Quantitation of Bacteria in Blood of Typhoid Fever Patients and Relationship between Counts and Clinical Features, Transmissibility, and Antibiotic Resistance

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Journal of Clinical Microbiology, June 1998, p. 1683-1687, Vol. 36, No. 6
0095-1137/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Quantitation of Bacteria in Blood of Typhoid Fever Patients and Relationship between Counts and Clinical Features, Transmissibility, and Antibiotic Resistance

John Wain,¹^,²^,³ To Song Diep,² Vo Anh Ho,⁴ Amanda M. Walsh,¹^,³ Nguyen Thi Tuyet Hoa,² Christopher M. Parry,¹^,²^,³ and Nicholas J. White¹^,³^,^*

Wellcome Trust Clinical Research Unit¹ and Department of Microbiology,² Centre for Tropical Diseases, Cho Quan Hospital, Ho Chi Minh City, and Dong Thap Hospital, Cao Lanh, Dong Thap,⁴ Vietnam, and Centre for Tropical Medicine, Nuffield Department of Clinical Medicine, Oxford University, Oxford, United Kingdom³

Received 30 December 1997/Returned for modification 8 February 1998/Accepted 3 March 1998

	ABSTRACT

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Salmonella typhi was isolated from 369 and Salmonella paratyphi A was isolated from 6 of 515 Vietnamese patients with suspectedenteric fever. Compared with conventional broth culture of blood,direct plating of the buffy coat had a diagnostic sensitivityof 99.5% (95% confidence interval [CI], 97.1 to 100%). Blood bacterialcounts were estimated by the pour plate method. The median S.typhi count in blood was 1 CFU/ml (range, <0.3 to 387 CFU/ml),of which a mean of 63% (95% CI, 58 to 67%) were intracellular.The mean number of bacteria per infected leukocyte was 1.3 (interquartilerange [IQR], 0.7 to 2.4) CFU/cell (n = 81). Children (<15 yearsold; n = 115) had higher median blood bacterial counts than adults(n = 262): 1.5 (range, <0.3 to 387) versus 0.6 (range, <0.3 to17.7) CFU/ml (P = 0.008), and patients who excreted S. typhi infeces had higher bacteremias than those who did not: a medianof 3 (range, <0.3 to 32) versus 1 (range, <0.3 to 68) CFU/ml (P= 0.02). Blood bacterial counts declined with increasing durationof illness (P = 0.002) and were higher in infections caused bymultidrug-resistant S. typhi (1.3 [range, <0.3 to 387] CFU/ml;n = 313) than in infections caused by antibiotic-sensitive S.typhi (0.5 [range, <0.3 to 32] CFU/ml; n = 62) (P = 0.006). Ina multivariate analysis this proved to be an independent association,suggesting a relationship between antibiotic resistance and virulencein S. typhi.

	INTRODUCTION

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Typhoid fever is a prolonged illness characterized by bacteremia with Salmonella typhi, a highly evolved gram-negative bacterialparasite that infects only humans. Despite the bacteriologicalsimilarities between S. typhi and other enterobacteriaceae, theclinical picture of typhoid is usually distinctive and differsin many respects from that of other septicemias caused by gram-negativeorganisms. In general, typhoid patients are less severely ill,and severity in typhoid usually reflects localization of the infectionto the Peyer's patches, and consequent intestinal ulceration,rather than fulminant septicemia. There is little informationon the numbers of bacteria in the blood and their relationshipwith disease state (17). With standard broth culture, salmonellaehave been found in the blood of 30 to 90% of patients with clinicallysuspected cases of enteric fever, and the proportion of typhoidfever patients with positive blood cultures decreases with increasingduration of illness (3, 5, 20, 21). The volume of bloodtaken and the laboratory methods used for isolation are also importantfactors determining the yields from blood culture (3-6, 10,13, 17, 18, 20, 24). S. typhi is able to survive andreproduce inside monocytic phagocytes, and in typhoid fever S.typhi is reported to be confined to the monocyte-platelet fractionof the blood (5, 17, 18, 24). In order to investigatethe relationship between bacterial counts in blood and clinicaland laboratory features of typhoid, we have performed quantitativebacteriological cultures for a large series of patients with uncomplicatedenteric fever.

