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An 83-year-old man presented to the ED via emergency medical services (EMS) with a chief complaint of neck pain. He was the restrained driver of a car that was struck from behind by another vehicle. The patient denied any head injury, loss of consciousness, chest pain, shortness of breath, or abdominal pain. His medical history was significant for hypertension and coronary artery disease, for which he was taking several medications. Regarding his social history, the patient denied alcohol consumption or cigarette smoking. |
The patient’s physical examination was unremarkable. His vital signs were normal, and there was no obvious external evidence of trauma. The posterior cervical spine was tender to palpation in the midline, but no step-off signs were appreciated. The neurological examination, including strength and sensation in all four extremities, was normal.
Since the patient’s only complaint was neck pain and his physical examination and history were otherwise normal, the emergency physician (EP) ordered radiographs of the cervical spine. The imaging studies were interpreted as showing advanced degenerative changes but no fractures, and the patient was prescribed an analgesic and discharged home.
When the patient woke up the next morning, he was unable to move his extremities, and returned to the same ED via EMS. He was placed in a cervical collar and found to have flaccid extremities on examination. A computed tomography (CT) scan of the cervical spine revealed a transverse fracture through the C6 vertebra. Radiology services also reviewed the cervical spine X-rays from the previous day, noting the presence of fracture.
The patient was taken to the operating room by neurosurgery services but remained paralyzed postoperatively. He never recovered from his injury and died 6 months later. His family sued the EP and the hospital for missed diagnosis of cervical spine fracture at the first ED presentation and the resulting paralysis. The case was settled for $1.3 million prior to trial.
Discussion
The evaluation of suspected cervical spine injury secondary to blunt trauma is a frequent and important skill practiced by EPs. Motor vehicle accidents are the most common cause of spinal cord injury in the United States (42%), followed by falls (27%), acts of violence (15%), and sports-related injuries (8%).1 A review by Sekon and Fehlings2 showed that 55% of all spinal injuries involve the cervical spine. Interestingly, the majority of cervical spine injuries occur at the upper or lower ends of the cervical spine; C2 vertebral fractures account for 33%, while C6 and C7 vertebral fractures account for approximately 50%.1
There are two commonly used criteria to clinically clear the cervical spine (ie, no imaging studies necessary) in blunt-trauma patients. The first is the National Emergency X-Radiography Use Study (NEXUS), which has a sensitivity of 99.6% of identifying cervical spine fractures.1 According to the NEXUS criteria, no imaging studies are required if: (1) there is no midline cervical spine tenderness; (2) there are no focal neurological deficits; (3) the patient exhibits a normal level of alertness; (4) the patient is not intoxicated; and (5) there is no distracting injury.1
The other set of criteria used to clear the cervical spine is the Canadian Cervical Spine Rule. In these criteria, a patient is considered at very low risk for cervical spine fracture in the following cases: (1) the patient is fully alert with a Glasgow Coma scale of 15; (2) the patient has no high-risk factors (ie, age >65 years, dangerous mechanism of injury, fall greater than five stairs, axial load to the head, high-speed vehicular crash, bicycle or motorcycle crash, or the presence of paresthesias in the extremities); (3) the patient has low-risk factors (eg, simple vehicle crash, sitting position in the ED, ambulatory at any time, delayed onset of neck pain, and the absence of midline cervical tenderness); and (4) the patient can actively rotate his or her neck 45 degrees to the left and to the right. The Canadian group found the above criteria to have 100% sensitivity for predicting the absence of cervical spine injury.1
The patient in this case failed both sets of criteria (ie, presence of cervical spine tenderness and age >65 years) and therefore required imaging. Historically, cervical spine X-ray (three views, anteroposterior, lateral, and odontoid; or five views, three views plus obliques) has been the imaging study of choice for such patients. Unfortunately, however, cervical spine radiographs have severe limitations in identifying spinal injury. In a large retrospective review, Woodring and Lee,3 found that the standard three-view cervical spine series failed to demonstrate 61% of all fractures and 36% of all subluxation and dislocations. Similarly, in a prospective study of 1,006 patients with 72 injuries, Diaz et al,4 found a 52.3% missed fracture rate when five-view radiographs were used to identify cervical spine injury. In addition, radiographic evaluation of elderly patients was found to be even more challenging in identifying cervical spine injury due to age-related degenerative changes.
