Cases Of Tetraplegia Research Articles

A Case of Tetraplegia after Proteus mirabilis Infection.

A Case of Tetraplegia after Proteus mirabilis Infection.

Computed tomographic angiography of anterior spinal artery in acute cervical spinal cord injury

In addition to spinal fracture and/or dislocation, acute traumatic spinal cord injury (SCI) includes neural tissue and vascular damage at the site of contusion. Vascular damage results in spinal cord ischemia, which is a key factor that contributes to secondary pathogenesis. There is a need to identify spinal cord ischemia secondary to anterior spinal artery (ASA) rupture in acute cervical SCI. After admission, 20 patients with cervical SCI, including 10 cases of central cord syndrome (CCS), four cases of brown-sequard syndrome (BSS) and six cases of tetraplegia (ASIA A), had computed tomographic angiography (CTA) of ASA performed on them. ASA rupture or occlusion was observed. The ASA was visualized in all 20 patients. No ASA rupture was found in CCS and BSS patients, even for sever blunt cervical fracture and dislocation tetraplegia patients, except one stab-wound patient. CTA provides the most detailed, highest resolution imaging of ASA in acute cervical SCI. ASA rupture is not commonly seen in acute blunt cervical SCI.

Tetraplegia After Coronary Artery Bypass Grafting in a Patient with Undiagnosed Cervical Stenosis

To the Editor: We read with great interest the case report of Fujioka et al. (1), who attributed the tetraplegia after coronary artery bypass grafting (CABG) to the perioperative extension of the neck in a patient with preexisting cervical spine stenosis. We report a second case of tetraplegia after CABG in a patient with undiagnosed cervical stenosis. A 61-yr-old man who developed acute myocardial infarction that was stabilized by streptokinase followed, after 10 days, by coronary artery bypass grafting. The preoperative neurological examination did not reveal any neurological complaint or abnormalities. The patient was monitored with an electrocardiogram, arterial blood pressure, saturation, a radial artery, and cannulation, and a pulmonary artery catheter was inserted. Anesthesia was induced with midazolam, propofol, fentanyl, and vecuronium, to be followed by easy orotracheal intubation. Thereafter, the patient’s neck was placed in an extension position. Cardiopulmonary bypass (CPB) was initiated after heparinization, and coronary artery bypass grafting of 4 vessels was performed. During CPB, the patient was perfused by a roller pump at a flow rate of 2.4 U · min/m2. The mean body temperature was maintained between 32°C–34°C and the mean blood pressure was maintained at 60–70 mm Hg. When surgery was completed after 4 h, the aortic cross-clamp was released, and the patient was rewarmed to a body temperature of 37°C. The weaning from cardiopulmonary bypass was successful. Heparinization was reversed with protamine and the patient was transferred to the intensive cardiac care unit. The patient awoke 6 h later, and the trachea was extubated. However, the patient was unable to move any of his four limbs. Neurological examination revealed complete paralysis of his four limbs associated with loss of sensation. An urgent cervical magnetic resonance imaging scan revealed a congenital cervical stenosis extending from C3 to C6, associated with a posterior disk herniation at C6-C7 compressing the cervical cord, which was focally edematous (Fig. 1). Immediately, an anterior surgical decompression with spinal instrumentation was performed (Fig. 2). After the operation, neurological examination showed a significant improvement and revealed a partial brown squared syndrome. Urinary and anal incontinence were also recorded. Six weeks later, the patient left the hospital. However, 3 mo later the patient died from bowel perforation and respiratory failure. The present report agrees with the previous report of Fujioka et al. (1), who speculated that placing the neck in an extended position during surgery might aggravate a preexisting spinal canal stenosis, resulting in cervical cord injury. Also, this report suggests that we should avoid extending the neck in patients with a preoperative diagnosis of cervical spine stenosis and that the neck should be manipulated similarly to manipulation of patients with cervical spine fracture. Also, preoperative screening for cervical spine stenosis is advised for elderly patients in whom an extended position of the neck is required.Figure 1.: Preoperative magnetic resonance image scan. Arrows = preoperative magnetic resonance image scan showing C5-C6 stenosis.Figure 2.: Postoperative magnetic resonance image scan. Arrows = postoperative magnetic resonance image scan showing site of C6 corpectomy. C4-C5, C5-C6, discectomy with bone graft and Codman plat®, and screws.Zoher Naja, MD* [email protected] Ahed Zeidan, MD† Hilal Maaliki, MD† Samir Zoubeir, MD‡ R. El-Khatib, MD* Anis Baraka, MD, FRCA** Departments of *Anesthesiology and ‡Neurosurgery, Makassed General Hospital, †Department of Anesthesiology, Sahel General Hospital, and **Department of Anesthesiology, American University of Beirut Medical Center, Beirut, Lebanon

