key: cord-0953826-fedi5yfw authors: Nishi, Shawn P.E.; Valentine, Vincent G.; Duncan, Steve title: Emerging Bacterial, Fungal, and Viral Respiratory Infections in Transplantation date: 2010-08-02 journal: Infect Dis Clin North Am DOI: 10.1016/j.idc.2010.04.005 sha: 17f8de3daa217100594a69a7da92259979b18019 doc_id: 953826 cord_uid: fedi5yfw Kidney, liver, heart, pancreas, lung, and small intestine transplantations are viable therapeutic options for patients with end-stage organ failure. Ongoing advancements of surgical techniques, immunosuppressive regimens, and perioperative management have resulted in improved survival of allograft recipients. Despite these refinements, infections still contribute to substantial morbidity and mortality, limiting long-term success rates of these procedures. This article discusses the emerging bacterial, fungal, and viral respiratory infections in transplantation. To help prevent the occurrence of common opportunistic infections in transplant recipients, prophylactic strategies have been used, but despite these efforts, emerging pathogens continue to pose unique challenges for clinicians to recognize, diagnose, and treat. One useful paradigm relevant to emerging infections in recipients of transplants stratifies these microbes into 3 categories. 1 The first category consists of known microbes causing infection with previously unrecognized pathogenicity causing human disease. Category 2 includes known microbes with already appreciated pathogenicity but cause more frequent or severe disease. The third category comprises newly discovered pathogens. This last category is growing apace in large part from technological advances that result in diagnosis or differentiation of new microbial pathogens. This article describes some of the organisms responsible for emerging respiratory infections in transplantation (Box 1). Nocardia is a gram-positive filamentous aerobic actinomycete with variable acid-fast staining characteristics. Among more commonly reported opportunists in transplantation, pulmonary nocardiosis infection rates range from 0.7% to 3.5%. [2] [3] [4] [5] [6] [7] The largest case series in transplantation describes these infections to be more common among lung recipients (3.5%), followed by recipients of heart (2.5%), intestine (1.3%), kidney (0.2%), and liver (0.1%). 7 However, literature reviews are difficult to systematically assess. With more than 50 species in existence, taxonomic classification is fraught with confusion and controversy. Until recently, most isolates causing human disease were labeled ''Nocardia asteroides'' and included organisms with considerable differences in antimicrobial susceptibility patterns. 8 With technological advances in molecular genotyping, isolates previously described as N asteroides have been subspeciated. 8 N asteroides is now denoted as N asteroides complex and includes Nocardia nova complex, Nocardia farcinica, Nocardia transvalensis complex, Nocardia Box abscessus, and, newly, Nocardia cyriacigeorgica. 8, 9 Moreover, additional species will emerge with continued advances in genotyping methods. Clinically and radiographically, most nocardial infections are nonspecific and often confined to the lungs, which usually have a favorable prognosis. 10, 11 These pathogens hematogenously disseminate in 20% to 25% of cases to the central nervous system, skin, and other organs, and, although much less frequently reported, extrapulmonary extension of infection is almost always fatal. 3, 5, 7, 10, 12, 13 Therefore, early recognition and prompt therapy is crucial. With ill-defined clinicoradiographic features, diagnosis is frequently delayed. Nocardia is a slow growing organism, with a mean duration of 2 weeks before a diagnosis is established. Concurrent infection or contamination by other microbes can overwhelm the growth of Nocardia species in laboratory culture media and further impede diagnosis. 6 Several studies suggest that Nocardia as the sole pathogen is uncommon in comparison with nocardial infections with other coisolates of cytomegalovirus, Aspergillus, or opportunistic fungi. [14] [15] [16] Given the delays in diagnosis, the clinician should have a low threshold to institute therapy early while awaiting culture results. Trimethoprim-sulfamethoxazole (TMP-SMX) prophylaxis for Pneumocystis jiroveci pneumonitis is widely thought to afford protection against Nocardia infections. 13 However, more than 60% of nocardiosis have occurred in patients receiving TMP-SMX prophylaxis. Conversion to high-dose therapy has been curative, suggesting that prophylaxis dosages are ineffective for nocardiosis prevention but does not indicate a reduced susceptibility once infection is established. 3, 6, 7, 10, 17 Most therapeutic regimens use TMP-SMX combined with imipenem, amikacin, third-generation cephalosporins, minocycline, moxifloxacin, or linezolid from concerns about resistance. 6, 18 To avoid recidivism, a protracted course of at least 6 to 12 months in immunocompromised patients is recommended. 