Given the abovementioned limitations associated with radiographic imaging, CT scan of the cervical spine has become the imaging study of choice in moderate-to-severe risk patients with blunt cervical spine trauma. This modality has been shown to have a higher sensitivity and specificity for evaluating cervical spine injury compared to plain X-ray films, with CT detecting 97% to 100% of cervical spine fractures.5
In addition to demonstrating a higher sensitivity, CT also has the advantage of speed—especially when the patient is undergoing other CT studies (eg, head, abdomen, pelvis). While some clinicians criticize the higher cost of CT versus plain films, CT has been shown to decrease institutional costs (when settlement costs are taken into account) due to the reduction of the incidence of paralysis resulting from false-negative imaging studies.6
Forgotten Tourniquet
A 33-year-old woman presented to the ED with a chief complaint of left-sided abdominal and flank pain. She described the onset of pain as abrupt, severe, and lasting approximately 3 hours in duration. She admitted to nausea, but no vomiting. She also denied a history of any previous similar symptoms or recent trauma. The patient’s medical history was unremarkable. Her last menstrual period began 3 days prior to presentation. Regarding social history, she denied any tobacco or alcohol use. |
The patient’s vital signs were: blood pressure, 138/82 mm Hg; heart rate, 102 beats/minute; respiratory rate, 18 breaths/minute; temperature 98.6˚F. Oxygen saturation was 99% on room air.
The patient appeared uncomfortable overall. The physical examination was remarkable only for mild left-sided costovertebral angle tenderness. Her abdomen was soft, nontender, and without guarding or rebound.
The EP ordered the placement of an intravenous (IV) line, through which the patient was administered normal saline and morphine and promethazine, respectively, for pain and nausea. A complete blood count, basic metabolic panel, urinalysis, and urine pregnancy test were ordered. All of the laboratory bloodwork results were normal, and the urine pregnancy test was negative. The urinalysis was remarkable for 50 to 100 red blood cells.
A noncontrast CT scan of the abdomen and pelvis revealed a 3-mm ureteral stone on the left side. When the patient returned from radiology services, her pain was significantly decreased and she felt much improved. She was diagnosed with a kidney stone and discharged home with an analgesic and a strainer, along with instructions to follow-up with urology services. The patient was in the ED for a total of 5 hours.
The plaintiff sued the EP and hospital, claiming that the tourniquet used to start the IV line and draw blood was never removed, which in turn caused nerve damage resulting in reflex sympathetic dystrophy and complex regional pain syndrome. The defense denied all of these allegations, and the ED personnel testified that the tourniquet was removed as soon as the IV was established. The defense cited the plaintiff’s medical records, which contained documentation that the tourniquet had been removed. The defense further argued that if the tourniquet had been left on as the patient alleged, she would have experienced obvious physical signs, such as swelling, redness, infiltration of fluids, pain, and numbness. A defense verdict was returned.
Discussion
It is very tempting to simply dismiss this case as absurd, with nothing to be learned from it. It does defy common sense that no one would have noticed the tourniquet or, at the very least, that the patient would not have spoken up about it during her stay in the ED. While the jury clearly came to the correct conclusion, it does highlight a real problem: forgotten tourniquets.
According to the Pennsylvania Patient Safety Advisory (PPSA), there were 125 reports of tourniquets being left on patients in Pennsylvania healthcare facilities in 1 year alone.1 In 5% of these cases, the tourniquet was discovered within a half hour of application. In approximately 66% of cases, the tourniquet was left on for up to 2 hours, and the remaining were left in place for 2 to 18 hours.
