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Gas-Containing Cervical Epidural Abscess Accompanying Bacterial Meningitis in an Adult

Article information

Korean J Spine. 2017;14(1):17-19
Publication date (electronic) : 2017 March 31
doi : https://doi.org/10.14245/kjs.2017.14.1.17
1Department of Internal Medicine, Chosun University College of Medicine, Gwangju, Korea
2Department of Neurosurgery, Chosun University College of Medicine, Gwangju, Korea
Corresponding Author: Seok Won Kim, Department of Neurosurgery, Chosun University College of Medicine, 365 Pilmun-daero, Dong-gu, Gwangju 61453, Korea, Tel: +82-62-220-3126, Fax: +82-62-227-4575, E-mail: chosunns@chosun.ac.kr
Received 2016 December 12; Revised 2017 March 2; Accepted 2017 March 3.

Abstract

Gas-containing spinal epidural abscesses are uncommon. Moreover, acute spinal epidural abscesses rarely complicate bacterial meningitis in adults. Here, we report a rare case of a gas-containing cervical epidural abscess accompanying bacterial meningitis. In spite of aggressive fluid and continuous antibiotic therapy after the isolation of Streptococcus anginosus and Streptococcus constellatus in the cerebrospinal fluid cultures, the patient showed remaining motor dysfunction and bladder involvement. Our experience suggests that the effort to prevent neurologic deterioration by emergent surgical decompression and drainage of pus is mandatory to avoid additional spinal cord dysfunction in patients with spinal epidural abscesses accompanying bacterial meningitis.

INTRODUCTION

The neurological complications of bacterial meningitis include cerebrovascular involvement such as hydrocephalus, seizures, hearing impairment, cranial nerve palsies, and hemi- or quadriparesis, and systemic complications such as septic shock, or disseminated intravascular coagulation10,12). However, acute spinal epidural abscesses rarely complicate bacterial meningitis in adults. Spinal epidural abscesses are an uncommon occurrence with high morbidity and mortality in case of a delay in diagnosis. Moreover, gas-containing spinal epidural abscesses are extremely rare2,46). As far as the authors’ knowledge, this case is unusual due to the extensive gas-containing spinal abscess accompanying bacterial meningitis in an adult. Here, we report an uncommon case of marked motor dysfunction as an unusual complication of a gas-containing acute spinal abscess accompanying bacterial meningitis.

CASE REPORT

A previously healthy 56-year-old male patient was admitted to the Otorhinolaryngology Department with a 5-day history of febrile sense and neck swelling with swallowing difficulty. At admission, he was alert, and his vital signs were stable except for a high fever, which was 39.2°C, along with a sore throat; he was admitted to the Otorhinolaryngology Department. However, there was no focal infection in fiber-optic laryngoscopy, and due to the focal neurological sign of a stiff neck, he was transferred to the Neurosurgery Department. On neurological examination his motor power and sensation were intact. Hematological investigation revealed leukocytosis with a total white blood cell (WBC) count of 12.760/μL, elevation of his erythrocyte sedimentation rate, to 62 mm/hr (normal range, 0–20 mm/hr), and C-reactive protein, to 13.2 mg/dL (normal range, below 0.5 mg/dL). To rule out pyogenic meningitis, a lumbar cerebrospinal fluid (CSF) analysis was performed. The color of the CSF was purulent yellowish (Fig. 1). Lumbar CSF analysis revealed 2,937 WBC cells/μL (poly:mono, 87%:13%) with a glucose level of 31.8 mg/dL, and protein level of 232.9 mg/dL. A computed tomography (CT) scan of the cervical spine demonstrated sparsely scattered gas in the prevertebral space of C4–5 and intraspinal canal of the C4–5 interspace (Fig. 2A). Magnetic resonance imaging (MRI) with gadolinium enhancement revealed an epidural abscess with air bubbles in the anterior aspect of the central spinal canal of C4 and C5, compressing the spinal cord and causing a large amount of retropharyngeal abscesses in the prevertebral space of C1 through C7 (Fig. 2B). Due to its ventral location in the epidural space, the patient underwent open pus and irrigation following gram-stain culture. A yellowish purulent material was identified and retropharyngeal abscess was drained via anterior approach. CSF cultures showed the growth of gram-positive Streptococcus anginosus and Streptococcus constellatus. S. anginosus was also isolated from retropharyngeal abscess. According to an antibiotics susceptibility test, he was given Augmentin (GlaxoSmithKline. Middlesex, UK), Vancomycin (CJ pharmaceuticals, Seoul, Korea), and Metronidazole (CJ pharmaceuticals). Despite aggressive fluid and antibiotic therapy, he did not respond to treatment, in fact, his symptoms worsened. 10 days after admission, the patient’s level of consciousness deteriorated gradually to a drowsy state and showed tetraparesis at GIII/GIII. Brain MRI and magnetic resonance angiography with gadolinium enhancement showed no visible pathological enhanced lesions except for mild hydrocephalus. Cervical MRI with gadolinium enhancement revealed an aggravated high signal intensity of the spinal cord at the level of C5 through T1, suggesting spinal cord dysfunction with a remaining ventral epidural abscess pocket (Fig. 3). At this time, the patient’s body temperature was 39.8°C. WBC count steadily rose to 18.295 cells/μL, heart rate to 120 beats/min, respiratory rate to 24 breaths/min, and arterial CO2 tension to 26 mmHg, which indicated a septic condition. He was transferred to Infectious Diseases Department. On the 60th day of hospitalization, at the end of the prolonged antibiotic treatment, MRI revealed a marked regression of the lesions compared to the previous MRI, but little clinical improvement (Fig. 4). He was awake, alert, and oriented, but his muscle strength and occasional urinary incontinence were not improved. He was not able to walk by himself due to the flaccidity of both feet. Deep tendon reflexes were also persistent appeared in the lower extremities.