5 M abscessus is a gram-positive rod classified as rapid-growing nontuberculous mycobacteria. It is ubiquitously present in sewage, drinking water, decaying vegetation and the normal skin flora. Genotyping by polymerase chain reaction (PCR) methods have enabled distinction and subspeciation of this pathogen from Mycobacterium chelonae in 1992. 19 M abscessus is identified frequently in patients with cystic fibrosis (CF), less often in others with structural lung abnormalities caused by chronic respiratory disease, and occasionally among immunocompromised hosts. In a prevalence study of nontuberculous mycobacterium isolated from sputum cultures of patients with CF, M abscessus was second to Mycobacterium avium complex (72%). The sensitivity of sputum culture to detect disease due to M abscessus is low and increases little with serial sputum samples from 7% to 13%. 20 Clinicoradiological findings are nonspecific and complicated by underlying structural lung disease, making the diagnosis elusive. 21, 22 Infection is confined to the lungs in patients with CF, but dissemination is not uncommon among immunocompromised patients, including transplant recipients, which usually portends a poor prognosis. 20, [23] [24] [25] [26] [27] Whether M abscessus colonization before lung transplantation should be a contraindication is unknown. [24] [25] [26] Current guidelines urge caution in the face of virulent or resistant mycobacteria, especially with positive results for sputum smears before transplant, reflecting high airway mycobacterial loads. 25 The allograft can be secondarily colonized by microbes that persist proximally to the anastomoses and predisposes the recipient to infection of the newly transplanted lung. Treatment to Emerging Respiratory Infections in Transplantation establish and maintain serial smear negativity before transplantation and extension of treatment intraoperatively and postoperatively have had some success. 25 Treatment of M abscessus is complex and difficult for patients and clinicians. M abscessus isolates are resistant to most antimycobacterial agents, including tetracyclines, fluoroquinolones, and sulfonamides. 28 Initial therapy should include a combination of clarithromycin, amikacin, and cefoxitin or a carbapenem, pending sensitivity studies. Directed combination therapy should continue a minimum of 12 months after negative results of sputum cultures to avoid relapse. 20, 29 Maintenance suppressive therapy with clarithromycin and aerosolized amikacin has also been suggested, as relapse after extended therapy has occurred. 29 The toxic effects of therapy and interactions with transplant medications limit adequate treatment. R equi is an asporogenous, nonmotile, pleomorphic gram-positive coccobacilli and an obligate aerobe belonging to the family Nocardioform, order Actinomycetes. 30 The organism is present in soil, thrives in freshwater and marine habitats, and can live in the intestines of bloodsucking arthropods. It can be acquired by inhalation from the soil, direct inoculation, ingestion, colonization, and person-to-person transmission. 30 R equi was first isolated as a causative agent of equine bronchopneumonia in 1923. The first human infection of R equi was reported in 1967 as cavitary pneumonia in a patient with autoimmune hepatitis receiving immunosuppressive therapy. Only 13 other cases have been reported up to 1983. 30 Subsequently, a marked increase in reported cases has occurred commensurate with human immunodeficiency virus, advances in cancer therapies, and transplantation. 30 More than 100 cases have now been reported, with 29 involving organ recipients, of which 23 involved the lungs. 31 Establishing a diagnosis of R equi is difficult. Imaging is nonspecific and occasionally normal. [32] [33] [34] Identification of R equi from culture has proven difficult because of variable acid-fast staining and pleomorphic appearance in laboratory media. 30 Two studies have reported R equi lung infections in heart recipients initially misdiagnosed when laboratory cultures grew ''diptheroids'' mistaken for contaminants. Two other cases involving the kidney and pancreas and a pancreas recipient were misdiagnosed as tuberculosis, based on acid-fast staining and radiographs showing an upper lobe cavity, small satellite nodules, perihilar mass, and nonspecific infiltrate. 35, 36 Final diagnosis was confirmed by bronchoalveolar lavage cultures prompted by worsening respiratory symptoms. Given the limited number of cases, heterogeneous patient populations, and diverse clinical manifestations, standard treatments for R equi infection do not exist. However, success has been reported with dual antibiotic therapy for a minimum of 6 months and surgical drainage of complicated cases. 30, 37, 38 Combinations using vancomycin, imipenem, aminoglycosides, and fluoroquinolones are suggested empiric regimens until antimicrobial susceptibilities of the isolate are known. 