	MATERIALS AND METHODS

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Patients. Adults and children admitted with suspected uncomplicated typhoid fever were studied over a 3-year period at two separatesites in Vietnam: the Centre for Tropical Diseases, Ho Chi MinhCity, an infectious disease referral hospital, and the FriendshipHospital, Cao Lanh City, a large provincial hospital in Dong ThapProvince in the Mekong Delta. These patients were recruited forprospective treatment studies of short-course fluoroquinolonetherapy on the basis of either clinical suspicion or a positiveblood culture. The criteria for the clinical diagnosis of typhoidfever were usually fever for $>=$ 6 days with no obvious focus ofinfection, a negative malaria blood smear, and abdominal discomfortwith change of bowel habits. In some cases the patients' withdrawnor apathetic behavior in the presence of fever was also a diagnosticpointer. Patients with severe or complicated typhoid (except thosewith a history of melena only) and those who had already receivedeffective antibiotic treatment (i.e., antibiotics active againstS. typhi) were not included in these studies. Before treatmentwas started, blood was taken for routine laboratory tests andcultures as described below, and when it was possible withoutdelaying the start of treatment, a stool sample was cultured forSalmonella. Fully informed consent to blood sampling was obtainedfrom all patients. This study was approved by the Scientific andEthical Committees of the participating institutions.

Laboratory methods. The same laboratory methods were used at both centers. Five to ten milliliters of venous blood was drawn aseptically fromeach patient and inoculated into 50 ml of brain heart infusionbroth (Oxoid, Basingstoke, United Kingdom) containing 0.05% sodiumpolyanetholesulfonate (Sigma, Poole, United Kingdom). A minimumblood-to-broth ratio of 1 to 10 was maintained. Blood culturebroths were incubated for 7 days, and subcultures were performedat 24 h and after 7 days. All bottles were also examined daily,and if a bottle showed visible signs of growth, subculture ontosheep blood agar was performed. Stool cultures were performedafter enrichment of a 1-g sample in 10 ml of selenite broth for24 h. Five microliters from the top of the broth was then platedonto XLD agar (Oxoid). Bacterial isolates were identified by standardbiochemical tests (glucose, lactose fermentation and productionof gas, indole and H₂S production, citrate utilization, motility,and ability to split urea) and agglutination with Salmonella 09-and Vi-specific antisera (Wellcome Diagnostics, Dartford, UnitedKingdom). Antibiotic disc sensitivities were performed by usinga modification of the method of Bauer et al. (1). Organismsresistant to chloramphenicol, ampicillin, trimethoprim, and sulfamethoxazolebut sensitive to ofloxacin and ceftriaxone were described as multidrugresistant.

Quantitative cultures. Venous blood for quantitative culture and for broth culture was taken before administration of antimicrobials for typhoidfever. The blood (3 to 9 ml from adults and 1.5 to 6 ml from children)was collected in a sterile heparinized tube and transported immediatelyto the laboratory. Quantitative whole-blood cultures (QBC) werecarried out by a pour plate method. In brief, three measured aliquotsof blood (usually 1 ml; 0.5 ml for small children) were mixedwith 19 ml of molten (50°C) Columbia agar (Unipath, Basingstoke,United Kingdom) in a sterile petri dish, allowed to set, and thenincubated at 37°C. After 2 to 4 days colonies were counted andrecorded as CFU per milliliter. Up to five colonies were pickedfrom the surface of the agar for identification. After reincubationfor 24 h standard biochemical tests and agglutination with thespecific antisera were performed. Plates were discarded as negativeif no colonies were visible after 4 days of incubation.