Few locations within the hospital are without risk for this type of accident. The PPSA further noted that approximately 30% of retained tourniquets occurred on medical/surgical units, 14% in the ED, and 14% on inpatient and ambulatory surgical services departments. Approximately 19% were discovered when patients were transferred from one department to another.1
In the analysis of these incidents, contributing factors to forgotten tourniquets included staff failing to follow proper procedures, inadequate staff proficiency, and staff distractions and/or interruptions.1 In addition, some patients appeared to be at increased risk of having a retained tourniquet than others. Sixty percent of 125 patients with a forgotten tourniquet were aged 70 years or older, whereas some patients were younger than age 2 years.1 Not surprisingly, patients who were unable to verbally communicate (eg, patients who were intubated, under anesthesia, had expressive aphasia, severe dementia), were at the highest risk.
In a review of recovery room incidents, Salman and Asfar2 identified two cases of forgotten tourniquets out of approximately 7,000 patients. Potential strategies to avoid this mistake include: (1) only documenting procedures after they have been completed (eg, tourniquet removal); (2) double-checking that the tourniquet has been removed prior to leaving patient bedside; and (3) the use of extra-long tourniquets so the ends are more clearly visible.
Reference - Missed Cervical Spine Injury
- Looby S, Flanders A. Spine trauma. Radiol Clin North Am. 2011;49(1):129-163.
- Sekon LH, Fehlings MG. Epidemiology, demographics, and pathophysiology of acute spinal cord injury. Spine (Phila Pa 1976). 2001;26(24 Suppl):S2-S12.
- Woodring JH, Lee C. Limitations of cervical radiography in the evaluation of acute cervical trauma. J Trauma. 1993;34(1):32-39.
- Diaz JJ Jr, Gillman C, Morris JA Jr, May AK, Carrillo YM, Guy J. Are five-view plain films of the cervical spine unreliable? A prospective evaluation in blunt trauma patients with altered mental status. J Trauma. 2003;55(4):658-663.
- Parizel PM, Zijden T, Gaudino S, et al. Trauma of the spine and spinal cord: imagining strategies. Eur Spine J. 2010;19(Suppl 1):S8-S17.
- Grogan EL, Morris JA Jr, Dittus RS, et al. Cervical spine evaluation in urban trauma centers: lowering institutional costs and complications through helical CT scan. J Am Coll Surg. 2005;200(2):160-165.
Reference - Forgotten Tourniquet
- Pennsylvania Safety Advisory. Forgotten but not gone: tourniquets left on patients. PA PSRS Patient Saf Advis. 2005;2(2):19-21.
- Salman JM, Asfar SN. Recovery room incidents. Bas J Surg. 2007;24:3.
An 83-year-old man presented to the ED via emergency medical services (EMS) with a chief complaint of neck pain. He was the restrained driver of a car that was struck from behind by another vehicle. The patient denied any head injury, loss of consciousness, chest pain, shortness of breath, or abdominal pain. His medical history was significant for hypertension and coronary artery disease, for which he was taking several medications. Regarding his social history, the patient denied alcohol consumption or cigarette smoking. |
The patient’s physical examination was unremarkable. His vital signs were normal, and there was no obvious external evidence of trauma. The posterior cervical spine was tender to palpation in the midline, but no step-off signs were appreciated. The neurological examination, including strength and sensation in all four extremities, was normal.
Since the patient’s only complaint was neck pain and his physical examination and history were otherwise normal, the emergency physician (EP) ordered radiographs of the cervical spine. The imaging studies were interpreted as showing advanced degenerative changes but no fractures, and the patient was prescribed an analgesic and discharged home.
When the patient woke up the next morning, he was unable to move his extremities, and returned to the same ED via EMS. He was placed in a cervical collar and found to have flaccid extremities on examination. A computed tomography (CT) scan of the cervical spine revealed a transverse fracture through the C6 vertebra. Radiology services also reviewed the cervical spine X-rays from the previous day, noting the presence of fracture.
