Strategies to Reduce Mortality from Bacterial Sepsis in Adults in Developing Countries
article has not abstract
Published in the journal:
. PLoS Med 5(8): e175. doi:10.1371/journal.pmed.0050175
Category:
Neglected Diseases
doi:
https://doi.org/10.1371/journal.pmed.0050175
Summary
article has not abstract
Sepsis is a progressive injurious process resulting from a systemic inflammatory response to infection [1]. In developed countries, sepsis is an important cause of mortality: in the United States alone, up to 750,000 people annually suffer from severe sepsis—mostly bacterial in aetiology—of whom 29% may die [2,3]. Unfortunately, data on bacterial sepsis in developing countries are notably lacking, particularly in adults. Estimates of the burden of lower respiratory tract infections, meningitis, and “other infections”, of which a significant proportion are associated with severe sepsis, show that the majority of deaths and disability-adjusted life years lost occur in low-income countries (Figure 1) [4]. Additionally, severe sepsis is likely to complicate a varying proportion of cases of malaria, HIV/AIDS, diabetes, maternal conditions, and cancer deaths globally.
The standard of care varies significantly across lower- and middle-income developing countries, but published reports suggest that outcomes are poor even at major hospitals [5–10]. Melioidosis, a serious tropical infection caused by Burkholderia pseudomallei that often presents with sepsis, is endemic in a region containing both high- and low-income countries [11]. Outcomes vary significantly: the case fatality rate for melioidosis is higher in Thailand (40%–50%) than in Australia (10%–20%) [11–13], and the case-fatality rate for melioidosis with severe sepsis is approximately 50% in Singapore compared with 90% in a Thai clinical trial [14,15]. The burden of disease and case fatality of patients with melioidosis in less developed countries such as Cambodia and Myanmar are unknown. Although melioidosis is not common outside of southeast Asia, extrapolating this experience suggests that the outcomes from all-cause bacterial sepsis in underdeveloped regions are likely to be poor.
The recently updated “Surviving Sepsis Campaign” guidelines have been widely disseminated in the developed world as a model of optimal sepsis management [16]. Although there has been some controversy regarding the recommendations and the development of the guidelines [17–19], most interventions based on improving early management of septic patients are less controversial. Crucially, most of the studies on which these recommendations are based were undertaken in the developed world and may not be applicable to the majority of the world's population who live in poorer regions. The purpose of this paper is to highlight the paucity of epidemiological or management data on bacterial sepsis in the developing world, discuss current management approaches to sepsis in adults, and examine how clinical sepsis management guidelines could be best adapted to provide improved care at low cost in under-resourced regions. We use the term “developing country” to refer to lower- or middle-income countries as defined by the World Bank [20].
Summary Points
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The burden of sepsis is understudied but likely to be high in developing countries.
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Most previous studies have been disease-specific rather than syndrome-focused.
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The recently updated “Surviving Sepsis” guidelines have defined the standard of care for patients with severe sepsis in the developed world but do not incorporate the realities of health care in resource-constrained settings.
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A focus on early management of severe sepsis, including fluid management, blood pressure control, timely administration of antibiotics, and source control, is likely to be the most cost-effective intervention for critically ill, septic patients in resource-constrained settings. The efficacy of particular strategies of care needs to be evaluated in clinical studies.
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An integrated programme of management for adults, which includes training for health care workers on the prevention, recognition, and management of severe sepsis, is required.
Identification of Sepsis
Interventions performed soon after diagnosis of sepsis in developed regions have been shown to improve survival [21,22], and in developing countries, interventions to identify and treat pneumonia in children reduce mortality [23]. Thus, prompt identification of sepsis in developing countries is an essential component of any management strategy. Most studies of infection have focused on specific diseases, but sepsis itself is a clinically recognisable syndrome despite its heterogeneous causes. From a practical standpoint, sepsis is largely a clinical diagnosis [24], and implementation of strategies to promote recognition of sepsis as a clinical syndrome should be feasible even in the most resource-challenged areas where supportive radiographic imaging or laboratory measurements are not available. Education of health care providers about sepsis is critical to enhance the early identification of sick patients and may help facilitate transfer to available health care facilities. Simple algorithms tailored to local medical capacities that comprise the basic components of sepsis, such as diagnosed or suspected infection and the systemic manifestations of infection, may be useful.
