Rahnella aquatilis is an infrequently isolated Gram-negative rod within the Enterobacteriaceae family. The organism’s natural habitat is water. The organism is rarely isolated from clinical specimens and it seldom causes infection in immunocompetent individuals. Here we present a one-month-old boy who was born prematurely at 27th week of gestation by cesarean section with a birth weight of 730 g. He developed sepsis caused by Rahnella aquatilis during the treatment for ventilator associated pneumonia due to Stenotrophomonas maltophilia with ciprofloxacin. He was successfully treated with a combination of amikacin plus meropenem. Although R. aquatilis is one of the saprophyticus organisms, it may cause life-threatening infection in newborn.
1. Introduction
Rahnella aquatilis is an infrequently isolated Gram-negative rod within the Enterobacteriaceae family. The organism’s natural habitat is water [1]. The organism is rarely isolated from clinical specimens and it seldom causes infection in immunocompetent individuals. The infections ascribed to this organism are bacteremia, sepsis, respiratory infection, urinary tract infection, wound infections in immunocompromised patients, and infective endocarditis in patients with congenital heart disease. Here we present a one-month-old boy who was born prematurely at 27th week of gestation by cesarean section with a birth weight of 730 g. He developed sepsis caused by R. aquatilis despite ciprofloxacin according to ventilator associated pneumonia caused by Stenotrophomonas maltophilia. The mother who underwent bone marrow transplantation 3 years before pregnancy for essential thrombocytosis had reportedly preeclampsia during the last trimester.
2. Case
He was born prematurely at 27th week of gestation by cesarean section with a birth weight of 730 g, APGAR score 8 at 1 minute and 7 at 5 minutes. He was supported by mechanical ventilator for respiratory distress syndrome and was given parenteral nutrition by an umbilical venous catheter. Because of CRP of 10 mg/L and platelets count of 170,000/μL, ampicillin and gentamicin were initiated for suspected septicemia on the first day of his life. There were not any positive cultures (Table 1). On the second postnatal day, after the increase in both oxygen demand and pressure requirement as well as laboratory findings including leukocytes count of 30,000/μL, platelets count of 80,000/μL, and CRP of 42.4 mg/L, the antibiotic regimen was replaced by vancomycin and cefepime (Table 1). Meanwhile on echocardiography, patent ductus arteriosus was determined; then ibuprofen was added. However ibuprofen was discontinued because of side effects such as increased creatinine and thrombocytopenia.
All the patient’s significant laboratory/microbiological findings and the corresponding therapeutical changes.
Postnatal day
Clinical picture
Leukocytes count (/µL)
Platelets count (/µL)
CRP (mg/L)
Culture
Treatment
1st day
Suspected septicemia
40,000
170,000
10
Negative
Ampicillin and gentamicin
2nd day
Increasing in both oxygen demand and pressure requirement
30,000
80,000
42.4
Negative
Vancomycin and cefepime
8th day
Need for reintubation, abdominal distension, and hypotension
1,000
5,000
120
Negative
Meropenem and liposomal amphotericin B as well as intravenous immunoglobulin as adjuvant therapy
14th day
Pneumonia and atelectasis?
23,000
150,000
36
Negative
Linezolid was added
21st day
Pneumonia, oxygen desaturation, increasing ventilation demand, and suctioning requirement
28,000
110,000
89
S. maltophilia was isolated from endotracheal aspirate culture
Ciprofloxacin was added to liposomal amphotericin B
25th day
Pneumonia, oxygen desaturation, increasing ventilation demand, and suctioning requirement
21,000
33,000
110
Vancomycin and ceftazidime were added to ciprofloxacin; liposomal amphotericin B was discontinued
26th day
The blood cultures taken on 22nd and 23rd day were resulted in on 26th day. R. aquatilis was isolated from blood cultures
Meropenem and amikacin for 21 days
On the 4th postnatal day, fluconazole prophylaxis was given to prevent invasive fungal infection. On the 8th postnatal day, he was extubated but he needed reintubation on the same day. Despite therapy, we observed deep thrombocytopenia (5,000/μL), leukocytes count of 1,000/μL, CRP of 120 mg/L, and clinical deterioration including abdominal distension and hypotension and, thus, cefepime was replaced by meropenem and liposomal amphotericin B as well as intravenous immunoglobulin. An adjuvant therapy was added to antimicrobial regimen (Table 1). At the same time no pathologic finding was found. Any additional finding with respect to necrotizing enterocolitis was not also found. Then, his clinical picture improved.
However, on the 14th postnatal day, his clinical picture deteriorated again. The umbilical venous catheter was removed. Because he developed suspected pneumonia, the antimicrobial treatment was replaced by linezolid, meropenem, and liposomal amphotericin B. Moreover findings were considered as atelectasis, so the appropriate therapy was given (Table 1). On the 19th postnatal day his clinical picture was noted to improve; therefore he was extubated and any microorganism was not isolated from all cultures, so linezolid was stopped. Meropenem and liposomal amphotericin B were continued.