The patient was taken to the operating room by neurosurgery services but remained paralyzed postoperatively. He never recovered from his injury and died 6 months later. His family sued the EP and the hospital for missed diagnosis of cervical spine fracture at the first ED presentation and the resulting paralysis. The case was settled for $1.3 million prior to trial.
Discussion
The evaluation of suspected cervical spine injury secondary to blunt trauma is a frequent and important skill practiced by EPs. Motor vehicle accidents are the most common cause of spinal cord injury in the United States (42%), followed by falls (27%), acts of violence (15%), and sports-related injuries (8%).1 A review by Sekon and Fehlings2 showed that 55% of all spinal injuries involve the cervical spine. Interestingly, the majority of cervical spine injuries occur at the upper or lower ends of the cervical spine; C2 vertebral fractures account for 33%, while C6 and C7 vertebral fractures account for approximately 50%.1
There are two commonly used criteria to clinically clear the cervical spine (ie, no imaging studies necessary) in blunt-trauma patients. The first is the National Emergency X-Radiography Use Study (NEXUS), which has a sensitivity of 99.6% of identifying cervical spine fractures.1 According to the NEXUS criteria, no imaging studies are required if: (1) there is no midline cervical spine tenderness; (2) there are no focal neurological deficits; (3) the patient exhibits a normal level of alertness; (4) the patient is not intoxicated; and (5) there is no distracting injury.1
The other set of criteria used to clear the cervical spine is the Canadian Cervical Spine Rule. In these criteria, a patient is considered at very low risk for cervical spine fracture in the following cases: (1) the patient is fully alert with a Glasgow Coma scale of 15; (2) the patient has no high-risk factors (ie, age >65 years, dangerous mechanism of injury, fall greater than five stairs, axial load to the head, high-speed vehicular crash, bicycle or motorcycle crash, or the presence of paresthesias in the extremities); (3) the patient has low-risk factors (eg, simple vehicle crash, sitting position in the ED, ambulatory at any time, delayed onset of neck pain, and the absence of midline cervical tenderness); and (4) the patient can actively rotate his or her neck 45 degrees to the left and to the right. The Canadian group found the above criteria to have 100% sensitivity for predicting the absence of cervical spine injury.1
The patient in this case failed both sets of criteria (ie, presence of cervical spine tenderness and age >65 years) and therefore required imaging. Historically, cervical spine X-ray (three views, anteroposterior, lateral, and odontoid; or five views, three views plus obliques) has been the imaging study of choice for such patients. Unfortunately, however, cervical spine radiographs have severe limitations in identifying spinal injury. In a large retrospective review, Woodring and Lee,3 found that the standard three-view cervical spine series failed to demonstrate 61% of all fractures and 36% of all subluxation and dislocations. Similarly, in a prospective study of 1,006 patients with 72 injuries, Diaz et al,4 found a 52.3% missed fracture rate when five-view radiographs were used to identify cervical spine injury. In addition, radiographic evaluation of elderly patients was found to be even more challenging in identifying cervical spine injury due to age-related degenerative changes.
Given the abovementioned limitations associated with radiographic imaging, CT scan of the cervical spine has become the imaging study of choice in moderate-to-severe risk patients with blunt cervical spine trauma. This modality has been shown to have a higher sensitivity and specificity for evaluating cervical spine injury compared to plain X-ray films, with CT detecting 97% to 100% of cervical spine fractures.5
In addition to demonstrating a higher sensitivity, CT also has the advantage of speed—especially when the patient is undergoing other CT studies (eg, head, abdomen, pelvis). While some clinicians criticize the higher cost of CT versus plain films, CT has been shown to decrease institutional costs (when settlement costs are taken into account) due to the reduction of the incidence of paralysis resulting from false-negative imaging studies.6
Forgotten Tourniquet
A 33-year-old woman presented to the ED with a chief complaint of left-sided abdominal and flank pain. She described the onset of pain as abrupt, severe, and lasting approximately 3 hours in duration. She admitted to nausea, but no vomiting. She also denied a history of any previous similar symptoms or recent trauma. The patient’s medical history was unremarkable. Her last menstrual period began 3 days prior to presentation. Regarding social history, she denied any tobacco or alcohol use. |
The patient’s vital signs were: blood pressure, 138/82 mm Hg; heart rate, 102 beats/minute; respiratory rate, 18 breaths/minute; temperature 98.6˚F. Oxygen saturation was 99% on room air.