Initial Treatment of Sepsis
Volume resuscitation is a well-established initial therapy of sepsis. Many studies have demonstrated that tissue perfusion in sepsis is partly impaired by hypovolaemia [25,26], and patients may have substantial fluid deficits requiring 6–10 l within the first 24 hours [21,27]. Guidelines suggest that hypotensive patients should receive an initial challenge of 20 ml/kg or boluses of 500–1000 ml of crystalloid with ongoing monitoring of volume status [16,28,29]. Observational evidence suggests that aggressive fluid resuscitation was associated with decreased early mortality from typhoid with ileal perforation in a rural African hospital [30].
Although albumin is at least as effective as crystalloids for volume resuscitation in sepsis, the latter is cheaper and more widely available [31]. Judicious enteral fluid loading with standard oral rehydration solution has been used in other forms of hypovolaemia, but is as yet untested as a strategy in sepsis [32,33]. In severely compromised patients, oral fluids may be associated with a risk of pulmonary aspiration and are less likely to be effective with severe intravascular hypovolaemia. Invasively measured endpoints of fluid resuscitation have been defined [28], but clinical endpoints such as blood pressure and heart rate measurements, skin colour and capillary refill, mental status, or urinary output are the most feasible measures for monitoring in underdeveloped regions. Central venous access, where available, may be helpful for monitoring of central venous pressure and administration of vasopressors. Simpler non-invasive devices such as tissue perfusion monitors may be more practical but are not yet used widely [33].
Because septic shock is often characterised by inappropriate peripheral vasodilation, initiation of vasopressor therapies is indicated for persistent hypotension following fluid loading [16,34]. Although norepinephrine and (suprarenal dose) dopamine are accepted first-line agents [16,28], both may be associated with extravasation-related tissue necrosis if infused into a peripheral vein when central venous access is not possible. Accurate titration of intravenous vasopressors is also problematic in the absence of infusion pumps. Finally, non-invasive monitoring of blood pressure may be less accurate than intra-arterial blood pressure monitoring [16]. We have identified very few studies of non-intravenous vasopressor agents, such as oral midodrine [35], yet conceivably such therapies may play a role in sepsis management when intravenous medications are not feasible.
Haemodynamic optimisation measures in the resuscitation of ill septic patients often require extensive nursing and medical resources. An invasive goal-directed haemodynamic optimisation therapy approach to early sepsis management, while effective, has proven challenging to implement even in large hospitals in the United States, and is not practical to consider in this form for health care facilities in most developing settings [21,36]. Nonetheless, in regions where basic sepsis therapies exist yet early management is suboptimal, enhanced care could be achieved with simple, clearly defined fluid resuscitation and blood pressure management protocols, incorporating clinical endpoints and non-invasive tools if available. In areas where paramedical staff are available, simply engaging an assistant to observe patient status may be a cost-effective substitute for electronic monitoring. In better staffed facilities, designation of a dedicated nurse for at least the initial resuscitation period may be beneficial. However, more studies are required to determine optimal fluid resuscitation strategies where invasive haemodynamic monitoring and fall-back therapies (such as mechanical ventilation and dialysis) may not be available.
Antibiotic Regimens
The timely and appropriate use of antibiotics in the early management period is associated with survival from sepsis and pneumonia [22,37]. A potential barrier to the formulation of an effective empiric antimicrobial regimen is that the spectrum of bacterial pathogens in the tropics is often diverse. In one study in Kenyan children, 16 individual pathogens, each of which accounted for less than 10% of cases, accounted for over a third of bacteraemias [38]. Similarly, in a study of adults in Nepal, no single pathogen accounted for more than 13% of patients where a pathogen was identified [39].
Many regions do not have access to diagnostic microbiology laboratories, so the causes of sepsis and their susceptibility profiles may not be known. The list of common bacterial pathogens may also show significant variation, even between neighbouring countries. An example of this is between the adjacent countries of Thailand and Laos. In northeast Thailand, common causes of community-acquired sepsis include Staphylococcus aureus, pneumococci and other streptococci, Escherichia coli and other Enterobacteriaceae, Pseudomonas spp., and B. pseudomallei [40], as well as leptospirosis, scrub typhus, and dengue [41]. In adjacent Vientiane, Laos, the commonest cause of community-acquired bacteraemia in one study was Salmonella enterica serovar typhi (50.9%), followed by S. aureus and E. coli [42]. Causes of hospital-acquired sepsis are also poorly characterised in resource-constrained settings where culture facilities are limited or absent, but lack of infection control infrastructure is likely to be associated with a significant burden of nosocomial sepsis. Because improved outcomes in sepsis management depend on early and appropriate antibiotic administration, it is critical that these issues be addressed in future epidemiological studies.