On the 21st postnatal day apnea and bradycardia occurred. He was supported by mechanical ventilator. Ciprofloxacin was added to liposomal amphotericin B, because Stenotrophomonas maltophilia was isolated from endotracheal aspirate culture at the time of clinical deterioration. On the 25th postnatal day, since leukocytes count was 21000/μL, it was determined that platelets count was 33,000/μL and CRP 110 mg/L. Vancomycin was added to antimicrobial regimen, including ciprofloxacin. Liposomal amphotericin B was discontinued. Ceftazidime was added to antimicrobial treatment according to antibiogram susceptibility, because Stenotrophomonas maltophilia was isolated in endotracheal aspirate culture again. At the same time echocardiography did not show any pathologic findings suggesting endocarditis and patent ductus arteriosus was closed. Meanwhile Rahnella aquatilis resistant to piperacillin and cephalosporins, and susceptible to carbapenems and aminoglycosides, was isolated from both blood cultures taken on 2nd day and 3rd day of ciprofloxacin; the antimicrobial regimen was changed to meropenem and amikacin (Table 1). The patient was successfully treated with a combination of amikacin plus meropenem for 21 days. His clinical picture and laboratory findings returned normal. Upon starting full enteral feeding, he was discharged from the hospital.
3. Discussion
Rahnella aquatilis is environmental bacteria commonly isolated from water [1]. To our knowledge, there are 18 reports in the literature about human infection caused by R. aquatilis. The majority of these suggested that the infection had been accompanied by diabetes mellitus, alcoholism, cancer, AIDS, and immunosuppression secondary to medications, suggesting that the microorganism may have been an opportunistic pathogen. However, 5 reported cases were in nonimmunocompromised patients [1–5]. The organisms were isolated from blood [1–4, 6–12], wounds [5, 8], urine [8, 13–15], the respiratory tract [8, 16], and stool cultures [8]. In our patient, considering the patient’s clinical deterioration, R. aquatilis was accepted as active agent because it reproduced in the separate blood cultures. The origin of the R. aquatilis strain isolated from our patient is unclear. There were no other reported R. aquatilis infections in the hospital during his time there. We did not think of an outbreak due to R. aquatilis, so newborn intensive care unit water was not tested for R. aquatilis. Our patient was successfully treated with a combination of amikacin plus meropenem. Although R. aquatilis is one of the saprophyticus organisms, it may cause life-threatening infection in newborn, especially early preterm and very low birthweight babies.
Conflict of Interests
The authors declare no conflict of interests.
CaroffN.ChamouxC.le GallouF.EspazeE.GaviniF.GautreauD.RichetH.ReynaudA.Two epidemiologically related cases of Rahnella aquatilis bacteremia199817534935210.1007/s1009600500802-s2.0-0031854362ChangC. L.JeongJ.ShinJ. H.LeeE. Y.SonH. C.Rahnella aquatilis sepsis in an immunocompetent adult19993712416141622-s2.0-0032727166SakataH.MaruyamaS.Study on bacteremia due to community-acquired infection in infants and children without underlying diseases19987211119712012-s2.0-0032198858MatsukuraH.KatayaniaK.KitanoN.KobayashiK.KaneganeC.HiguchiA.KyotaniS.Infective endocarditis caused by an unusual gram-negative rod, Rahnella aquatilis199617210811110.1007/s0024699000232-s2.0-0029967420MarakiS.SamonisG.MarnelakisE.TselentisY.Surgical wound infection caused by Rahnella aquatilis19943211270627082-s2.0-0028143548LibertoM. C.MateraG.PuccioR.Lo RussoT.ColosimoE.FocàE.Six cases of sepsis caused by Pantoea agglomerans in a teaching hospital20093211191232-s2.0-62149147517CarinderJ. E.ChuaJ. D.CoralesR. B.TaegeA. J.ProcopG. W.Rahnella aquatilis bacteremia in a patient with relapsed acute lymphoblastic leukemia200133647147310.1080/003655401520299722-s2.0-0034958587ReinaJ.LopezA.Clinical and microbiological characteristics of Rahnella aquatilis strains isolated from children199633213513710.1016/s0163-4453(96)93138-22-s2.0-0029815629FunkeG.RosnerH.Rahnella aquatilis bacteremia in an HIV-infected intravenous drug abuser199522329329610.1016/0732-8893(95)00100-o2-s2.0-0029099575OhH. M. L.TayL.Bacteraemia caused by Rahnella aquatilis: report of two cases and review1995271798010.3109/003655495090189792-s2.0-0028927381HoppeJ. E.HerterM.AleksicS.KlingebielT.NiethammerD.Catheter-related Rahnella aquatilis bacteremia in a pediatric bone marrow transplant recipient1993317191119122-s2.0-0027292815GoubauP.van AelstF.VerhaegenJ.BoogaertsM.Septicaemia caused by Rahnella aquatilis in an immunocompromised patient19887569769910.1007/bf019642612-s2.0-0024097434DomannE.HongG.ImirzaliogluC.TurschnerS.KühleJ.WatzelC.HainT.HossainH.ChakrabortyT.Culture-independent identification of pathogenic bacteria and polymicrobial infections in the genitourinary tract of renal transplant recipients200341125500551010.1128/jcm.41.12.5500-5510.20032-s2.0-0346849591WooP. C. Y.CheungE. Y. L.LeungK.-W.YuenK.-Y.Identification by 16S ribosomal RNA gene sequencing of an Enterobacteriaceae species with ambiguous biochemical profile from a renal transplant recipient2001392859310.1016/s0732-8893(01)00206-12-s2.0-0035097461AlballaaS. R.QadriS. M. H.Al-FurayhO.Al-QataryK.Urinary tract infection due to Rahnella aquatilis in a renal transplant patient19923011294829502-s2.0-0026786204FajardoM.BuenoM. J.Isolation of Rahnella aquatilis in the tracheostomy exudate from a patient with laryngeal cancer2000185251