The patient appeared uncomfortable overall. The physical examination was remarkable only for mild left-sided costovertebral angle tenderness. Her abdomen was soft, nontender, and without guarding or rebound.
The EP ordered the placement of an intravenous (IV) line, through which the patient was administered normal saline and morphine and promethazine, respectively, for pain and nausea. A complete blood count, basic metabolic panel, urinalysis, and urine pregnancy test were ordered. All of the laboratory bloodwork results were normal, and the urine pregnancy test was negative. The urinalysis was remarkable for 50 to 100 red blood cells.
A noncontrast CT scan of the abdomen and pelvis revealed a 3-mm ureteral stone on the left side. When the patient returned from radiology services, her pain was significantly decreased and she felt much improved. She was diagnosed with a kidney stone and discharged home with an analgesic and a strainer, along with instructions to follow-up with urology services. The patient was in the ED for a total of 5 hours.
The plaintiff sued the EP and hospital, claiming that the tourniquet used to start the IV line and draw blood was never removed, which in turn caused nerve damage resulting in reflex sympathetic dystrophy and complex regional pain syndrome. The defense denied all of these allegations, and the ED personnel testified that the tourniquet was removed as soon as the IV was established. The defense cited the plaintiff’s medical records, which contained documentation that the tourniquet had been removed. The defense further argued that if the tourniquet had been left on as the patient alleged, she would have experienced obvious physical signs, such as swelling, redness, infiltration of fluids, pain, and numbness. A defense verdict was returned.
Discussion
It is very tempting to simply dismiss this case as absurd, with nothing to be learned from it. It does defy common sense that no one would have noticed the tourniquet or, at the very least, that the patient would not have spoken up about it during her stay in the ED. While the jury clearly came to the correct conclusion, it does highlight a real problem: forgotten tourniquets.
According to the Pennsylvania Patient Safety Advisory (PPSA), there were 125 reports of tourniquets being left on patients in Pennsylvania healthcare facilities in 1 year alone.1 In 5% of these cases, the tourniquet was discovered within a half hour of application. In approximately 66% of cases, the tourniquet was left on for up to 2 hours, and the remaining were left in place for 2 to 18 hours.
Few locations within the hospital are without risk for this type of accident. The PPSA further noted that approximately 30% of retained tourniquets occurred on medical/surgical units, 14% in the ED, and 14% on inpatient and ambulatory surgical services departments. Approximately 19% were discovered when patients were transferred from one department to another.1
In the analysis of these incidents, contributing factors to forgotten tourniquets included staff failing to follow proper procedures, inadequate staff proficiency, and staff distractions and/or interruptions.1 In addition, some patients appeared to be at increased risk of having a retained tourniquet than others. Sixty percent of 125 patients with a forgotten tourniquet were aged 70 years or older, whereas some patients were younger than age 2 years.1 Not surprisingly, patients who were unable to verbally communicate (eg, patients who were intubated, under anesthesia, had expressive aphasia, severe dementia), were at the highest risk.
In a review of recovery room incidents, Salman and Asfar2 identified two cases of forgotten tourniquets out of approximately 7,000 patients. Potential strategies to avoid this mistake include: (1) only documenting procedures after they have been completed (eg, tourniquet removal); (2) double-checking that the tourniquet has been removed prior to leaving patient bedside; and (3) the use of extra-long tourniquets so the ends are more clearly visible.