30 Aside from Candida species, Aspergillus species are the most common fungal pathogens causing infection in transplant patients. This genus comprises more than 175 species, and although only a few are human pathogens, mortality of invasive aspergillosis varies from 74% to 92%. 40 Aspergillus fumigatus is the most common cause of disease, followed by Aspergillus flavus and rarely A terreus, Aspergillus niger, or Aspergillus nidulans. 41 Recently, A ustus and A terreus have gained attention as rare, mycelial fungi responsible for fatalities with posttransplant respiratory infection. 40, [42] [43] [44] [45] [46] [47] [48] [49] [50] Primary modes of acquisition are inhalation of environmental microconidia, similar to other mycelial fungi, or direct inoculation through the skin. 51 Predisposing factors include prolonged and severe neutropenia, high-dose steroid treatment, nosocomial exposure in hospitals undergoing construction, and prophylactic use of amphotericin B aerosols. 42, 49, 50, 52 Once a primary respiratory infection is established, the organism has a proclivity to disseminate. Most cases of A terreus and A ustus infections were described in the last 15 years. 45 This increase is attributed to the growing population of severely immunosuppressed patients and better diagnostic methods. Among cases reviewing these pathogens in transplant recipients, infection involved the lungs in all but one case noted with A ustus. 51,53-63 More than half disseminated and a third involved the central nervous system or skin. 62 A terreus is emerging as the next most common invasive pulmonary aspergillosis after A fumigatus and A flavus. [42] [43] [44] [45] [46] [47] [48] [49] [50] Clinicians must possess an index of suspicion and a low threshold for aggressive and often invasive diagnostic procedures necessary for sampling. In many instances, Aspergillus species have unique histomorphologic characteristics from culture isolates facilitating identification. However, rarely encountered Aspergillus species such as A ustus and A terreus are not readily identified. Diagnoses by growth in culture may also be hindered by concurrent infecting organisms, most frequently other Aspergillus species, in nearly half of patients. 44 PCR analysis has advantages for rapid diagnosis because definitive speciation by culture takes weeks. 43, 51, 56, 58, 60, 63 Early antifungal therapy is routinely initiated once a fungal pathogen is suspected or presumptively identified. However, this strategy is tempered by highly variable susceptibilities of A terreus and A ustus. 42, 43, 45, 47, 49 Growing recognition of A ustus and A terreus is clinically important, as these species are resistant to amphotericin B, which has been standard therapy for most invasive Aspergillus infections. 42, 45, 47 Reports involving a series of 17 patients noted that 3 of 4 patients with A ustus who survived received voriconazole combined with caspofungin, although other reports using the same antifungal regimen as prophylaxis or as empiric therapy have not proven successful. 51, 54, 56, 62, 63 Unfortunately, A terreus infections are difficult to treat, with few reported successes. Only isolated respiratory infection has been amenable to amphotericin B with itraconazole after surgical lobectomy in a nonneutropenic transplant recipient. 43 Firm data for treating A ustus and A terreus infections are not available, as reflected by the multitude of antifungal regimens used. Other nonpharmacologic methods such as reduction in immunosuppression and local surgical debridement have had some success as adjunctive therapy. 42, 47, 49, 52, 57, 64 Overall, however, treatment results are disappointing. Fusarium solani is a colorless, septated mycelial fungus found in the soil, with increased frequency among transplant recipients. 65 The portal of entry is unclear, but inhalation, ingestion, and direct inoculation are suspected. Infection disseminates by vascular invasion with formation of yeast-like structures in the blood (adventitious sporulation), which are easily cultured. 65 Other than the characteristic fusiform or canoe-shaped macroconidia, Fusarium species are indistinguishable from Aspergillus species by routine histology. 65 Diagnosis ultimately requires speciation from culture. 66 Among transplant recipients, reported infections have mostly occurred in hematopoietic stem cell transplantation (HSCT) recipients with prolonged neutropenia and are rarely seen in solid organ recipients. Notable differences exist between HSCT Emerging Respiratory Infections in Transplantation and organ recipients. First, fusariosis in HSCT recipients occurs in a trimodal distribution: early posttransplant during extreme neutropenia, a median of 70 days after transplant associated with acute graft versus host disease (GvHD) (while receiving corticosteroid therapy), and more than 1 year posttransplant in association with extensive GvHD; however, in solid organ recipients, fusariosis occurs after the first year of transplantation. 