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Query: UMLS:C0085437 (
bacterial meningitis
)
4,038
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Lumbar puncture is the best way to prove
bacterial meningitis
. It should be performed without any delay if the diagnosis is suspected. Herniation is a rare complication of LP. CT is normal in most cases of purulent meningitis, including those complicated by a subsequent herniation; normal CT results does not mean that performing a LP is safe. Three main clinical features can help determine which patient is at risk of herniation and should have a CT before LP. This risk has to be determined rapidly in the emergency ward while assessing anamnestic data, localization signs or symptoms, and level of consciousness. Cranial imaging (mainly MRI) is useful in the course of
bacterial meningitis
. Patients who do not respond well to treatment or with atypical presentation, persistence of fever, or new neurological signs should undergo brain imaging; MRI and CT may identify subdural effusions, brain abscesses, empyemas, hydrocephaly, or brain parenchymal changes (cerebritis, infarction, hemorrhage). CT and MRI are useful to screen for an ENT cause of
bacterial meningitis
, and mandatory in case of pneumococcal meningitis. Numerous MRI sequences are useful to identify
bacterial meningitis
complications: SE T1 without and with gadolinium injection, SE T2, FLAIR, gradient-echo T2, diffusion weighted imaging, MR angiography.
Med
Mal
Infect
PMID:[Indication of neuro-imaging for the initial management and the follow-up of acute community-acquired bacterial meningitis]. 1939 88
No prospective randomized clinical studies are available to determine exactly how much time should be spent on investigation before initiating antibiotherapy in a patient with presumed
bacterial meningitis
. Experimental models show that antibiotics should be administered before the inflammatory response, but at this time the patient's symptoms are often unspecific. Models also demonstrate that a gain of time is beneficial at any time, in terms of inflammation, magnitude of bacteremia, or loss of hearing. Very few clinical studies address the acceptable delay between admission and administration of antibiotics and two of these show a correlation with outcome in adult meningitis. The available data supports the recommendation that hospital investigation of a patient with presumed
bacterial meningitis
should be conducted in such a way that efficient antimicrobial chemotherapy will be initiated within one hour after arrival.
Med
Mal
Infect
PMID:[Degree of emergency for antibiotherapy in patients with presumed bacterial meningitis: experimental and clinical data]. 1940 52
Bacterial meningitis
is a medical emergency requiring prompt recognition and evaluation and urgent initiation of appropriate antibacterial therapy. However, early recognition of severe bacterial infection including
bacterial meningitis
is a challenge in infants. Two clinical forms are basically observed in infants and young children: firstly, clinical meningitis which is characterized by fever, usually greater than 39 degrees C, and poorly specific gastrointestinal signs such as refusal of feeding and/or vomiting; irritability, abnormal crying, bulging fontanel, unusual generalized seizures occurring before six months of age and lasting more than 10 min should draw the clinician's attention and lead him/her to perform a lumbar puncture and initiate antibiotics; secondly, severe sepsis which is characterized by tachycardia, cold and/or mottled limbs and sometimes leg pain which should suggest a meningococcal disease; it is quite urgent to administer rapid fluid loading and antibiotic treatment while postponing lumbar puncture before the septic cascade evolves towards septic shock, extensive hemorrhagic rash, and ischemic limbs. Given the relative frequency of viral self-limiting diseases and rarity of serious bacterial infections, guidelines were published to guide the clinician's decision when dealing with a febrile infant. However, an alternative to these guidelines was recently suggested with a more clinically oriented decision-making attitude appearing as efficient while limiting hospitalizations.
Med
Mal
Infect
PMID:[Clinical signs suggestive of bacterial meningitis in infants]. 1940 42
The management of
bacterial meningitis
is based on the combination of several components. The objective of this review is to give an overview of the literature concerning both the arguments for urgent antibiotic treatment associated with a particular focus on the place of corticosteroids. Among other treatments, glycerol seems the best rated but symptomatic measures, which may not be achieved by randomized studies, should not be overlooked. Many animal studies explore other treatment options, but none can be translated into clinical practice. The neuroimaging has been little evaluated despite recent technological advances but remains important in monitoring of patients whose evolution is considered unfavorable.
