41 USA 1989–2003 Dental injury with anesthesia
(n—161,687 anesthetics)
4.8/10,000
  Gaudio et al.42 Italy 2000–2009 Dental injuries in surgical procedures under GA with tracheal intubation
(n—62,898)
37.4/10,000

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Jun 29, 2016 | Posted by in ANESTHESIA | Comments Off on Anesthetic Risk, Quality Improvement, and Liability

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