To determine the number of intraleukocytic CFU in blood samples, quantitative cultures were performed on peripheral bloodbuffy coats. This study was performed on a randomly chosen subgroupof patients. Heparinized whole blood (2.5 or 5 ml) taken at thesame time as QBC was centrifuged at 2,700 × g for 10 min. Theplasma was removed carefully with a sterile plastic pipette, and0.1 ml including the buffy coat layer was aspirated with a sterile1-ml syringe. Quantitative cultures were performed on this 0.1-mlsample by mixing it with 19 ml of molten Columbia agar, pouringthe mixture as an agar plate, and incubating it for up to 4 days.Peripheral blood phagocytes containing more than one bacteriumwill produce a single colony in solid culture medium. Thus, forwhole-blood and buffy coat samples, results were expressed asCFU per milliliter. To quantitate precisely the number of intracellularbacteria per infected phagocyte, a second 0.1-ml buffy coat samplewas taken and the leukocytes were lysed by incubation with 0.1ml of 0.1% digitonin (Sigma) for 10 min at 37°C. This should havereleased the intracellular bacteria. Quantitative cultures werethen performed on this sample in the same way as for the firstsample, i.e., by mixing with 19 ml of molten Columbia agar, pouringthe mixture as an agar plate, and incubating it at 37°C for upto 4 days. In order to exclude the possibility that the localizationof bacteria in the buffy coat was an artifact of the centrifugationstep, 10 ml of blood from a healthy volunteer was seeded with10⁴ CFU of S. typhi and centrifuged immediately at 2,700 × g for10 min. A 0.1-ml volume of buffy coat and 0.1 ml of the erythrocytelayer were collected with sterile 1-ml syringes, mixed with 19ml of molten Columbia agar, and allowed to set as described above.Bacterial colonies were counted after 4 days of incubation at37°C.

Calculation of bacterial counts. The number of S. typhi bacteria per milliliter of blood (QBC) was estimated from the number of CFU on each pour plate. Theminimum volume of whole blood used for quantitative methods fromany one patient was 1.5 ml for small children and 3 ml for adultsand larger children. This gives a lower limit of detection of0.7 or 0.3 CFU per ml, respectively. When reporting the numberof bacteria in buffy coat and lysed buffy coat samples the denominatorwas the volume of whole blood from which the buffy coat was collected.In patients who were broth culture positive but QBC negative,the quantitative value was estimated from the total volume ofblood cultured: 0.7 to 1.0 CFU/ml from 1.5 ml of blood and 0.3to 1.0 CFU/ml from 3 ml of blood. The viable bacteria within the0.1-ml buffy coat sample were considered to be intraleukocytic,and the organisms in the remainder of the blood were assumed tobe in the plasma. Extracellular bacterial counts were thereforecalculated by the following formula: (whole-blood CFU/ml) $-$ (buffycoat CFU/ml). The average number of viable bacteria per infectedleukocyte was calculated by the following formula: lysed buffycoat counts (in bacteria per milliliter)/unlysed buffy coat counts(in infected cells per milliliter).

Statistical analysis. SPSS for Windows (SPSS Benelux Inc., Gorinchem, The Netherlands) release 6 was used for all statistical analyses. Partialcorrelation coefficients were calculated for associations betweenthe continuous variables and bacterial counts. Differences inbacterial counts between groups defined by dichotomous variableswere tested by the Mann-Whitney U tests. Potentially confoundingvariables (site and/or age) were controlled for, and all non-normallydistributed data were ranked before correlation tests on the rankeddata were performed. Interactions were assessed by multivariateanalysis.

	RESULTS

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Broth blood culture was performed on 515 adults and children with suspected enteric fever between March 1993 and March 1996(Table 1). All patients received treatment with oral ofloxacin(total dose, 60 to 135 mg/kg of body weight given over 2 to 5days) as reported elsewhere (4, 22), and all made a goodrecovery. Enteric fever pathogens were isolated from 375 (72.8%)patients: S. typhi from 369 patients and Salmonella paratyphiA from 6 patients. For two patients the pour plate QBC was positivebut the broth blood cultures were negative. Salmonella derby wasisolated from the blood of one patient, and this patient was considerednegative for enteric fever pathogens and excluded from the analysis.The majority of S. typhi isolates (313; 80%) were multidrug resistant,i.e., resistant to chloramphenicol, trimethoprim-sulfamethoxazole,and ampicillin. Both whole-blood and buffy coat bacterial countswere performed for 187 patients. These patients had admissionclinical parameters similar to those of the 188 patients withenteric fever for whom only whole-blood QBC were performed. Simultaneouswhole-blood, buffy coat, and lysed buffy coat samples were takenfrom a subgroup of 81 patients. These patients had a slightlyshorter duration of illness before admission, i.e., a median of7 (range, 2 to 33) days compared with a median of 9 (range, 2to 33) days overall, but in all other respects their clinicalpresentations were similar.