Med
Mal
Infect
PMID:[Emergency antibiotherapy and adjuvant treatments for acute bacterial meningitis]. 1940 43
Bacterial meningitis
is still a serious disease with a high risk of mortality and sequels. The progress in antibiotic treatment has not improved the prognosis. Thus, optimizing the initial care and the treatment of the most severe cases should improve the outcome. No study has compared the outcome according to the level of care at the admission site. There is evidence that the most severe cases should be managed by critical care units. It seems reasonable to recommend initial admission of common cases to units able to provide intensive care. Most people now agree that fluid restriction has not demonstrated its efficiency, furthermore it might have deleterious effects. However, a fluid overload should be avoided. Maintaining cerebral perfusion is a key issue in the treatment of
bacterial meningitis
and requires monitoring both arterial blood pressure and intracranial pressure. Intracranial pressure monitoring is probably useful to optimize the treatment of the most severe cases. The aggressive treatments of cerebral edema have not been evaluated but seem, in some limited series, able to improve some life threatening situations. The benefit of systematic glycerol administration needs confirmation. Seizures should be treated with the usual medications. However, drugs with potentially deleterious effects on hemodynamics should be avoided. There is no sufficient evidence to support the administration of a systematic prophylactic treatment. Fever should be treated when above 39.5 degrees C/40 degrees C and in the case of intracranial hypertension. There is no clinical study to explore the modifications of fever on bacterial growth or on inflammation as observed in some experimental studies.
Med
Mal
Infect
PMID:[Adjunctive therapies (excluding corticosteroids). Site of initial management]. 1941 Apr 4
The epidemiology of
bacterial meningitis
has changed since the last French consensus in 1996, mainly because of more frequent Haemophilus influenzae B and pneumoccocus vaccination. A research PubMed and Cochrane databases was performed for articles published within the past 12 years, mentioning the diagnosis, surveillance, and follow-up of presumed
bacterial meningitis
in children. Sixty-one references were included among the 1606 on PubMed and 50 on the Cochrane databases. Additional articles (n=35) were identified using the references of selected articles. The definition of
bacterial meningitis
was reviewed, particularly when the causal agent was not identified. Clinical and biological criteria for the diagnosis and the place of brain imaging were updated. Guidelines available after the common use of Haemophilus influenzae vaccination were analyzed with their level of evidence. Initial surveillance data and risk factors associated with death or poor outcome were reviewed. The short and long-term follow-up was also analyzed to identify the proper follow-up for children.
Med
Mal
Infect
PMID:[Management strategy for pediatric presumptive bacterial meningitis (diagnosis, surveillance, follow-up)]. 1941 Apr 5
Meningeal defects and primitive ENT infections are known to promote pneumococcal meningitis. Other risk factors can be identified in the occurrence of community acquired
bacterial meningitis
(CABM) and play a key role either in the frequency of this kind of infection, the type of bacteria concerned, the prognosis or the risk of recurrence. Thus, epidural infiltrations are rarely responsible for staphylococcal or streptococcal meningitis. Cochlear implants are also known to increase the risk of pneumococcal meningitis. The occurrence in children of aseptic meningitis or meningitis due to Staphylococcus aureus or Enterobacteriaceae is strongly suggestive of congenital spinal or cerebral anomalies (dermal sinus or spina bifida). MRI must be rapidly performed. In cases of splenectomy or asplenism, pneumococcal meningitis is common and must be prevented. According to the larger series available on this topic, age over 60, diabetes mellitus, alcoholism and immune deficiency are found to promote CABM in about 25% of cases. Streptococcus pneumoniae is the most frequent causative bacteria in elderly patients, in case of alcoholism, as well as Listeria monocytogenes and some Enterobacteriaceae (Escherichia coli, Klebsiella pneumoniae). L. monocytogenes is frequently isolated in immunodepressed patients and patients treated by anti-TNF molecules (infliximab notably). Finally, some genetic polyphormisms promote CABM: complement and properdin deficiencies (meningococcal meningitis), mannose-binding lectin deficiency, Fcgamma receptors alteration or interleukin-1 and IL-1R polymorphisms. Screening for such genetic disorders may be discussed in case of CABM but is mandatory in case of recurrent meningococcal infections.