The role of the clinical microbiology laboratory in developing countries has been discussed extensively elsewhere, and issues relating to problems with clinical misdiagnosis, poor use of existing resources, and quality assurance are well documented [43,44]. Possible solutions include the development of low-cost laboratories, or the intermittent use of mobile diagnostic “clinics” that can define the range of pathogens and their susceptibility patterns in a given area to inform a rational empiric prescribing policy. These data should be widely disseminated to clinicians within the region. Evidence for the impact on mortality of accurate diagnosis can be seen from mortality rates from melioidosis in northeast Thailand over time. The burden of melioidosis became apparent after diagnostic laboratories were introduced into this area in the early 1970s [45]. This led to the first clinical treatment trial that reported a reduction in mortality from 74% to 37% for patients with acute melioidosis treated with ceftazidime compared with the previous combination antibiotic therapy [46]. Similarly, recent clinical trials have been prompted by the recognition of emerging resistance in Salmonella typhi [47].
There are a number of concerns with respect to antibiotic therapy in developing regions. In many developing countries, antibiotics are not regulated and are freely available, particularly in urban areas. It is becoming widely appreciated that a significant proportion of patients in rural Asia will have taken antibiotics prior to presentation to hospital [48,49]. This has major implications both for antibiotic resistance and the sensitivity of diagnostic culture when the patient presents to hospital. The quality of antibiotics is a further consideration. Fake drugs are widespread in the tropics [50] and have been implicated in deaths from malaria. Furthermore, many antibiotics are stored at room temperature, but ambient temperatures may reach 40° C in the tropics.
Five Key Papers in the Field
Dellinger et al., 2008 [16] These international guidelines detail the current standard of care for patients with severe sepsis in developed countries.
Cheng et al., 2007 [15] This trial demonstrated poor outcomes from septic shock due to suspected melioidosis despite hospital care in Thailand, with in-hospital mortality exceeding 80%. Granulocyte colony stimulating factor, as an adjuvant to antibiotics, was not associated with a mortality benefit.
Phu et al., 2002 [63] This trial in Vietnam demonstrated that haemodialysis was more effective than peritoneal dialysis in patients with infection-related acute renal failure predominantly due to malaria. Despite the increased cost, the mortality benefit was large, suggesting that haemodialysis was more cost-effective.
Rivers et al., 2001 [21] This single-centre randomised controlled trial demonstrated a 16% absolute decrease in in-hospital mortality associated with early goal-directed management compared with standard management.
Gove S, 1997 [73] This paper describes the development and evaluation of the integrated management of childhood illness guidelines and training course for health workers in developing countries.
Supportive and Adjunctive Therapeutic Agents
Prophylaxis for deep venous thrombosis and for peptic “stress” ulcers can be readily implemented in many developing countries. Histamine blockers such as ranitidine are inexpensive and can be administered via nasogastric tube to intubated patients. Although some have argued that the incidence of venous thromboembolism is lower in populations of non-European origin [51–53], more recent evidence suggests that this may not be the case in post-operative and medical patients [54,55]. In the absence of studies in critically unwell patients with prolonged immobilisation, the use of subcutaneous unfractionated heparin seems warranted.
Other interventions often used in the developed setting for patients with severe sepsis are renal replacement therapy and mechanical ventilation. Respiratory failure is a frequent complication of severe sepsis, and progression to acute lung injury is most commonly caused by sepsis [56,57]. In a trial of granulocyte colony stimulating factor in severe sepsis due to melioidosis in Thailand [15], 70% of patients required intubation and ventilation. Where available, mechanical ventilation of septic patients in developing countries is associated with extremely high mortality rates [6], and in some countries, patients with respiratory failure are ventilated by hand by relatives (A. C. Cheng, personal experience). Many ventilators in developing countries are simple devices that do not have minute ventilation alarms or allow for adjunct ventilator functions such as positive end-expiratory pressure. Sub-optimal ventilator care may lead to ventilator-associated pneumonia [58,59], and the lack of low-volume “lung-protective” strategies may be associated with poor outcomes from acute lung injury [60]. The reliance on non-invasive monitoring using peripheral oxygen saturation may reduce the ability to monitor the adequacy of ventilation. Although non-invasive positive-pressure ventilation is mainly used for respiratory failure in non-septic patients, it has been used successfully in developing countries [61,62], and strategies incorporating non-invasive positive-pressure ventilation should be evaluated further where invasive mechanical ventilation cannot be managed adequately.