An 83-year-old man presented to the ED via emergency medical services (EMS) with a chief complaint of neck pain. He was the restrained driver of a car that was struck from behind by another vehicle. The patient denied any head injury, loss of consciousness, chest pain, shortness of breath, or abdominal pain. His medical history was significant for hypertension and coronary artery disease, for which he was taking several medications. Regarding his social history, the patient denied alcohol consumption or cigarette smoking. |
The patient’s physical examination was unremarkable. His vital signs were normal, and there was no obvious external evidence of trauma. The posterior cervical spine was tender to palpation in the midline, but no step-off signs were appreciated. The neurological examination, including strength and sensation in all four extremities, was normal.
Since the patient’s only complaint was neck pain and his physical examination and history were otherwise normal, the emergency physician (EP) ordered radiographs of the cervical spine. The imaging studies were interpreted as showing advanced degenerative changes but no fractures, and the patient was prescribed an analgesic and discharged home.
When the patient woke up the next morning, he was unable to move his extremities, and returned to the same ED via EMS. He was placed in a cervical collar and found to have flaccid extremities on examination. A computed tomography (CT) scan of the cervical spine revealed a transverse fracture through the C6 vertebra. Radiology services also reviewed the cervical spine X-rays from the previous day, noting the presence of fracture.
The patient was taken to the operating room by neurosurgery services but remained paralyzed postoperatively. He never recovered from his injury and died 6 months later. His family sued the EP and the hospital for missed diagnosis of cervical spine fracture at the first ED presentation and the resulting paralysis. The case was settled for $1.3 million prior to trial.
Discussion
The evaluation of suspected cervical spine injury secondary to blunt trauma is a frequent and important skill practiced by EPs. Motor vehicle accidents are the most common cause of spinal cord injury in the United States (42%), followed by falls (27%), acts of violence (15%), and sports-related injuries (8%).1 A review by Sekon and Fehlings2 showed that 55% of all spinal injuries involve the cervical spine. Interestingly, the majority of cervical spine injuries occur at the upper or lower ends of the cervical spine; C2 vertebral fractures account for 33%, while C6 and C7 vertebral fractures account for approximately 50%.1
There are two commonly used criteria to clinically clear the cervical spine (ie, no imaging studies necessary) in blunt-trauma patients. The first is the National Emergency X-Radiography Use Study (NEXUS), which has a sensitivity of 99.6% of identifying cervical spine fractures.1 According to the NEXUS criteria, no imaging studies are required if: (1) there is no midline cervical spine tenderness; (2) there are no focal neurological deficits; (3) the patient exhibits a normal level of alertness; (4) the patient is not intoxicated; and (5) there is no distracting injury.1
The other set of criteria used to clear the cervical spine is the Canadian Cervical Spine Rule. In these criteria, a patient is considered at very low risk for cervical spine fracture in the following cases: (1) the patient is fully alert with a Glasgow Coma scale of 15; (2) the patient has no high-risk factors (ie, age >65 years, dangerous mechanism of injury, fall greater than five stairs, axial load to the head, high-speed vehicular crash, bicycle or motorcycle crash, or the presence of paresthesias in the extremities); (3) the patient has low-risk factors (eg, simple vehicle crash, sitting position in the ED, ambulatory at any time, delayed onset of neck pain, and the absence of midline cervical tenderness); and (4) the patient can actively rotate his or her neck 45 degrees to the left and to the right. The Canadian group found the above criteria to have 100% sensitivity for predicting the absence of cervical spine injury.1
The patient in this case failed both sets of criteria (ie, presence of cervical spine tenderness and age >65 years) and therefore required imaging. Historically, cervical spine X-ray (three views, anteroposterior, lateral, and odontoid; or five views, three views plus obliques) has been the imaging study of choice for such patients. Unfortunately, however, cervical spine radiographs have severe limitations in identifying spinal injury. In a large retrospective review, Woodring and Lee,3 found that the standard three-view cervical spine series failed to demonstrate 61% of all fractures and 36% of all subluxation and dislocations. Similarly, in a prospective study of 1,006 patients with 72 injuries, Diaz et al,4 found a 52.3% missed fracture rate when five-view radiographs were used to identify cervical spine injury. In addition, radiographic evaluation of elderly patients was found to be even more challenging in identifying cervical spine injury due to age-related degenerative changes.