67, 68 Next, HSCT recipients typically have fungemia with disseminated fusariosis, whereas organ recipients develop isolated infection. Only 6 cases have been reported up to 2001 in solid organ recipients, with only 1 disseminated and others isolated to lung (n 5 1) or skin (n 5 4). [68] [69] [70] Localized infection in HSCT recipients, although much less reported, includes septic arthritis, endophthalmitis, osteomyelitis, cystitis, brain abscess, and cutaneous necrotizing lesions. 66 Lung (pneumonia, nonspecific alveolar or interstitial infiltrates, nodules, cavities) is the most commonly involved site of infection, accounting for 39% of HSCT recipients who develop invasive disease. 67 Last, especially in the setting of prolonged neutropenia, fusariosis mortality rates are up to 70% to 100% in HSCT recipients. No deaths due to fusariosis have been seen in organ recipients. 68 Effective treatment regimens for fusariosis in transplantation are unknown but invariably require correction of neutropenia. 66, 67 Response rates of disseminated fusariosis to antifungal therapy are disappointing, as most organisms are resistant to currently available antifungals. 66, 71 Surgical resection of localized disease combined with topical antifungal therapy has been successful in most patients, 66 whereas treatment with amphotericin B alone has only a 32% response rate. 72 Response rates up to 45% are reported with voriconazole and posaconazole salvage treatment after amphotericin B failure. 48, 73 Adjunctive therapy with granulocyte transfusions and granulocyte colony-stimulating factor has shown some benefit but has not been extensively studied. 65 The genus Scedosporium includes two important human pathogens, S apiospermum and S prolificans. Historically, Scedosporium species are found in patients with hematologic malignancy or destructive chronic lung disease such as CF. Scedosporium species are the second most common mold (after Aspergillus species) colonizing airways of patients with CF. [74] [75] [76] [77] These organisms are found ubiquitously in soil, sewage, and polluted waters and are histologically indistinct from Aspergillus, Fusarium, and other mycelial fungi. 78 Infection occurs via inhalation of spores or direct tissue inoculation and most commonly involves the respiratory tract. 78, 79 Before 2000, there were only 4 cases of disseminated infection in organ transplant recipients. 80 Recently, Scedosporium has emerged as a pathogen among the growing immunocompromised population, particularly transplant recipients. PCR methods are being developed to facilitate early identification of this pathogen. 75 The spectrum of disease for both Scedosporium species resembles aspergillosis. However, there are notable clinical differences between these 2 pathogens. S apiospermum, the asexual anamorph of Pseudallescheria boydii, is found throughout the world, whereas S prolificans is geographically concentrated in Spain, Australia, and the southern United States. [76] [77] [78] 81 Rates of invasive infection are reported in 6% of cases with S apiospermum and in more than half of patients with S prolificans. 76 In addition, mortality rates of S apiospermum and S prolificans infection range from 47% to 68% and from 50% to 100%, respectively, with respiratory involvement associated with higher mortality. 74, 76, 77, 79, 82, 83 Scedosporium infections have been reported since 1985 in bone marrow transplant recipients but only recently in solid organ transplantation with prominent differences in manifestations of infection within these 2 populations. 77 In a comparison between 23 HSCT and 57 solid organ recipients with Scedosporium species infection, the former were more likely to have infection by S prolificans and have early infections (within 90 days compared with >1 year) given that solid organ recipients rarely become neutropenic. HSCT recipients were also more likely to develop fungemia and had the poorest response to therapy (40%-45% compared with 63%). 77, 80, 81, 84 Reported rates of fungemia (70%) and dissemination (44%) with S prolificans are notably greater than with Aspergillus species and is attributed to the organism's ability to undergo adventitious sporulation. 83, 84 Unfortunately, effective antifungal therapy for Scedosporium infection is lacking. S apiospermum and S prolificans are resistant to amphotericin B and most antifungals. S apiospermum may have some susceptibility to the newer triazoles, and anecdotal regimens based on prior successfully treated cases are reported using voriconazole as monotherapy or in combination with terbinafine or an echinocandin. 74, 81, 82, 85, 86 S prolificans, however, remains resistant to all antifungals, as no therapy was shown to reduce mortality. 83, 85 Only surgical excision and recovery from neutropenia were independently associated with survival from S prolificans. 83 Long-term itraconazole treatment in combination with fluconazole among patients with structurally abnormal airways who were colonized with Scedosporium species have lower rates of dissemination, suggesting a possible role of maintenance therapy to prevent disease progression. 