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TABLE 1. Clinical and laboratory variables for patients with suspected enteric fever

Direct plating of buffy coat. Direct plating of buffy coat was performed for 192 patients with cases of broth culture-positive enteric fever: 190 of 191S. typhi and 1 of 1 S. paratyphi A cultures were positive, a sensitivityof 99.5% (95% confidence interval [CI], 97.1 to 100%). Althoughthe precise time for colony formation from the buffy coat cultureswas not recorded, counts were usually possible after overnightincubation. Significant contamination did not occur.

Quantitative culture results. The median S. typhi count in whole blood from patients with uncomplicated enteric fever (n = 375) was 1 CFU/ml (interquartilerange [IQR], <0.3 to 5; range, <0.3 to 387) (Fig. 1). A mean of37.5% (95% CI, 32.9 to 42.1%) of the CFU were from organisms distributedin the erythrocyte and plasma layers (n = 187), and the remaining62.5% of viable bacteria were concentrated in the buffy coat layer.The mean number of bacteria per infected leukocyte was 1.3 (IQR,0.7 to 2.4) CFU/cell (n = 81). Children less than 15 years old(n = 115) had higher whole-blood counts than did adults (n = 262):a median of 1.5 (IQR, <0.3 to 6.0; range, <0.3 to 387) versusa median of 0.6 (IQR, <0.3 to 2.8; range, <1.3 to 17.7) CFU/ml(P = 0.008). Extracellular bacterial counts were also higher inchildren less than 15 years of age than in adults: a median of1.5 (range, 0 to 93) versus a median of 0.6 (range, 0 to 17.7)(P = 0.005). When blood from a healthy volunteer was seeded withS. typhi, the concentration of organisms cultured from the erythrocytelayer was the same as that in the buffy coat layer. No bacteriawere cultured from the plasma layer. Thus, S. typhi cells werenot concentrated in the buffy coat as a result of centrifugation.

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FIG. 1. Distribution of blood bacterial counts in acute typhoid fever.

Antibiotic resistance and blood bacterial counts. The QBC counts were higher in patients infected by multidrug-resistant S. typhi (n = 313) than in those infected by more sensitiveisolates (n = 62): a median of 1.3 (range, 0 to 387) versus amedian of 0.5 (range, 0 to 32) CFU/ml (P = 0.006) (Fig. 2). Patientsinfected by multidrug-resistant strains tended to be younger thanpatients infected by more sensitive strains: a median of 10 (IQR,6 to 15) versus a median of 13 (IQR, 7 to 24) years (P = 0.02).The duration of the preceding illness was also slightly shorterin infections by multidrug-resistant strains: a median of 9 (IQR,6 to 12) versus a median of 10 (IQR, 6 to 15) days (P = 0.07).In a multivariate analysis, duration of preceding illness, ageof the patient, and multidrug resistance in the isolated S. typhiproved to be associated independently with the blood bacterialcount (P = 0.04, P = 0.003, and P = 0.02, respectively). The associationbetween blood bacterial counts and multidrug resistance was foundto be robust and could not be explained by confounding factors.

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FIG. 2. Blood bacterial counts in patients infected by antibiotic-sensitive and multidrug-resistant S. typhi. $bullet$ , median; the bars indicate the IQR. Each circle represents one patient.

