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Treatment of meningitis
Last reviewed: 23.04.2024
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Before the treatment of meningitis, patients with a presumptive diagnosis should undergo spinal puncture (the main method of confirming the diagnosis).
Treatment of viral meningitis
Due to the fact that viral meningitis is considered to be life-threatening diseases, antiviral therapy is very limited. Indications for the use of antiviral drugs are severe complications or recurrence of meningitis. For the treatment of meningitis caused by the herpes simplex virus, aciclovir is used at a dose of 10 mg / kg at 8 hours for adults and 20 mg / kg at 8 hours for children. For the treatment of meningitis caused by enteroviruses, change plexonil - a low-molecular inhibitor of piconaviruses. It should be noted that his clinical trials continue, since in small clinical studies, his positive effect on the duration of the headache compared to placebo was noted.
Treatment of viral meningoencephalitis
Currently, there are antiviral drugs that are active against herpesviruses type 1 and type 2, herpes zoster virus, cytomegalovirus and HIV. The use of acyclovir (10 mg / kg in adults and 20 mg / kg in children at 8 h intravenously) for 21 days significantly reduced the lethality of patients with generalized herpetic infection and herpetic encephalitis from 70% to 40%. The degree of neurologic damage in surviving patients decreased from 90% to 50%. It was not possible to accurately assess the inefficiency of acyclovir, it is estimated that it is about 5%.
The combined use of acyclovir (10 mg / kg in adults and 20 mg / kg in children at 8 h intravenously) for 21 days and a specific immunoglobulin against the herpes zoster virus dramatically reduced the incidence of complications in neonatal children and patients with immunosuppression. Despite the lack of reliable evidence of high efficacy of acyclovir in the case of encephalitis, it is usually used in everyday practice.
For the treatment of cytomegalovirus encephalitis in HIV-infected patients, ganciclovir is used (5 mg / kg intravenously after 12 hours for 14 days, then 5 mg / kg intravenously after 24 hours) and sodium foscarnet (90 mg / kg intravenously after 12 hours for 14 days , then 90 mg / kg intravenously after 24 hours), although there is no reliable evidence of efficacy to date. In addition, it is not clear what is the possible positive effect of treatment with the suppression of viral action on the central nervous system, a positive effect on the function of the immune system (reducing the viral load) or a decrease in the negative impact of opportunistic infections.
There are no reliable data on the effectiveness of immunomodulatory therapy in patients with viral encephalitis. In practice, some physicians try to use immunomodulators to limit the destruction of the CNS by T cells with cytotoxic activity. As a rule, the authors point out the effectiveness of the method developed by them and, unfortunately, do not indicate the number of cases of ineffective use and iatrogenic complications arising in the course of treatment, which can also lead to an unfavorable outcome of the infection.
Treatment of bacterial meningitis and meningoencephalitis
Recommendations on the treatment of bacterial infections of the central nervous system have been repeatedly reviewed, which is associated with a changing epidemiological situation, a change in the etiological structure of pathogens and their sensitivity to antibiotics. Modern recommendations for the treatment of bacterial CNS infections are presented in the tables. The levels of evidence of antimicrobial therapy regimens are presented in parentheses.