84 Human metapneumovirus (hMPV) is a nonsegmented, single-stranded RNA virus belonging to the Paramyxoviridae family. First described in 2001 in the Netherlands among children with acute respiratory viral symptoms, hMPV has since been increasingly noted to have worldwide distribution among children and immunocompromised adults, including transplant recipients. [87] [88] [89] [90] [91] Infection with hMPV mimics the course of respiratory syncytial virus (RSV), with a spectrum from mild respiratory symptoms and wheezing to severe bronchiolitis and pneumonia. Symptomatic infection occurs in less than 5% of the general population and up to about 5% to 10% of the immunocompromised population. 87, 89, 92 In temperate climates, seasonal variation occurs predominantly in late winter (January to April). [87] [88] [89] The clinical and radiographic courses of the disease closely resemble that of RSV infection, and this diagnosis should be considered after RSV infection is ruled out. 87 The first case of hMPV in transplantation involved an HSCT recipient who died within a week because of pneumonia and respiratory failure. 93 Since then, multiple series among HSCT, lung, and a liver recipient have been published. [88] [89] [90] [93] [94] [95] [96] [97] [98] [99] [100] [101] One study involving lung transplantation recipients showed an association between detection of replicating hMPV in bronchoalveolar lavage specimens and allograft rejection. 96 Despite intensifying immunosuppression to treat acute rejection, viral clearance and reduced viral replication to lower than detectable levels was still achievable in contrast to other respiratory viral data, particularly cytomegalovirus infection data, which show increased viral replication with intensification of immunosuppression. 96 This observation suggests differing mechanisms of viral clearance between these 2 pathogens, which has not been elucidated. Diagnosis of hMPV disease is confounded by several factors. First, persistent detection of the virus in nasopharyngeal aspirates is reported in up to 85% of asymptomatic HSCT and lung recipients. 96, 98 No long-term respiratory sequelae in Emerging Respiratory Infections in Transplantation persistently infected patients have been noted. 98 Second, primary infection is nearly universal by age 5 years, necessitating a 4-fold increase in antibody titer or seroconversion to establish a diagnosis in adults. 87 Third, although isolation of hMPV with standard cell culture techniques is the definitive method of detection, it is technically difficult, as the virus does not grow efficiently in traditional cell lines used for viral isolation. 87 PCR is the most widely used method of detection of hMPV but largely limited to research investigation. 87 Fourth, although nasopharyngeal aspirates are easily obtainable, detection is less sensitive than in bronchoalveolar lavage specimens. 95 No agent has been approved to treat hMPV in immunocompromised hosts, but because of the close clinical correlation to RSV, similar therapies have been used. 99 A combination of intravenous ribavirin and immunoglobulin has been successful in the treatment of an HSCT recipient. 88, 99 Intravenous ribavirin treatment has been used in a lung transplant recipient after isolated respiratory symptoms progressed to systemic disease and shock despite inhalational treatment. After repeat bronchoalveolar lavage specimens tested negative by PCR, therapy was discontinued. 88 With increasing reports in the transplant literature of hMPV causing disease, it would be prudent to include hMPV in the differential diagnosis of respiratory infections, especially in winter months. Early diagnosis of hMPV infection may reduce injudicious use of antibiotics and invasive diagnostic investigations and promote appropriate infection control practices to prevent nosocomial spread. 94 Lymphocytic choriomeningitis virus (LCM) is an RNA arenavirus. Serologic surveys estimate that 5% of the US population has been infected but remained asymptomatic or had only mild self-limited infection. 102, 103 LCM in immunocompromised individuals, however, can cause an acute febrile illness with fatal dissemination. [102] [103] [104] Posttransplant infections present as an acute, nonspecific febrile illness, often with abdominal symptoms that frequently progress to severe illness. Diagnosis is made by serologic testing for anti-LCM IgG or IgM antibodies, isolation of the virus from blood or cerebral spinal fluid, and immunohistochemical staining of tissue specimens or PCR. 102, 103 Infection occurs from either direct or indirect exposure to aerosolized rat urine or excrement of the common house mouse, the natural host for the virus. 