Tetraplegia After Coronary Artery Bypass Grafting in a Patient with Undiagnosed Cervical Stenosis

To the Editor: We read with great interest the case report of Fujioka et al. (1), who attributed the tetraplegia after coronary artery bypass grafting (CABG) to the perioperative extension of the neck in a patient with preexisting cervical spine stenosis. We report a second case of tetraplegia after CABG in a patient with undiagnosed cervical stenosis. A 61-yr-old man who developed acute myocardial infarction that was stabilized by streptokinase followed, after 10 days, by coronary artery bypass grafting. The preoperative neurological examination did not reveal any neurological complaint or abnormalities. The patient was monitored with an electrocardiogram, arterial blood pressure, saturation, a radial artery, and cannulation, and a pulmonary artery catheter was inserted. Anesthesia was induced with midazolam, propofol, fentanyl, and vecuronium, to be followed by easy orotracheal intubation. Thereafter, the patient’s neck was placed in an extension position. Cardiopulmonary bypass (CPB) was initiated after heparinization, and coronary artery bypass grafting of 4 vessels was performed. During CPB, the patient was perfused by a roller pump at a flow rate of 2.4 U · min/m2. The mean body temperature was maintained between 32°C–34°C and the mean blood pressure was maintained at 60–70 mm Hg. When surgery was completed after 4 h, the aortic cross-clamp was released, and the patient was rewarmed to a body temperature of 37°C. The weaning from cardiopulmonary bypass was successful. Heparinization was reversed with protamine and the patient was transferred to the intensive cardiac care unit. The patient awoke 6 h later, and the trachea was extubated. However, the patient was unable to move any of his four limbs. Neurological examination revealed complete paralysis of his four limbs associated with loss of sensation. An urgent cervical magnetic resonance imaging scan revealed a congenital cervical stenosis extending from C3 to C6, associated with a posterior disk herniation at C6-C7 compressing the cervical cord, which was focally edematous (Fig. 1). Immediately, an anterior surgical decompression with spinal instrumentation was performed (Fig. 2). After the operation, neurological examination showed a significant improvement and revealed a partial brown squared syndrome. Urinary and anal incontinence were also recorded. Six weeks later, the patient left the hospital. However, 3 mo later the patient died from bowel perforation and respiratory failure. The present report agrees with the previous report of Fujioka et al. (1), who speculated that placing the neck in an extended position during surgery might aggravate a preexisting spinal canal stenosis, resulting in cervical cord injury. Also, this report suggests that we should avoid extending the neck in patients with a preoperative diagnosis of cervical spine stenosis and that the neck should be manipulated similarly to manipulation of patients with cervical spine fracture. Also, preoperative screening for cervical spine stenosis is advised for elderly patients in whom an extended position of the neck is required.Figure 1.: Preoperative magnetic resonance image scan. Arrows = preoperative magnetic resonance image scan showing C5-C6 stenosis.Figure 2.: Postoperative magnetic resonance image scan. Arrows = postoperative magnetic resonance image scan showing site of C6 corpectomy. C4-C5, C5-C6, discectomy with bone graft and Codman plat®, and screws.Zoher Naja, MD* [email protected] Ahed Zeidan, MD† Hilal Maaliki, MD† Samir Zoubeir, MD‡ R. El-Khatib, MD* Anis Baraka, MD, FRCA** Departments of *Anesthesiology and ‡Neurosurgery, Makassed General Hospital, †Department of Anesthesiology, Sahel General Hospital, and **Department of Anesthesiology, American University of Beirut Medical Center, Beirut, Lebanon

Toxicité du disulfirame (Espéral ®). À propos de trois observations originales

Prescribed since 1948 to control chronic alcoholism, disulfiram may cause severe toxicity as report in three cases of acute motive axonal polyneuritis. Disulfiram toxicity may present different clinical aspects: 1) Cytolytic hepatitis with fatal evolution in 30% of cases (fulminant hepatitis), and full recovery for the other 70%. The onset of the symptoms usually occurs as early as 15 days to a maximum of 6 months (most within 2 months) after initiation of treatment. 2) Severe optic neuritis with full recovery in 2 months. 3) Peripheral neuropathy usually dose dependent, with different clinical presentations: polyneuritis with sensory, motor, or both deficits, and few cases of tetraplegia. 4) Encephalopathy frequently associated with one of the precedent symptoms, having a favorable outcome (probably resulting in inhibition of dopamine-beta-hydroxylase by disulfiram). The mechanism of toxicity (direct or idiosyncractic) remain unclear. Disulfiram has been used safely in millions of people since 1948, and we have only few cases reports of severe toxicity. From a practical point of view, treated patients should benefit by a neurological examination once a month, ophtalmological examination every 2 months, and hepatic enzymes monitored twice a month during the 2 first months. This is the price to prevent and to detect side effects of disulfiram therapy.