Given the abovementioned limitations associated with radiographic imaging, CT scan of the cervical spine has become the imaging study of choice in moderate-to-severe risk patients with blunt cervical spine trauma. This modality has been shown to have a higher sensitivity and specificity for evaluating cervical spine injury compared to plain X-ray films, with CT detecting 97% to 100% of cervical spine fractures.5
In addition to demonstrating a higher sensitivity, CT also has the advantage of speed—especially when the patient is undergoing other CT studies (eg, head, abdomen, pelvis). While some clinicians criticize the higher cost of CT versus plain films, CT has been shown to decrease institutional costs (when settlement costs are taken into account) due to the reduction of the incidence of paralysis resulting from false-negative imaging studies.6
Forgotten Tourniquet
A 33-year-old woman presented to the ED with a chief complaint of left-sided abdominal and flank pain. She described the onset of pain as abrupt, severe, and lasting approximately 3 hours in duration. She admitted to nausea, but no vomiting. She also denied a history of any previous similar symptoms or recent trauma. The patient’s medical history was unremarkable. Her last menstrual period began 3 days prior to presentation. Regarding social history, she denied any tobacco or alcohol use. |
The patient’s vital signs were: blood pressure, 138/82 mm Hg; heart rate, 102 beats/minute; respiratory rate, 18 breaths/minute; temperature 98.6˚F. Oxygen saturation was 99% on room air.
The patient appeared uncomfortable overall. The physical examination was remarkable only for mild left-sided costovertebral angle tenderness. Her abdomen was soft, nontender, and without guarding or rebound.
The EP ordered the placement of an intravenous (IV) line, through which the patient was administered normal saline and morphine and promethazine, respectively, for pain and nausea. A complete blood count, basic metabolic panel, urinalysis, and urine pregnancy test were ordered. All of the laboratory bloodwork results were normal, and the urine pregnancy test was negative. The urinalysis was remarkable for 50 to 100 red blood cells.
A noncontrast CT scan of the abdomen and pelvis revealed a 3-mm ureteral stone on the left side. When the patient returned from radiology services, her pain was significantly decreased and she felt much improved. She was diagnosed with a kidney stone and discharged home with an analgesic and a strainer, along with instructions to follow-up with urology services. The patient was in the ED for a total of 5 hours.
The plaintiff sued the EP and hospital, claiming that the tourniquet used to start the IV line and draw blood was never removed, which in turn caused nerve damage resulting in reflex sympathetic dystrophy and complex regional pain syndrome. The defense denied all of these allegations, and the ED personnel testified that the tourniquet was removed as soon as the IV was established. The defense cited the plaintiff’s medical records, which contained documentation that the tourniquet had been removed. The defense further argued that if the tourniquet had been left on as the patient alleged, she would have experienced obvious physical signs, such as swelling, redness, infiltration of fluids, pain, and numbness. A defense verdict was returned.
Discussion
It is very tempting to simply dismiss this case as absurd, with nothing to be learned from it. It does defy common sense that no one would have noticed the tourniquet or, at the very least, that the patient would not have spoken up about it during her stay in the ED. While the jury clearly came to the correct conclusion, it does highlight a real problem: forgotten tourniquets.
According to the Pennsylvania Patient Safety Advisory (PPSA), there were 125 reports of tourniquets being left on patients in Pennsylvania healthcare facilities in 1 year alone.1 In 5% of these cases, the tourniquet was discovered within a half hour of application. In approximately 66% of cases, the tourniquet was left on for up to 2 hours, and the remaining were left in place for 2 to 18 hours.