102, 103 Human-to-human transmission has also been documented from mother to fetus and via donor organs to recipients. [102] [103] [104] Among the clusters of LCM transmission by donor organs, 12 of 13 recipients died of multisystem organ failure, and the lone surviving patient responded to ribavirin therapy and reduction of immunosuppression. [102] [103] [104] Interestingly, none of the donors responsible for transmission had clinical signs of infection, none had IgG or IgM antibodies to LCM, and only one had an identified rodent exposure. No known treatment trials have been reported. Ribavirin use is based on in vitro viral susceptibility, but the effectiveness of this therapy and need to reduce immunosuppression remains unclear. Diagnosis of lymphocytic choriomeningitis is difficult. Current assays to detect LCM are notably insensitive, with frequent false-negative test results during donor screening. 102, 103 Lack of accurate and sensitive diagnostics for LCM necessitate rapid 2-way communication between organ procurement organizations and transplantation centers to help identify clustering of patient infections stemming from a common donor. A corona virus causes the severe acute respiratory syndrome (SARS) associated with an outbreak in the Toronto area linked to an index case of a traveler from Hong Kong. Several SARS cases diagnosed by PCR of bronchoalveolar lavage samples occurred in 2003 among solid-organ and HSCT recipients. In 2 cases, despite treatment with ribavirin and reduction of immunosuppression, rapid, fatal progression to respiratory failure ensued. 1, 105 One allogeneic bone marrow recipient survivor was treated with oral prednisolone and ribavirin. 106 Subsequently, a risk stratification tool initially used for donor screening of SARS based on hospital exposure, clinical symptoms, imaging studies, and contact history was developed. 1,105 A modified version was later implemented for potential recipients. This screening protocol highlights the need for high clinical suspicion and early initiation of specific diagnostic testing with existing serologic tests or PCR methods, if available. Respiratory infections in transplantation medicine will continue to pose significant obstacles with associated detrimental effects on morbidity and mortality. The high morbidity and mortality observed from emerging infections stem from protean manifestations of disease, which delay diagnosis as well as appropriate diagnostic and therapeutic interventions. Early institution and maintenance of antimicrobial therapy is often restricted by toxicity and interactions with necessary immunosuppressive drugs. Also, limited data on effective antimicrobial regimens exist, with most therapeutic strategies based on anecdotal experiences. Despite the introduction of newer antimicrobials, infections continue to emerge, especially among transplantation recipients. The interaction of several additional factors including transplant type, surgical technique, underlying metabolic defects, epidemiologic exposures, extent and nature of immunosuppression, and prior antimicrobial use contribute to development of infection. Technological advances have improved diagnostic techniques and modalities to define few new, previously uncharacterized pathogens. Innovations have also enabled definitive genotypic distinctions of pathogens formerly characterized exclusively by phenotypic differences. Finally, the transplant population has experienced increasing numbers, intensification of immunosuppressive regimens, and prolonged survival. Clinicians should focus on prevention of infections if at all possible, consider a broad but rational range of causes of infections in patients presenting with respiratory symptoms and perform early interventional procedures such as bronchoscopy with bronchoalveolar lavage and/or transbronchial biopsy or surgical biopsy as clinically indicated for adequate diagnostic sampling while maintaining awareness of the potential for multidrug resistance. Emerging viral infections in transplant recipients Nocardia infection in heart-lung transplant recipients at Alfred Hospital Nocardia infection in lung transplant recipients Nocardiosis following solid organ transplantation: a single-centre experience Pulmonary nocardiosis in heart transplant recipients: treatment and outcome Challenges in the diagnosis and management of Nocardia infections in lung transplant recipients Risk factors, clinical characteristics, and outcome of Nocardia infection in organ transplant recipients: a matched casecontrol study Clinical and laboratory features of the Nocardia spp. based on current molecular taxonomy Taxonomy of Nocardia species Nocardia infection in lung transplant recipients Pulmonary nocardiosis after lung transplantation: CT findings in 7 patients and review of the literature Nocardial infections in the immunocompromised host: A detailed study in a defined population Infectious complications among 620 consecutive heart transplant patients at Stanford University Medical Center Successful management of disseminated Nocardia transvalensis infection in a heart transplant recipient after development of sulfonamide resistance: case report and review Disseminated Nocardia transvalensis infection: an unusual opportunistic pathogen in severely