Recommendations for the antimicrobial therapy of purulent meningitis based on the age of patients and concomitant pathology
| Predisposing factor | The most likely causative agent | Antimicrobial therapy |
| Age | ||
|
<1 month |
Streptococcus agalactiae, Escherichia coli, Listeria monocytogenes, Klebsiella spp. |
Ampicillin + cefotaxime, Ampicillin + aminoglycosides |
|
1-23 months |
Streptococcus pneumoniae, Neisseria meningitidis, S. Agalactiae, Haemophilus influenzae, E. Coli |
Cephalosporins of the 3rd generation ab |
|
2-50 years |
N. Meningitidis, S. Pneumoniae |
Cephalosporins of the 3rd generation ab |
|
> 50 years |
S. Pneumoniae, N. Meningitidis, L. Monocytogenes, aerobic gram-negative rods |
Third-generation cephalosporins + ampicillin ab |
|
Type of pathology |
||
|
Fracture of the base |
S. Pneumoniae H. Influenzae, ß-hemolytic streptococci of the group A |
Third-generation cephalosporins |
|
Penetrating craniocerebral injury |
Staphylococcus aureus, coagulase-negative staphylococci (especially Staphylococcus epidermidis), aerobic gram-negative bacteria (including Pseudomonas aeruginosa) |
Cefepime, ceftazidime, meropenem |
|
After neurosurgical operations |
Aerobic Gram-negative bacteria (including P. Aeruginosa), S. Aureus, coagulase-negative staphylococci (especially S. Epidermidis) |
Cefepime + vancomycin / linezolid, ceftazidime + vancomycin / linezolid |
|
CNS shunts |
Coagulase-negative staphylococci (especially S. Epidermidis), S. Aureus, aerobic gram-negative bacteria (including Pseudomonas aeruginosa) Propionibacterium acnes |
Cefepime + vancomycin / linezolid in, ceftazidime, vancomycin + / linezolid in |
- a - ceftriaxone or cefotaxime,
- b - some experts recommend the addition of rifampicin,
- in - newborns and children, monotherapy with vancomycin can be prescribed, if Gram staining does not reveal gram-negative microbes
The role of vancomycin / linezolid
In the treatment of primary community-acquired bacterial meningitis, drugs are used to suppress multiresistant Streptococcus pneumoniae, since in the presence of S. Pneumoniae resistance to benzylpenicillin, third-generation cephalosporins are the most appropriate treatment regimen. Considering the fact that epidemiological data on the relevance of multidrug-resistant S. Pneumoniae in the etiological structure of bacterial meningitis have not been sufficiently studied, the advisability of including vancomycin in the regimens of starting therapy of this group of patients is justified by the extraordinary importance of adequate starting therapy. However, according to some domestic authors, the incidence of multidrug-resistant S. Pneumoniae in the etiologic structure of bacterial meningitis is less than 1%, which calls into question the advisability of using vancomycin in regions where there is evidence of a low occurrence of such strains of pneumococci.
In regimens for the treatment of secondary meningitis associated with CCT or neurosurgical operations, vancomycin / linezolid is used against staphylococci with resistance to oxacillin. Overcoming this type of resistance with ß-lactam antibiotics (penicillins, cephalosporins, carbapenems) is impossible, and the use of vancomycin should be considered as a forced measure. With respect to methicillin-susceptible strains of staphylococci, the clinical efficacy of β-lactam antibiotics is substantially higher, so it is advisable to use this group, primarily oxacillin, and vancomycin should be discontinued.
Recommendations for the antimicrobial therapy of bacterial meningitis, based on microbiological data and the definition of sensitivity to antibiotics
| Causative agent, sensitivity | Standard Therapy | Alternative Therapy |
Streptococcus pneumoniae
|
IPC of benzylpenicillin <0 1 μg / ml |
Benzylpenicillin or ampicillin |
Cephalosporins third generation and chloramphenicol |
|
IPC of benzylpenicillin 0 1-1 0 μg / ml |
Cephalosporins third generation and |
Cefepime, meropenem |
|
IPC of benzylpenicillin> 2.0 μg / ml |
Vancomycin + cephalosporins of 3rd generation av |
Fluoroquinolones g |
|
MIC of cefotaxime or ceftriaxone> 1 μg / ml |
Vancomycin + cephalosporins of the 3rd generation av |
Fluoroquinolones g |
Neisseria meningitidis
|
IPC of benzylpenicillin <0.1 μg / ml |
Benzylpenicillin or ampicillin |
Cephalosporins third generation and chloramphenicol |
|
IPC of benzylpenicillin 0.1-1.0 μg / ml |
Cephalosporins third generation and |
Chloramphenicol, fluoroquinolones meropenem |
|
Listeria monocytogenes |
Ampicillin benzylpenicillin or d |
Co-trimoxazole meropenem |
|
Streptococcus agalactiae |
Ampicillin benzylpenicillin or d |
Third-generation cephalosporins |
|
Escherichia coh and other Enterobacteriaceae hedgehog |
Third-generation cephalosporins (A-P) |
Fluoroquinolones meropenem, co-trimoxazole, ampicillin |
|
Pseudomonas aeruginosa f |
Cephepimid or ceftazidime (A-P) |
Ciprofloxacin d meropenem d |
Haemophilus influenzae
|
Without production of ß-lactamases |
Ampicillin |
Third-generation cephalosporins and cefepime chloramphenicol, fluoroquinolones |
|
With the production of ß-lactamases |
Third-generation cephalosporins (AI) |
Cefepime chloramphenicol, fluoroquinolones |
Staphylococcus aureus
|
Sensitive to oxacillin |
Oxacillin |
Meropenem |
|
Resistant to oxacillin or methicillin |
Vancomycin e |
Linezolid, rifampicin, Co-trimoxazole |
| Staphylococcus epidermidis | Vancomycin e | Linezolid |
Enterococcus spp.
