Ceftazidime-avibactam-based combination therapy for hospital-acquired central nervous system infections caused by carbapenem-resistant Klebsiella pneumoniae.

OBJECTIVES: Klebsiella pneumoniae (K. pneumoniae) is one of the most common bacteria in the hospital-acquired central nervous system (CNS) infections. Central nervous system infections caused by carbapenem-resistant K. pneumoniae (CRKP) are associated with significant mortality rates and high hospital costs due to limited antibiotic treatment options. This retrospective study aimed to evaluate the clinical efficacy of ceftazidime-avibactam (CZA) for the treatment of CNS infections caused by CRKP. METHODS: Twenty-one patients with hospital-acquired CNS infections caused by CRKP who received treatment with CZA for ≥ 72 hours were enrolled. The primary outcome was to assess the clinical and microbiology efficacy of CZA for the treatment of CNS infections caused by CRKP. RESULTS: A high burden of comorbidity was discovered in 20 of 21 patients (95.2%). Most patients had a history of craniocerebral surgery and 17 (81.0%) of the patients were in the intensive care unit with a median APACHE II score of 16 (IQR 9-20) and SOFA score of 6 (IQR 3-7). Eighteen cases were treated by CZA-based combination therapies, while the remaining three cases were treated with CZA alone. At the end of the treatment, the overall clinical efficacy was 76.2% (16 of 21) with a bacterial clearance rate of 81.0% (17 of 21) and all-cause mortality of 23.8% (five of 21). CONCLUSION: This study showed that CZA-based combination therapy is an effective treatment option for CNS infections caused by CRKP.

Intravenous plus intraventricular tigecycline-amikacin therapy for the treatment of carbapenem-resistant Klebsiella pneumoniae ventriculitis: A case report.

RATIONALE: Central nervous system infections (CNSIs) are one of the most serious complications after neurosurgery, especially carbapenem-resistant bacterial meningitis. Owing to the poor blood-brain barrier permeability of most antibiotics, the treatment of CNSIs by intraventricular (IVT) administration is becoming a hot topic in clinical research. Currently, the treatment of CNSIs caused by carbapenem-resistant Klebsiella pneumoniae is mainly based on intraventricular injection of an antibiotic combined with one or more other systemic intravenous (IV) antibiotics, whereas there are few case reports of intraventricular injection of 2 antibiotics. PATIENT CONCERNS: A 57-year-old man with an open craniocerebral injury presented with dyspnea, high fever, and seizures associated with surgery. DIAGNOSIS: Intracranial infection caused by carbapenem-resistant K. pneumoniae was diagnosed. INTERVENTIONS: On the advice of a clinical pharmacist, the patient was given tigecycline (100 mg IV + 3 mg IVT q12h) combined with amikacin (0.8 g IV + 30 mg IVT qd) antiinfective therapy. Ultimately, the pathogens in the cerebrospinal fluid were eradicated after 7 days, and the CNSIs were completely cured after 14 days. OUTCOMES: The patient recovered and was discharged from the hospital without adverse reactions. LESSONS: A series of in vitro and in vivo synergy tests of carbapenem-resistant K. pneumoniae showed that tigecycline combined with aminoglycosides had good synergistic effects and effectively suppressed bacterial resistance selection. Intravenous plus intraventricular tigecycline-amikacin seems to be a safe and effective treatment option for carbapenem-resistant K. pneumoniae CNSIs.

Ceftazidime-avibactam for the Treatment of Multidrug-resistant Pseudomonas aeruginosa Central Nervous System Infection in Pediatric Patient: A Case Report.

Very limited experimental and clinical data are currently available regarding the cerebrospinal fluid (CSF) penetration of ceftazidime-avibactam in adults. Nevertheless, up to our knowledge, there are no data of ceftazidime-avibactam use in central nervous system infections in pediatric patients. For that, here we describe our experience with the use of ceftazidime-avibactam in addition to intraventricular colistin in a pediatric patient diagnosed with ventriculoperitoneal shunt infection due to multidrug-resistant P. aeruginosa. A 2-year-old boy known to pre-term, delivered at 26 weeks with hydrocephalus that required ventriculoperitoneal shunt which was infected due to P. aeruginosa. He was treated with multiple antipseudomonal agents; however, cultures remained persistently positive. On day 54 of admission, the isolate was reported as multidrug-resistant P. aeruginosa and he was switched to ceftazidime-avibactam and intraventricular colistin. CSF cultures became sterile 3 days after initiation of this antibiotic regimen, and subsequent CSF cultures had no growth. No recurrent episode of central nervous system infections due to P. aeruginosa occurred up to 2 years of follow-up.