Few locations within the hospital are without risk for this type of accident. The PPSA further noted that approximately 30% of retained tourniquets occurred on medical/surgical units, 14% in the ED, and 14% on inpatient and ambulatory surgical services departments. Approximately 19% were discovered when patients were transferred from one department to another.1
In the analysis of these incidents, contributing factors to forgotten tourniquets included staff failing to follow proper procedures, inadequate staff proficiency, and staff distractions and/or interruptions.1 In addition, some patients appeared to be at increased risk of having a retained tourniquet than others. Sixty percent of 125 patients with a forgotten tourniquet were aged 70 years or older, whereas some patients were younger than age 2 years.1 Not surprisingly, patients who were unable to verbally communicate (eg, patients who were intubated, under anesthesia, had expressive aphasia, severe dementia), were at the highest risk.
In a review of recovery room incidents, Salman and Asfar2 identified two cases of forgotten tourniquets out of approximately 7,000 patients. Potential strategies to avoid this mistake include: (1) only documenting procedures after they have been completed (eg, tourniquet removal); (2) double-checking that the tourniquet has been removed prior to leaving patient bedside; and (3) the use of extra-long tourniquets so the ends are more clearly visible.
Reference - Missed Cervical Spine Injury
- Looby S, Flanders A. Spine trauma. Radiol Clin North Am. 2011;49(1):129-163.
- Sekon LH, Fehlings MG. Epidemiology, demographics, and pathophysiology of acute spinal cord injury. Spine (Phila Pa 1976). 2001;26(24 Suppl):S2-S12.
- Woodring JH, Lee C. Limitations of cervical radiography in the evaluation of acute cervical trauma. J Trauma. 1993;34(1):32-39.
- Diaz JJ Jr, Gillman C, Morris JA Jr, May AK, Carrillo YM, Guy J. Are five-view plain films of the cervical spine unreliable? A prospective evaluation in blunt trauma patients with altered mental status. J Trauma. 2003;55(4):658-663.
- Parizel PM, Zijden T, Gaudino S, et al. Trauma of the spine and spinal cord: imagining strategies. Eur Spine J. 2010;19(Suppl 1):S8-S17.
- Grogan EL, Morris JA Jr, Dittus RS, et al. Cervical spine evaluation in urban trauma centers: lowering institutional costs and complications through helical CT scan. J Am Coll Surg. 2005;200(2):160-165.
Reference - Forgotten Tourniquet
- Pennsylvania Safety Advisory. Forgotten but not gone: tourniquets left on patients. PA PSRS Patient Saf Advis. 2005;2(2):19-21.
- Salman JM, Asfar SN. Recovery room incidents. Bas J Surg. 2007;24:3.
Reference - Missed Cervical Spine Injury
- Looby S, Flanders A. Spine trauma. Radiol Clin North Am. 2011;49(1):129-163.
- Sekon LH, Fehlings MG. Epidemiology, demographics, and pathophysiology of acute spinal cord injury. Spine (Phila Pa 1976). 2001;26(24 Suppl):S2-S12.
- Woodring JH, Lee C. Limitations of cervical radiography in the evaluation of acute cervical trauma. J Trauma. 1993;34(1):32-39.
- Diaz JJ Jr, Gillman C, Morris JA Jr, May AK, Carrillo YM, Guy J. Are five-view plain films of the cervical spine unreliable? A prospective evaluation in blunt trauma patients with altered mental status. J Trauma. 2003;55(4):658-663.
- Parizel PM, Zijden T, Gaudino S, et al. Trauma of the spine and spinal cord: imagining strategies. Eur Spine J. 2010;19(Suppl 1):S8-S17.
- Grogan EL, Morris JA Jr, Dittus RS, et al. Cervical spine evaluation in urban trauma centers: lowering institutional costs and complications through helical CT scan. J Am Coll Surg. 2005;200(2):160-165.
Reference - Forgotten Tourniquet
- Pennsylvania Safety Advisory. Forgotten but not gone: tourniquets left on patients. PA PSRS Patient Saf Advis. 2005;2(2):19-21.
- Salman JM, Asfar SN. Recovery room incidents. Bas J Surg. 2007;24:3.