|
Sensitive to ampicillin |
Ampicillin + gentamicin |
|
|
Resistant to ampicillin |
Vancomycin + gentamicin |
|
|
Resistant to ampicillin and vancomycin |
Linezolid |
- a - ceftriaxone or cefotaxime,
- b - strains sensitive to ceftriaxone and cefotaxime,
- c - if the MIC of ceftriaxone> 2 μg / ml, rifampicin may additionally be prescribed,
- g - moxifloxacin,
- d - aminoglycosides may additionally be prescribed,
- e - Rifampicin may additionally be prescribed,
- g - drug selection only based on the in vitro sensitivity test of the strain
Doses of antibiotics for the treatment of bacterial meningitis
| Antimicrobial preparation | Daily dose, dosing interval | |||
| Newborns, age, days | Children | Adults | ||
|
0-7 |
8-28 |
|||
|
Amicacin b |
15-20 mg / kg (12) |
30 mg / kg (8) |
20-30 mg / kg (8) |
15 mg / kg (8) |
|
Ampicillin |
150 mg / kg (8) |
200 mg / kg (6-8) |
300 mg / kg (6) |
12 g (4) |
|
Vancomycin f |
20-30 mg / kg (8-12) |
30-45 mg / kg (6-8) |
60 mg / kg (6) |
30-45 mg / kg (8-12) |
|
Gatifloxacin |
400 mg (24) g |
|||
|
Gentamicin b |
5 mg / kg (12) |
7.5 mg / kg (8) |
7 5 mg / kg (8) |
5 mg / kg (8) |
|
Chloramphenicol |
25 mg / kg (24) |
50 mg / kg (12-24) |
75-100 mg / kg (6) |
4-6 g (6) " |
|
Linezolid |
No data |
10 mg / kg (8) |
10 mg / kg (8) |
600 mg (12) |
|
Meropenem |
120 mg / kg (8) |
6 g (8) |
||
|
Moxifloxacin |
400 mg (24) g |
|||
|
Oxacillin |
75 mg / kg (8-12) |
150-200 mg / kg (6-8) |
200 mg / kg (6) |
9-12 g (4) |
|
Benzylpenicillin |
0.15 million units / kg (8-12) |
0.2 million units / kg (6-8) |
0.3 million units / kg (4-6) |
24 million units (4) |
|
Pefloxacin |
400-800 mg (12) |
|||
|
Rifampicin |
10-20 mg / kg (12) |
10-20 mg / kg (12-24) g |
600 mg (24) |
|
|
Tobramycin b |
5 mg / kg (12) |
7.5 mg / kg (8) |
7 5 mg / kg (8) |
5 mg / kg (8) |
|
To trimoxazole e |
10-20 mg / kg (6-12) |
10-20 mg / kg (6-12) |
||
|
Cefepim |
150 mg / kg (8) |
6 g (8) |
||
|
Cefotaxime |
100-150 mg / kg (8-12) |
150-200 mg / kg (6-8) |
225-300 mg / kg (6-8) |
B-12 g (4-6) |
|
Ceftazidime |
100-150 mg / kg (8-12) |
150 mg / kg (8) |
150 mg / kg (8) |
6 g (B) |
|
Ceftriaxone |
80-100 mg / kg (12-24) |
4 g (12-24) |
||
|
Ciprofloxacin |
800-1200 mg (8-12) |
|||
- a - lower doses or longer intervals of administration can be used in newborns with low weight (<2000 g),
- b - it is necessary to monitor the peak and residual concentrations in the plasma,
- c - the maximum dose is recommended for patients with pneumococcal meningitis,
- g - there is no data on optimal dosages in patients with bacterial meningitis,
- d is the maximum daily dose of 600 mg,
- The e - dose is based on the amount of trimethoprim,
- g - maintain a residual concentration of 15-20 μg / ml
The duration of antibiotic treatment of meningitis
The optimal duration is unknown and, apparently, is related to the characteristics of the micro- and macroorganism. Usually, meningococcal meningitis treatment duration is 5-7 days, with meningitis caused by H. Influenzae, 7-10 days, with pneumococcal - 10 days. In patients without immune disorders and listeriosis etiology of meningitis - 14 days, with immunosuppression - 21 days, the same duration is recommended for meningitis caused by gram-negative flora. The general rule for a justified cessation of antibacterial therapy is the sanation of CSF, a decrease in cytosis below 100 cells per 1 μl and