The cost of equipment and trained staff largely prohibits the use of renal replacement therapies in low-income settings, although they are used to a variable extent in rural regions of middle-income countries. In Vietnam, haemofiltration was more cost-effective than peritoneal dialysis in infection-related renal failure despite its significant cost [63]. This study primarily included patients with malaria, but such a study would be of significant interest in patients with sepsis in resource-constrained settings where haemofiltration is possible. In a study of severe sepsis in melioidosis, acute renal failure and acidosis were prominent on admission, suggesting that aggressive fluid resuscitation and/or renal replacement therapy would be potentially beneficial in this group [15]. There has been increasing awareness of the importance of acidosis and fluid and electrolyte imbalances in severe malaria, and despite differences in pathophysiology, such research may be relevant to severe bacterial sepsis [64,65].
There have been few trials of adjuvant therapies in developing countries, and results of studies may not be generalisable to this setting. For example, granulocyte colony stimulating factor appeared to be associated with significant benefit in treating melioidosis in Australia [13], but was not associated with a significant mortality benefit in Thailand in a clinical trial [15]. Conversely, high-dose steroids are not thought to be useful in severe sepsis generally, but may possibly have a specific application in severe typhoid [66–68]. Interventions that are of marginal benefit in developed countries, such as physiological dose steroid replacement [19,69] or intensive insulin therapy, are unlikely to be effective in developing countries in the absence of other standard intensive care interventions. The risk of adverse events, such as hypoglycaemia, associated with intensive insulin regimens are likely be greater in resource-poor settings, and the setting of less strict blood glucose targets may be warranted [16,18,70]. However, the safety and efficacy of such strategies require study. The effectiveness of activated protein C (drotrecogin alfa) has also been subject to intensive debate, but the cost of this therapy is prohibitive for most health care systems in developing countries [71,72].
Training
Implicit in this discussion is the need for appropriately trained health care providers at the local level. Ideally, sepsis identification and management training should be integrated into general adult health care. Such a strategy is analogous to the World Health Organization's Integrated Management of Childhood Illness training course, which included severe infection, chronic diseases, and preventative measures for all levels of health workers including doctors, nurses, medical assistants, and literate paramedical workers at both a primary, and more recently, hospital level [73,74]. This course was integrated into a comprehensive strategy that also included measures to improve drug supply, health care infrastructure, and family behaviour in relation to sick children.
Cost-Effectiveness
The development of critical care services has significant resource implications for developing countries. We propose a stepwise approach based on income level, from extremely limited services in Africa and parts of southeast Asia, to more extended services in lower-middle-income countries such as Thailand and some South American countries (Table 1). Some evidence suggests that critical care services may be cost-effective even in poor countries, but such a decision needs to be made on a case-by-case basis [75]. We feel that with the current paucity of evidence regarding the effectiveness of potential interventions for severe sepsis, such decisions cannot currently be made. We further note that factors other than cost-effectiveness must be considered in priority setting in health care resource allocation, including equity, ethical, and political considerations [76]. However, where such services already exist, the challenge is to integrate these into the broader health care system to ensure access and to provide a cost-effective and sustainable staffing model [77]. Further research is required to define the most effective interventions for sepsis in developing countries, as well as evaluation and quality control programmes for existing services.
Prevention
Few vaccines are available against most of the common causes of severe sepsis in the tropics, and many vaccines with known substantial efficacy against common diseases such as typhoid and pneumococcal disease are not generally available to developing countries because of cost. Other preventative measures may be useful for specific diseases. In a case-control study in northeast Thailand, the use of protective clothing reduced the incidence of leptospirosis [78], and protective footwear may also help prevent melioidosis, scrub typhus, snake bite, and physical injury. Although anecdotal reports suggested that farmers found protective footwear uncomfortable, particularly during the ploughing and planting seasons (V. Wuthiekanun, personal communication), it is possible that this obstacle could be overcome through a combination of education and the development of comfortable and practical clothing. Predictive modelling has proven to be a useful tool in malaria control [79], and similar techniques have been developed for a variety of other diseases such as cholera [80] and arboviruses [81]. Such tools might allow for targeting of public health interventions that may reduce exposure or disease transmission in specific populations.