Duration of illness. There was a decline in whole-blood bacterial counts with increasing duration of illness. The median whole-blood counts were1.7 (range, <0.2 to 387) CFU/ml in the first week of illness,1 (range, 0.2 to 68) CFU/ml in the second week, 1 (range, <0.2to 23) CFU/ml in the third week, and 0.3 (range, <0.2 to 19) CFU/mlin the fourth week of illness (P < 0.001). This remained statisticallysignificant when age and site were both controlled for in thepartial correlation analysis (P = 0.002). Similar trends wereobserved for intracellular (P = 0.06) and extracellular (P = 0.03)counts. The proportion of organisms that was extracellular alsodeclined with duration of illness, but in a multiple regressionanalysis, controlling for age and multidrug resistance, this trenddid not reach statistical significance (P = 0.058).

Stool cultures. S. typhi was isolated from 24 of 167 patients' stool samples. The median blood bacterial count in patients with positive stoolcultures was significantly higher than that in those with negativecultures: 3 (IQR, 0.7 to 7.3) CFU/ml compared to 1 (IQR, <0.3to 3.0) CFU/ml (P = 0.02). The relative risk for stool carriagein patients with infections by multidrug-resistant S. typhi comparedto that for patients with infections by fully sensitive S. typhiwas 3.0 (95% CI, 0.75 to 12.3) (P = 0.15).

	DISCUSSION

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Enteric fever is a characteristic clinical syndrome which differs clinically and pathologically from other septicemias causedby gram-negative bacteria. The illness has a subacute onset andchronic course when untreated, but it rarely causes endotoxicshock and carries a significantly lower mortality than other septicemiascaused by gram-negative bacteria (6, 12, 15, 16, 23).Despite these differences the levels of bacteremia in patientswith uncomplicated typhoid (median count, 1 CFU/ml; mortality,<1%) (27) are similar to those reported in bacteremias causedby other enterobacteriaceae (mortality 10 to 50%) (6, 16,27). Approximately 50% of patients with typhoid fever whoseblood cultures are positive have less than 1 CFU/ml of blood,and 10% have greater than 50 CFU/ml. Thus, the pathological differencesbetween septicemia caused by enteric fever pathogens and thatcaused by other enterobacteriaceae cannot be explained by differencesin the numbers of organisms circulating in the blood. In a previousstudy of 25 patients with typhoid fever reported by Butler etal., blood bacterial counts were higher: five patients had countsof more than 100 CFU/ml (3). In that series a small volume(0.1 ml) of blood was plated directly onto bile-containing agar,which may have released intracellular organisms. The patientswere also more severely ill (three had intestinal hemorrhages,and two died). However, intestinal perforation and hemorrhageare usually signs of a late stage of typhoid and are associatedwith lower diagnostic yields from blood culture (5, 17).In the present study severely ill patients, who comprise lessthan 5% of all cases in this area, were not included (although14 of 374 patients did have evidence of upper gastrointestinalbleeding). The range of bacterial counts in blood in this largestudy of typhoid fever is similar to those in the much-smallerstudies reported previously by Rubin et al., using first a semiquantitativeDNA hybridization method (19) and, second, direct cultures (18).

In terms of intrinsic toxicity there is little difference between enterobacteriaceae. The purified endotoxin of S. typhi issimilar in cytotoxicity and ability to induce proinflammatorycytokine release to that of Escherichia coli (26). However,septicemias caused by gram-negative bacteria are often suddenin onset, whereas the subacute progression of typhoid may allowsome endotoxin tolerance to develop (11, 14). The salmonellae,including S. typhi, have evolved mechanisms for downregulatingthe inflammatory response, presumably to facilitate persistenceand transmission (7). As in other severe bacterial infections,higher bacteremias were found more commonly in children with typhoidfever and were associated with higher peak temperatures. Thismay reflect lower background immunity. The principal differencebetween systemic infection with salmonellae and that with otherenterobacteriaceae is that two-thirds of the bacteria in the circulatorysystem are located within phagocytic cells, where they remainviable. Thus, the numbers of extracellular organisms in the bloodstreamin patients with typhoid tends to be lower than in those withother systemic infections.