its lymphocytic character. These recommendations on the duration of antibiotic therapy are rational to use only in those cases when immediately after diagnosis of the infection an antibiotic, active against the subsequently isolated pathogen, was assigned, and there was a stable positive clinical dynamics of the disease. In the case of complications of cerebral edema and dislocation, ventriculitis, intracerebral hemorrhages and ischemic lesions that limit the effectiveness of antibiotic delivery to the focus of infectious inflammation, the duration of antibiotic therapy determines on the basis of a combination of clinical and laboratory data a consultation of specialists having sufficient experience for making a responsible decision.
Delayed prescription of antibacterial drugs
Special studies were not conducted for ethical reasons. However, when studying outcomes of treatment of patients with atypical clinical manifestations of bacterial meningitis, it was shown that the delay in diagnosis and treatment led to weight gain and increased mortality. The frequency of complications and the level of mortality were also related to age, the presence of immunological disorders and the level of impaired consciousness in the moment of diagnosis. Separately it is necessary to specify that the appointment in the mode of empirical therapy of drugs inactive against the pathogen of infection should be considered as one of the options for delaying the appointment of antibacterial drugs.
Use of original and generic antibacterial drugs for the treatment of bacterial meningitis. Meningitis is a life-threatening condition, and antibiotic therapy is considered the basis of effective treatment. All the above antibiotic therapy regimens have been studied using original drugs. The emergence of the possibility of using generic drugs can significantly reduce the costs associated with the use of antibiotics. The determination of the sensitivity of flora to the active substance of antibacterial drugs in vitro creates the illusion of equal effectiveness of all drugs that have it in its composition. However, studies on the comparative efficacy of the original and generic drugs have not been conducted. Therefore, preparations with non-proprietary trade names can be used only in the absence of original products for various reasons on the market.
List of trade (patented) and corresponding international non-proprietary names
| International Nonproprietary Name | Original trade name | Alternative for lack of an original drug on the market |
| Amikacin | Amikin | |
| Vancomycin | Vancocin | Edicine |
| Gentamicin | Domestic analogue | |
| Linezolid | Zivox | |
|
Meropenem |
Meronem |
|
|
Moxifloxacin |
Avelox |
|
|
Cefepim |
Maksipim |
|
|
Cefotaxime |
Claforan |
|
|
Ceftazidime |
Fortum |
|
|
Ceftriaxone |
Rocefine |
[Dexamethasone in the treatment of bacterial meningitis
The effectiveness of glucocorticoids has been proven in terms of reducing neurological complications (hearing loss) in children with meningitis caused by H. Influenzae, and a reduction in mortality in adults with meningitis caused by S. Pneumoniae. It is recommended to use dexamethasone in a dose of 0.15 mg / kg after 6 hours for 4 days. It should be remembered that dexamethasone reduces the increased penetration of antibiotics into the subarachnoid space as a result of inflammation.