Conclusion
The burden of sepsis is greatest in developing countries, and there is a need to translate modern management strategies for adults with severe sepsis to this context. The majority of studies of infectious diseases to date have been pathogen-specific, but efforts are required to define the epidemiology of all-cause sepsis in developing countries and to define the most cost-effective interventions that are sustainable in these countries. Principles of management may be adapted from current guidelines, particularly low-cost interventions targeted at early sepsis. Critical care services need to be considered in the context of competing priorities for resource allocation, but where they currently exist, standardised protocols need to be developed and evaluated to make the best use of available resources.
Access to diagnostic facilities is fundamental to the care of the individual and to the development of logical and effective empiric prescribing regimens. Low-income countries rarely have access to diagnostic laboratories, and this is a major impediment to the improvement of care. Primary prevention is theoretically possible for a range of serious tropical infections, and studies are required to define acceptable measures and to validate their effectiveness.
Zdroje
1. [No authors listed]
1992
American College of Chest Physicians/Society of Critical Care Medicine Consensus Conference: Definitions for sepsis and organ failure and guidelines for the use of innovative therapies in sepsis.
Crit Care Med
20
864
874
2. AngusDCLinde-ZwirbleWTLidickerJClermontGCarcilloJ
2001
Epidemiology of severe sepsis in the United States: Analysis of incidence, outcome, and associated costs of care.
Crit Care Med
29
1303
1310
3. MartinGSManninoDMEatonSMossM
2003
The epidemiology of sepsis in the United States from 1979 through 2000.
N Engl J Med
348
1546
1554
4. World Health Organization
2008
Revised global burden of disease 2002 estimates.
Available: http://www.who.int/healthinfo/bodgbd2002revised/en/index.html. Accessed 18 July 2008
5. SiddiquiS
2007
Not “surviving sepsis” in the developing countries.
J Indian Med Assoc
105
221
6. TanrioverMDGuvenGSSenDUnalSUzunO
2006
Epidemiology and outcome of sepsis in a tertiary-care hospital in a developing country.
Epidemiol Infect
134
315
322
7. FrikhaNMebazaaMMnifLEl EuchNAbassiM
2005
[Septic shock in a Tunisian intensive care unit: Mortality and predictive factors. 100 cases].
Tunis Med
83
320
325
8. SmithCArreguiLMPromnitzDAFeldmanC
1991
Septic shock in the Intensive Care Unit, Hillbrow Hospital, Johannesburg.
S Afr Med J
80
181
184
9. DegoricijaVSharmaMLegacAGradiserMSeferS
2006
Survival analysis of 314 episodes of sepsis in medical intensive care unit in university hospital: Impact of intensive care unit performance and antimicrobial therapy.
Croat Med J
47
385
397
10. SilvaEPedro MdeASogayarACMohovicTSilvaCL
2004
Brazilian Sepsis Epidemiological Study (BASES study).
Crit Care
8
R251
R260
11. WhiteNJ
2003
Melioidosis.
Lancet
361
1715
1722
12. CurrieBJFisherDAHowardDMBurrowJNLoD
2000
Endemic melioidosis in tropical northern Australia: A 10-year prospective study and review of the literature.
Clin Infect Dis
31
981
986
13. ChengACStephensDPAnsteyNMCurrieBJ
2004
Adjunctive granulocyte colony-stimulating factor for treatment of septic shock due to melioidosis.
Clin Infect Dis
38
32
37
14. ChanKPLowJGRaghuramJFook-ChongSMKurupA
2005
Clinical characteristics and outcome of severe melioidosis requiring intensive care.
Chest
128
3674
3678
15. ChengACLimmathurotsakulDChierakulWGetchalaratNWuthiekanunV
2007
A randomized controlled trial of granulocyte colony-stimulating factor for the treatment of severe sepsis due to melioidosis in Thailand.
Clin Infect Dis
45
308
314
16. DellingerRPLevyMMCarletJMBionJParkerMM
2008
Surviving Sepsis Campaign: International guidelines for management of severe sepsis and septic shock: 2008.
Crit Care Med
36
296
327
17. EichackerPQNatansonCDannerRL
2006
Surviving sepsis—Practice guidelines, marketing campaigns, and Eli Lilly.
N Engl J Med
355
1640
1642
18. BrunkhorstFMEngelCBloosFMeier-HellmannARagallerM
2008
Intensive insulin therapy and pentastarch resuscitation in severe sepsis.