Sarocladium and Acremonium infections: New faces of an old opportunistic fungus.

The genera Acremonium and Sarocladium comprise a high diversity of morphologically and genetically related fungi generally found in the environment, although a few species, mainly Sarocladium kiliense and Acremonium egyptiacum, can also be involved in many human infections. Clinical management of opportunistic infections caused by these fungi is very complex, since their correct identification is unreliable, and they generally show poor antifungal response. More than 300 clinical cases involving a broad range of Acremonium/Sarocladium infections have so far been published, and with this review we aim to compile and provide a detailed overview of the current knowledge on Acremonium/Sarocladium human infections in terms of presentation, diagnosis, treatments and prognoses. We also aim to summarise and discuss the data currently available on their antifungal susceptibility, emphasising the promising results obtained with voriconazole as well as their impact in terms of animal infections.

Spinal arachnoiditis followed by intrathecal tigecycline therapy for central nervous system infection by extremely drug-resistant Acinetobacter baumannii.

In prior research, intrathecal tigecycline was successfully used to treat central nervous system infection by extensively drug-resistant Acinetobacter baumannii. However, little is known about its safe dose and adverse reactions. This study reports the case of a 28-year-old male patient who was diagnosed with central nervous system infection by extensively drug-resistant A. baumannii after the removal of a ventriculoperitoneal shunt. Intravenous and intrathecal tigecycline were administrated simultaneously. Spinal arachnoiditis was discovered after nine doses of intrathecal tigecycline. Spinal arachnoiditis was resolved after discontinuation of the antibiotic. This is the first report of an adverse reaction to intrathecal tigecycline. The case was complicated by spinal arachnoiditis, which obstructed the assessment of cerebrospinal fluid. The appropriate dose and administration schedule of intrathecal tigecycline remain to be determined.

Clinical Use of Colistin in Biofilm-Associated Infections.

Biofilm is an adaptive bacterial strategy whereby microorganisms become encased in a complex glycoproteic matrix. The low concentration of oxygen and nutrients in this environment leads to heterogeneous phenotypic changes in the bacteria, with antimicrobial tolerance being of paramount importance. As with other antibiotics, the activity of colistin is impaired by biofilm-embedded bacteria. Therefore, the recommendation for administering high doses in combination with a second drug, indicated for planktonic infections, remains valid in this setting. Notably, colistin has activity against metabolically inactive biofilm-embedded cells located in the inner layers of the biofilm structure. This is opposite and complementary to the activity of other antimicrobials that are able to kill metabolically active cells in the outer layers of the biofilm. Several experimental models have shown a higher activity of colistin when used in combination with other agents, and have reported that this can avoid the emergence of colistin-resistant subpopulations. Most experience of colistin in biofilm-associated infections comes from patients with cystic fibrosis, where the use of nebulized colistin allows high concentrations to reach the site of the infection. However, limited clinical experience is available in other scenarios, such as osteoarticular infections or device-related central nervous system infections caused by multi-drug resistant microorganisms. In the latter scenario, the use of intraventricular or intrathecal colistin also permits high local concentrations and good clinical results. Overall, the efficacy of intravenous colistin seems to be poor, but its association with a second antimicrobial significantly increases the response rate. Given its activity against inner bioflm-embedded cells, its possible role in combination with other antibiotics, beyond last-line therapy situations, should be further explored.

Treatment principles for Candida and Cryptococcus.

The yeasts Candida and Cryptococcus spp. are important human opportunistic pathogens. Candida spp. rely on skin or mucosal breach to cause bloodstream infection, whereas Cryptococcus spp. exploit depressed cell-mediated immunity characteristic of advanced HIV infection. The treatment for both organisms relies on the administration of rapidly fungicidal agents. In candidaemia, source control is important, with removal of prosthetic material and drainage of collections, as well as hunting for and tailoring therapy to disseminated sites of infection, particularly the eyes and heart. For cryptococcal meningitis, restoration of immune function through antiretroviral therapy (ART) is key, together with careful management of the complications of raised intracranial pressure and relapsed infection, both pre- and post-ART.

Cerebrospinal fluid shunt infection due to Gemella haemolysans.