Fig. 1

Purulent yellowish cerebrospinal fluid collected in test tubes.

Fig. 2

Cervical computed tomography scan (A) and magnetic resonance image (B) show epidural abscess with air bubbles compressing anterior spinal cord at C4 and C5 and a large amount of retropharyngeal abscess.

Fig. 3

T2-weighted sagittal image (A) and gadolinium enhanced magnetic resonance image (B) reveal extensive high signal intensity of the spinal cord at C5 through T1 and a remaining epidural abscess.

Fig. 4

T2-weighted sagittal (A) and gadolinium enhanced magnetic resonance (B) images at 60th day after admission show the absorbed retropharyngeal and epidural abscesses without enhancement.

DISCUSSION

This case is unusual in some aspects. First, gas-containing spinal epidural abscesses are extremely rare. Second, acute spinal epidural abscesses rarely complicate bacterial meningitis in adults. Third, a causative pathogen of the meningitis was isolated, but the patient subsequently had residual abnormalities, such as motor dysfunction and bladder involvement, caused by spinal cord dysfunction. To the best of our knowledge, a gas-producing spinal epidural abscess complicating bacterial meningitis has never been reported in an adult. Spinal epidural abscess is a diagnosis that may constitute a neurological emergency, which can result in catastrophic and irreversible neurological damage in the case of a delay in diagnosis1).

Usually, a fever and neck or back pains are the initial symptoms of a spinal epidural abscess. However, by the time of diagnosis, patients usually develop motor and sensory deficits with a loss of sphincter control. Patients with diabetes and those on systemic steroids are at higher risk, and the outcome in these groups is worse. The pathogenesis of spinal epidural abscesses involves several mechanisms. Infection may occur via direct extension of a local process (vertebral osteomyelitis, perinephric, retropharyngeal or psoas abscesses, or decubitus ulcers) or by hematogenous or lymphatic spread4). Ischemia of the spinal cord is the principal pathological process, along with thrombosis of leptomeningeal vessels and compression of spinal arteries. Other causes of ischemia are hypoperfusion resulting from shock or compression of the spinal cord, or edema or inflammation associated with arachnoiditis9).

Cerebral septic venous thrombosis is a well-recognized complication of purulent meningitis, and compromised venous drainage of the spine, septic venous thrombosis, or adhesive arachnoiditis is also conceivable in meningitis3). In this case, spinal cord dysfunction resulted from the cervical epidural abscess complicating bacterial meningitis. Plain radiographs are usually normal unless there is concomitant vertebral osteomyelitis. CT may show a loss of epidural fat, abnormal enhancement between bone and the dural sac, and an intraspinal space-occupying soft tissue mass7). However, MRI reveals the extent and location of an abscess better than CT. MRI can also detect spinal and paraspinal infections, and is now recommended as a radiological exam in spinal infection8). Early surgical drainage of pus is considered as the mainstay of the treatment for spinal epidural abscess11). In spite of the appropriate therapy, residual abnormalities such as motor dysfunction or bowel and bladder involvement continue to exist in most patients, as has been reported in 18 survivors out of 23 patients with spinal cord dysfunction after bacterial meningitis in a study conducted by Moffett and Berkowitz9) The present case is unusual due to the possibility of connection or dissemination between extensive retropharyngeal abscess and cervical spine and meninges. The causative organisms were isolated from the CSF culture and retropharyngeal abscess. Due to the anterior location of the pus, surgical decompression of the pus was not performed in compliance with the wishes of his family and patient’s refusal of surgical treatment. In such situations, a prolonged course of adequate antibiotics is essential.

CONCLUSION

We report a rare case of a gas-producing epidural abscess complicating bacterial meningitis in an adult. The effort to prevent neurologic deterioration by emergent surgical decompression and drainage of pus is mandatory to minimize the morbidity and mortality resulting from misdiagnosis.

ACKNOWLEDGEMENT

This study was supported by research fund from Chosun University 2016

Notes

CONFLICT OF INTEREST

No potential conflict of interest relevant to this article was reported.

References

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Article information Continued

Fig. 1

Purulent yellowish cerebrospinal fluid collected in test tubes.

Fig. 2

Cervical computed tomography scan (A) and magnetic resonance image (B) show epidural abscess with air bubbles compressing anterior spinal cord at C4 and C5 and a large amount of retropharyngeal abscess.

Fig. 3

T2-weighted sagittal image (A) and gadolinium enhanced magnetic resonance image (B) reveal extensive high signal intensity of the spinal cord at C5 through T1 and a remaining epidural abscess.

Fig. 4

T2-weighted sagittal (A) and gadolinium enhanced magnetic resonance (B) images at 60th day after admission show the absorbed retropharyngeal and epidural abscesses without enhancement.