N Engl J Med
358
125
139
19. SprungCLAnnaneDKehDMorenoRSingerM
2008
Hydrocortisone therapy for patients with septic shock.
N Engl J Med
358
111
124
20. World Bank
2008
Country classification.
Available: go.worldbank.org/K2CKM78CC0. Accessed 18 July 2008
21. RiversENguyenBHavstadSResslerJMuzzinA
2001
Early goal-directed therapy in the treatment of severe sepsis and septic shock.
N Engl J Med
345
1368
1377
22. KumarARobertsDWoodKELightBParrilloJE
2006
Duration of hypotension before initiation of effective antimicrobial therapy is the critical determinant of survival in human septic shock.
Crit Care Med
34
1589
1596
23. SazawalSBlackRE
2003
Effect of pneumonia case management on mortality in neonates, infants, and preschool children: A meta-analysis of community-based trials.
Lancet Infect Dis
3
547
556
24. LevyMMFinkMPMarshallJCAbrahamEAngusD
2003
2001 SCCM/ESICM/ACCP/ATS/SIS International Sepsis Definitions Conference.
Intensive Care Med
29
530
538
25. CarrollGCSnyderJV
1982
Hyperdynamic severe intravascular sepsis depends on fluid administration in cynomolgus monkey.
Am J Physiol
243
R131
R141
26. WinslowEJLoebHSRahimtoolaSHKamathSGunnarRM
1973
Hemodynamic studies and results of therapy in 50 patients with bacteremic shock.
Am J Med
54
421
432
27. RackowECFalkJLFeinIASiegelJSPackmanMI
1983
Fluid resuscitation in circulatory shock: A comparison of the cardiorespiratory effects of albumin, hetastarch, and saline solutions in patients with hypovolemic and septic shock.
Crit Care Med
11
839
850
28. HollenbergSMAhrensTSAnnaneDAstizMEChalfinDB
2004
Practice parameters for hemodynamic support of sepsis in adult patients: 2004 update.
Crit Care Med
32
1928
1948
29. HurtadoFJNinN
2006
The role of bundles in sepsis care.
Crit Care Clin
22
521
529
x
30. MockCVisserLDennoDMaierR
1995
Aggressive fluid resuscitation and broad spectrum antibiotics decrease mortality from typhoid ileal perforation.
Trop Doct
25
115
117
31. FinferSBellomoRBoyceNFrenchJMyburghJ
2004
A comparison of albumin and saline for fluid resuscitation in the intensive care unit.
N Engl J Med
350
2247
2256
32. MichellMWOliveiraHMKinskyMPVaidSUHerndonDN
2006
Enteral resuscitation of burn shock using World Health Organization oral rehydration solution: A potential solution for mass casualty care.
J Burn Care Res
27
819
825
33. NagerALWangVJ
2002
Comparison of nasogastric and intravenous methods of rehydration in pediatric patients with acute dehydration.
Pediatrics
109
566
572
34. ParrilloJEParkerMMNatansonCSuffrediniAFDannerRL
1990
Septic shock in humans. Advances in the understanding of pathogenesis, cardiovascular dysfunction, and therapy.
Ann Intern Med
113
227
242
35. WeipplG
1979
[Infectious toxic hypotension—Effect and dosage of midodrine (author's transl)].
Padiatr Padol
14
211
216
36. CarlbomDJRubenfeldGD
2007
Barriers to implementing protocol-based sepsis resuscitation in the emergency department—Results of a national survey.
Crit Care Med
35
2525
2532
37. HarbarthSGarbinoJPuginJRomandJALewD
2003
Inappropriate initial antimicrobial therapy and its effect on survival in a clinical trial of immunomodulating therapy for severe sepsis.
Am J Med
115
529
535
38. BerkleyJALoweBSMwangiIWilliamsTBauniE
2005
Bacteremia among children admitted to a rural hospital in Kenya.
N Engl J Med
352
39
47
39. MurdochDRWoodsCWZimmermanMDDullPMBelbaseRH
2004
The etiology of febrile illness in adults presenting to Patan hospital in Kathmandu, Nepal.
Am J Trop Med Hyg
70
670
675
40. ChaowagulWWhiteNJDanceDAWattanagoonYNaigowitP
1989
Melioidosis: A major cause of community-acquired septicemia in northeastern Thailand.