Gemella haemolysans has long been considered a commensal in the human upper respiratory tract. Commensals are natural inhabitants on or within another organism, deriving benefit without harming or benefiting the host. Opportunistic infection of the CNS by the species is exceedingly rare. In the present case, a 16-year-old boy was admitted with a ventriculoperitoneal shunt infection, which was confirmed to be due to G. haemolysans. Following antibiotic treatment, removal of the old shunt, and delayed insertion of a new shunt, the patient made a full neurological recovery. To the authors' knowledge, this is the eighth case of CNS infection with G. haemolysans. Although prosthesis-related infections have been reported in other systems, this is the first case of CNS infection by the bacterium associated with an implant. Previous reported cases of CNS infection by G. haemolysans are reviewed. Due to the variable Gram staining property of the organism, the difficulty in diagnosing G. haemolysans infection is emphasized.

Pharmacologic options for CNS infections caused by resistant Gram-positive organisms.

Infectious disease continues to evolve, presenting new and challenging clinical situations for practitioners. Specific to device-related and neurosurgical-related CNS infections, Gram-positive organisms are of growing concern. Current Infection Disease Society of America guidelines for the treatment of CNS infections offer little direction after conventional therapy, consisting of vancomycin, has failed or the patient has demonstrated intolerance. A review of literature evaluating alternative therapies, specifically linezolid, quinupristin/dalfopristin, daptomycin and tigecycline, will be presented. Interpretations of these data are offered followed by a brief presentation of future therapies, including ortavancin, telavancin, dalbavancin, ceftobiprole and iclaprim, all of which possess potent Gram-positive activity.

Neurologic complications of anthrax: a review of the literature.

A review of the literature suggests that the major neurologic symptom complex of infection by Bacillus anthracis is a fulminant and rapidly fatal hemorrhagic meningoencephalitis and that the reported initial mode of entry can be via the cutaneous or inhalation route. For febrile patients with acute neurologic deterioration with associated findings of dark necrotic pustules on the extremities, gram-positive rods in the cerebrospinal fluid, and multifocal areas of unexplained intracerebral hemorrhage on computed tomographic scans, anthrax should be considered within the differential diagnosis. A low cerebrospinal fluid glucose level has been reported, with gram-positive rods often noted on the gram stain of the cerebrospinal fluid in severely affected patients. Reports indicate that death usually occurs within a week.

Pharmacokinetic optimisation of the treatment of bacterial central nervous system infections.

Central nervous system (CNS) infections caused by bacteria with reduced sensitivity to antibacterials are an increasing worldwide challenge. In successfully treating these infections the following conditions should be considered: (i) Antibacterials do not distribute homogeneously in the central nervous compartments [cerebrospinal fluid (CSF), extracellular space of the nervous tissue, intracellular space of the neurons, glial cells and leucocytes]. Even within the CSF, after intravenous administration, a ventriculo-lumbar concentration gradient is often observed. (ii) Valid parameters of drug entry into the CSF are the CSF: serum concentration ratio in steady state and the CSF: serum ratio of the area under the concentration-time curves (AUCCSF/AUCS). Frequently, the elimination half-life (t1/2 beta) in CSF is longer than t1/2 beta in serum. (iii) For most antibacterials, lipophilicity, molecular weight and serum protein binding determine the drug entry into the CSF and brain tissue. With an intact blood-CSF and blood-brain barrier, the entry of hydrophilic antibacterials (beta-lactam antibacterials, glycopeptides) into the CNS compartments is poor and increases during meningeal inflammation. More lipophilic compounds [metronidazole, quinolones, rifampicin (rifampin) and chloramphenicol] are less dependent on the function of the blood-CSF and blood-brain barrier. (iv) Determination of the minimal inhibitory concentrations (MIC) of the causative organism is necessary for optimisation of treatment. (v) For rapid sterilisation of CSF, drug concentrations of at least 10 times MIC are required. The minimum CSF concentration: MIC ratio ensuring successful therapy is unknown. Strategies to achieve optimum antibacterial concentrations in the presence of minor disturbances of the blood-CSF and blood-brain barrier include, the increased use of low toxicity antibacterials (e.g., beta-lactam antibiotics), the use of moderately lipophilic compounds, and the combination of intravenous and intraventricular administration. Antibacterials which do not interfere with bacterial cell wall synthesis delay and/or decrease the liberation of proinflammatory bacterial products, delay or inhibit tumour necrosis factor release, and may reduce brain oedema in experimental meningitis. Conclusive evidence of the reduction of neuronal damage by this approach, however, is lacking.