Med
Mal
Infect
PMID:[Predisposing factors of community acquired bacterial meningitis (excluding neonates)]. 1941 29
CSF sterilization should be obtained very rapidly to reduce both mortality and morbidity due to
bacterial meningitis
. Thus, antibiotic treatment should be adapted to the suspected bacterium and administered as early as possible at high dosage with - if necessary - a loading dose and continuous perfusion. The rates of abnormal susceptibility to penicillin of Streptococcus pneumoniae, Neisseria meningitis and Haemophilus influenzae are 37%, 30% and 12% respectively. Thus, ceftriaxone or cefotaxim must be used as empirical treatment. Listeria monocytogenes remains fully susceptible to aminopenicillin, so, the combination aminopenicillin and aminoglycoside is the first-line treatment. Antibiotic resistance, allergy or contra-indications, are in fact rare but in these cases, antibiotic combinations are often needed. The latter are more or less complex and clinically validated; they include molecules such as vancomycine, fosfomycin, fluoroquinolone or linezolid.
Med
Mal
Infect
PMID:[Presumptive bacterial meningitis in adults: initial antimicrobial therapy]. 1942 7
Early clinical data must lead to suspect
bacterial meningitis
if fever, the most frequent sign, is present and if it is associated with more or less constant neurological and meningeal signs (consciousness impairment, headache, neck stiffness, focal neurological deficit, seizure, etc.). A skin rash is frequent in case of meningococcal meningitis whereas cranial nerve palsy is more in favor of tuberculous or Listeria meningitis. Presence of otitis, sinusitis, pneumonia, or a recent head trauma strongly suggests a pneumococcal involvement. Tuberculous meningitis is generally characterized by a slow evolution of meningeal signs together with aspecific signs. The main prognostic factors are consciousness impairment, circulatory instability, focal neurological signs, and advanced age. Morbidity and mortality are increased in case of pneumococcal compared to meningococcal meningitis. Cranial tomodensitometry gives further information about intracranial complications of meningitis. In some cases, particularly if focal neurological or intracranial hypertension signs are present, it must be performed before a lumbar puncture. The risk factors of meningitis must be investigated and treated if possible according to the bacterium. The management of patient after hospital discharge depends on evolution after treatment. The presence of neurological sequels imposes a specialized ambulatory follow-up. Neuropsychological sequels (cognitive dysfunction, memory impairment) can also persist for years even in absence of other neurological disorders.
Med
Mal
Infect
PMID:[Managing adult patients with acute community-acquired meningitis presumed of bacterial origin]. 1947 96
In most cases, differentiating viral from
bacterial meningitis
is relatively easy, based on clinical examination, CSF appearance and results of CSF examination (cytology, biochemistry and Gram stain). However, in about 20% of cases, this diagnosis may be difficult. For such cases, additional non-microbiological tests may be helpful. CSF lactate level is a good predictor of
bacterial meningitis
for values greater than 3.5 mmol/l. Serum procalcitonin is effective to discriminate between bacterial and viral meningitis, using a threshold between 1 and 2 ng/ml, although this parameter may fail in individual situations. Accurate diagnosis scores or models have been validated and may be used in routine clinical practice, especially in emergency rooms, both for adults and children to help identify patients with a very low probability of
bacterial meningitis
in whom antibiotic may thus be avoided.
Med
Mal
Infect
PMID:[Differentiating bacterial from viral meningitis: contribution of nonmicrobiological laboratory tests]. 1956 Aug 87
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