J Infect Dis
159
890
899
41. SuttinontCLosuwanalukKNiwatayakulKHoontrakulSIntaranongpaiW
2006
Causes of acute, undifferentiated, febrile illness in rural Thailand: Results of a prospective observational study.
Ann Trop Med Parasitol
100
363
370
42. PhetsouvanhRPhongmanySSoukalounDRasachakBSoukhaseumV
2006
Causes of community-acquired bacteremia and patterns of antimicrobial resistance in Vientiane, Laos.
Am J Trop Med Hyg
75
978
985
43. ArchibaldLKRellerLB
2001
Clinical microbiology in developing countries.
Emerg Infect Dis
7
302
305
44. PettiCAPolageCRQuinnTCRonaldARSandeMA
2006
Laboratory medicine in Africa: A barrier to effective health care.
Clin Infect Dis
42
377
382
45. PunyaguptaS
1989
Melioidosis. Review of 686 cases and presentation of a new clinical classification.
In
PunyaguptaSSirisanthanaTStapatayavongB
editors
Melioidosis
Bangkok
Bangkok Medical Publisher
217
229
46. WhiteNJDanceDAChaowagulWWattanagoonYWuthiekanunV
1989
Halving of mortality of severe melioidosis by ceftazidime.
Lancet
2
697
701
47. ParryCMHoVAPhuong leTBayPVLanhMN
2007
Randomized controlled comparison of ofloxacin, azithromycin, and an ofloxacin-azithromycin combination for treatment of multidrug-resistant and nalidixic acid-resistant typhoid fever.
Antimicrob Agents Chemother
51
819
825
48. KamolratanakulPDhanamunBThaithongS
1992
Human behavior in relation to selection of malaria treatment.
Southeast Asian J Trop Med Public Health
23
189
194
49. ThamlikitkulV
1988
Antibiotic dispensing by drug store personnel in Bangkok, Thailand.
J Antimicrob Chemother
21
125
131
50. WertheimerAIChaneyNMSantellaT
2003
Counterfeit pharmaceuticals: Current status and future projections.
J Am Pharm Assoc
43
710
717
51. De StefanoVChiusoloPPaciaroniKLeoneG
1998
Epidemiology of factor V Leiden: Clinical implications.
Semin Thromb Hemost
24
367
379
52. NandiPWongKPWeiWINganHOngGB
1980
Incidence of postoperative deep vein thrombosis in Hong Kong Chinese.
Br J Surg
67
251
253
53. LeeHMSukKSMoonSHKimDJWangJM
2000
Deep vein thrombosis after major spinal surgery: Incidence in an East Asian population.
Spine
25
1827
1830
54. ChotanaphutiTOngnamthipPSilpipatSFoojareonyosTRoschanS
2007
The prevalence of thrombophilia and venous thromboembolism in total knee arthroplasty.
J Med Assoc Thai
90
1342
1347
55. MannucciPM
2007
Thrombosis and bleeding disorders outside Western countries.
J Thromb Haemost
5
Suppl 1
68
72
56. PepePEPotkinRTReusDHHudsonLDCarricoCJ
1982
Clinical predictors of the adult respiratory distress syndrome.
Am J Surg
144
124
130
57. HudsonLDMilbergJAAnardiDMaunderRJ
1995
Clinical risks for development of the acute respiratory distress syndrome.
Am J Respir Crit Care Med
151
293
301
58. LeongJRHuangDT
2006
Ventilator-associated pneumonia.
Surg Clin North Am
86
1409
1429
59. JaimesFDe La RosaGGomezEMuneraPRamirezJ
2007
Incidence and risk factors for ventilator-associated pneumonia in a developing country: Where is the difference.
Respir Med
101
762
767
60. [No authors listed]
2000
Ventilation with lower tidal volumes as compared with traditional tidal volumes for acute lung injury and the acute respiratory distress syndrome. The Acute Respiratory Distress Syndrome Network.
N Engl J Med
342
1301
1308
61. HussainSFHaqqeeRIqbalJ
2004
Non-invasive ventilation in the management of acute respiratory failure in Pakistan.
Trop Doct
34
238
239
62. GeorgeIAJohnGJohnPPeterJVChristopherS
2007
An evaluation of the role of noninvasive positive pressure ventilation in the management of acute respiratory failure in a developing country.
Indian J Med Sci
61
495
504
63. PhuNHHienTTMaiNTChauTTChuongLV
2002
Hemofiltration and peritoneal dialysis in infection-associated acute renal failure in Vietnam.