The concentration of typhoid bacilli in the buffy coat (presumably in monocytes and polymorphonuclear leukocytes) means thatdirect plating of this cell layer provides an alternative andmore rapid method of diagnosis than whole-blood broth culture.Colonies were usually evident after an overnight incubation. Inthis study the average number of organisms per phagocytic cellwas 1.3, a figure identical to that reported by Rubin et al. (18).Lysing of the phagocytic cells increased absolute numbers of CFUidentified but not the sensitivity of the procedure. Overall,buffy coat culture was as sensitive as whole-blood broth cultureand allowed earlier organism identification and antimicrobialsensitivity testing. Contamination was rare in this study. Buffycoat culture might be particularly useful for young children,who tend to have higher bacteremias, as it allows a smaller totalvolume of blood to be taken. Plasma from the same sample can beused for both biochemical and serological tests.

In this study bacterial counts in blood declined with increasing duration of illness. The declining diagnostic sensitivityof blood culture with increasing duration of illness in typhoidhas been well known throughout this century. In 1907 a reviewof the literature reported that 89% of blood cultures were positivein the first week of typhoid fever, 73% were positive in the second,60% were positive in the third, and only 26% were positive inthe fourth and subsequent weeks (5). Modern blood culture mediacontain sodium polyanetholesulfonate (Liquoid) and may be betterat growing lower numbers of bacteria than those used previously(8, 9), but the trend in this large study was the same.The declining numbers of bacteria in blood coincide with an increasingrisk of small bowel ulceration and bleeding as the typhoid bacilliconcentrate in the Peyer's patches and areas of necrosis formin the gut wall.

In other studies in which multidrug resistance has been linked to severity of typhoid, the association has been ascribed toincorrect initial treatment and thus further progression of thedisease and later presentation to hospital (2, 25). In thisstudy patients with typhoid caused by multidrug-resistant strainshad higher numbers of S. typhi bacteria in the blood than patientsinfected by antibiotic-sensitive organisms. They also had a slightlyshorter preceding duration of illness, so previous treatment withineffective antimicrobials is unlikely to explain the higher bacteremiasin this group. Although ineffective previous treatment cannotbe definitely excluded, as many patients are unsure of the medicationsthey have received, fluoroquinolones were the antibiotics mostlikely to have been prescribed outside the hospital in the studysites (22a), and these should have been equally effective againstdrug-resistant and sensitive bacteria. Furthermore, fluoroquinolonesusually sterilize the blood within 2 days in patients with typhoid,so it is very unlikely that significant antibiotic treatment courseshad been given. Patients with infections by multidrug-resistantbacteria tended to be younger, but in a multivariate analysisdrug resistance was associated independently with higher bacteremias.This suggests that the multidrug-resistant phenotype may be associatedwith virulence in S. typhi. Multidrug resistance in S. typhi isencoded by genes carried in large transferable plasmids. Whetherthese plasmids carry other virulence genes or whether the resistancemechanisms themselves somehow enhance bacterial survival and multiplicationin vivo is not known.

Single-admission stool cultures were positive for S. typhi in 14.3% of 167 patients. Carriage of S. typhi in the stool wasassociated with significantly higher bacterial counts in the blood.As multidrug resistance was also positively associated with bacterialcounts in the blood, patients infected by multidrug-resistantbacteria were more likely to excrete the organisms in the stool,although this difference did not reach statistical significance.If studies of larger series of patients confirm this observation,then the association of drug resistance with increased bacteremiasand also increased transmission potential would provide a plausibleexplanation for the recent very rapid spread of multidrug-resistanttyphoid bacilli in the southern part of Vietnam.

	ACKNOWLEDGMENTS

We are very grateful to the directors and staffs of the Dong Thap Provincial Hospital and the Centre for Tropical Diseases,Ho Chi Minh City. We are particularly grateful to the MicrobiologyDepartments in both institutions for their help, and to JulieSimpson for statistical advice.

This study was supported by The Wellcome Trust of Great Britain.

	FOOTNOTES

^* Corresponding author. Mailing address: Wellcome Trust Clinical Research Unit, Centre for Tropical Diseases, Cho Quan Hospital,Ho Chi Minh City, Vietnam. Phone: 84 88 353954. Fax: 84 88 353904.E-mail: oxford.wellcome{at}bdvn.vnd.net.

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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
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