N Engl J Med
347
895
902
64. MaitlandKAkechSGwerSIdroRFeganG
2007
Phase III trials required to resolve clinical equipoise over optimal fluid management in children with severe malaria.
PLoS Clin Trials
2
e2
doi:10.1371/journal.pctr.0020002
65. IdroRAketchSGwerSNewtonCRMaitlandK
2006
Research priorities in the management of severe Plasmodium falciparum malaria in children.
Ann Trop Med Parasitol
100
95
108
66. PunjabiNHHoffmanSLEdmanDCSukriNLaughlinLW
1988
Treatment of severe typhoid fever in children with high dose dexamethasone.
Pediatr Infect Dis J
7
598
600
67. RogersonSJSpoonerVJSmithTARichensJ
1991
Hydrocortisone in chloramphenicol-treated severe typhoid fever in Papua New Guinea.
Trans R Soc Trop Med Hyg
85
113
116
68. HoffmanSLPunjabiNHKumalaSMoechtarMAPulungsihSP
1984
Reduction of mortality in chloramphenicol-treated severe typhoid fever by high-dose dexamethasone.
N Engl J Med
310
82
88
69. AnnaneDSebilleVCharpentierCBollaertPEFrancoisB
2002
Effect of treatment with low doses of hydrocortisone and fludrocortisone on mortality in patients with septic shock.
JAMA
288
862
871
70. PreiserJ
2007
Intensive glycemic control in med-surg patients (European Glucontrol trial).
Society of Critical Care Medicine 36th Critical Care Congress; 17–21 February 2007; Orlando, Florida, United States
71. BernardGRVincentJLLaterrePFLaRosaSPDhainautJF
2001
Efficacy and safety of recombinant human activated protein C for severe sepsis.
N Engl J Med
344
699
709
72. AbrahamELaterrePFGargRLevyHTalwarD
2005
Drotrecogin alfa (activated) for adults with severe sepsis and a low risk of death.
N Engl J Med
353
1332
1341
73. GoveS
1997
Integrated management of childhood illness by outpatient health workers: Technical basis and overview. The WHO Working Group on Guidelines for Integrated Management of the Sick Child.
Bull World Health Organ
75
Suppl 1
7
24
74. DukeTKellyJWeberMEnglishMCampbellH
2006
Hospital care for children in developing countries: Clinical guidelines and the need for evidence.
J Trop Peds
52
1
2
75. TopleyJMNkrumahFK
1987
Paediatric intensive care in Harare.
Ann Trop Paediatr
7
282
286
76. MusgroveP
1999
Public spending on health care: How are different criteria related.
Health Policy
47
207
223
77. BhagwanjeeS
2006
Critical care in Africa.
Crit Care Clin
22
433
438
viii
78. PhraisuwanPWhitneyEATharmaphornpilasPGuharatSThongkamsamutS
2002
Leptospirosis: Skin wounds and control strategies, Thailand, 1999.
Emerg Infect Dis
8
1455
1459
79. SnowRWGouwsEOmumboJRapuodaBCraigMH
1998
Models to predict the intensity of Plasmodium falciparum transmission: Applications to the burden of disease in Kenya.
Trans R Soc Trop Med Hyg
92
601
606
80. MatsudaFIshimuraSWagatsumaYHigashiTHayashiT
2008
Prediction of epidemic cholera due to Vibrio cholerae O1 in children younger than 10 years using climate data in Bangladesh.
Epidemiol Infect
136
73
79
81. AliMWagatsumaYEmchMBreimanRF
2003
Use of a geographic information system for defining spatial risk for dengue transmission in Bangladesh: Role for Aedes albopictus in an urban outbreak.
Am J Trop Med Hyg
69
634
640
Štítky
Interní lékařstvíČlánek vyšel v časopise
PLOS Medicine
2008 Číslo 8
- Není statin jako statin aneb praktický přehled rozdílů jednotlivých molekul
- Moje zkušenosti s Magnosolvem podávaným pacientům jako profylaxe migrény a u pacientů s diagnostikovanou spazmofilní tetanií i při normomagnezémii - MUDr. Dana Pecharová, neurolog
- Nedostatek hořčíku se projevuje u stále více lidí
- Magnosolv a jeho využití v neurologii
- Metamizol v terapii bolesti v ambulanci praktického lékaře i pediatra
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