immunocompromised patients Infections due to Nocardia transvalensis: clinical spectrum and antimicrobial therapy Disseminated Nocardia transvalensis infection resembling pulmonary infarction in a liver transplant recipient Update on management of patients with Nocardia infection Rapid genetic identification system of mycobacteria Nontuberculous mycobacteria. I: Multicenter prevalence study in cystic fibrosis Mycobacterium abscessus infections in lung transplant recipients: the international experience Mycobacterium abscessus empyema in a lung transplant recipient Fatal pulmonary infection due to multidrug-resistant Mycobacterium abscessus in a patient with cystic fibrosis Non-tuberculous mycobacteria in end stage cystic fibrosis: implications for lung transplantation Mycobacterium abscessus in cystic fibrosis lung transplant recipients: report of 2 cases and risk for recurrence Mycobacterium abscessus chest wall and pulmonary infection in a cystic fibrosis lung transplant recipient Successful recovery after disseminated infection due to Mycobacterium abscessus in a lung transplant patient: subcutaneous nodule as first manifestation-a case report Mycobacterium abscessus: an emerging rapid-growing potential pathogen Recent changes in taxonomy and disease manifestations of the rapidly growing mycobacteria Rhodococcus equi: an emerging pathogen Rhodococcus equi pneumonia in a renal transplant patient: a case report and review of literature Rhodococcus lung abscess complicating kidney transplantation: successful management by combination antibiotic therapy Rhodococcus equi infection after liver transplantation Rhodococcus equi and cytomegalovirus pneumonia in a renal transplant patient: diagnosis by fine-needle aspiration biopsy Pulmonary infection caused by Rhodococcus equi in a kidney and pancreas transplant recipient: a case report Rhodococcus equi pulmonary infection in a pancreas-alone transplant recipient: consequence of intense immunosuppression Spontaneous resolution of rhodococcal pulmonary infection in a liver transplant recipient Role of surgery in Rhodococcus equi pulmonary infections Rhodococcus equi infection in transplant recipients: case report and review of the literature Aspergillus infections in transplant recipients Changing epidemiology of systemic fungal infections Aspergillus terreus: an emerging amphotericin B-resistant opportunistic mold in patients with hematologic malignancies Invasive pulmonary aspergillosis due to Aspergillus terreus: 12-year experience and review of the literature Infections due to Aspergillus terreus: a multicenter retrospective analysis of 83 cases In vitro analyses, animal models, and 60 clinical cases of invasive Aspergillus terreus infection Invasive pulmonary aspergillosis with hematological malignancy caused by Aspergillus terreus and in vitro susceptibility of A. terreus isolate to micafungin Experimental pulmonary aspergillosis due to Aspergillus terreus: pathogenesis and treatment of an emerging fungal pathogen resistant to amphotericin B Voriconazole treatment for less-common, emerging, or refractory fungal infections Epidemiology and outcome of infections due to Aspergillus terreus: 10-year single centre experience Risk factors for pulmonary Aspergillus terreus infection in patients with positive culture for filamentous fungi Aspergillus ustus infections among transplant recipients Disseminated Aspergillus terreus infection arising from cutaneous inoculation treated with caspofungin Primary cutaneous infection by Aspergillus ustus in a 62-year-old liver transplant recipient Breakthrough disseminated Aspergillus ustus infection in allogeneic hematopoietic stem cell transplant recipients receiving voriconazole or caspofungin prophylaxis Invasive mold infections in allogeneic bone marrow transplant recipients Primary cutaneous aspergillosis caused by Aspergillus ustus following reduced-intensity stem cell transplantation Use of lung resection and voriconazole for successful treatment of invasive pulmonary Aspergillus ustus infection Invasive aspergillosis caused by Aspergillus ustus: case report and review Disseminated aspergillosis caused by Aspergillus ustus in a patient following allogeneic peripheral stem cell transplantation Serum Aspergillus galactomannan antigen testing by sandwich ELISA: practical use in neutropenic patients Cutaneous Aspergillus ustus in a lung transplant recipient: emergence of a new opportunistic fungal pathogen Invasive aspergillosis of the hand caused by Aspergillus ustus: a case report Cerebral aspergillosis caused by Aspergillus ustus following orthotopic heart transplantation: case report and review of the literature Successful treatment of simultaneous pulmonary Pseudallescheria boydii and Aspergillus terreus infection with oral itraconazole Diagnosis and successful treatment of fusariosis in the compromised host Fusarium infections of the skin Fusarium infection in hematopoietic stem cell transplant recipients Fusarium infection after solid-organ transplantation Primary pulmonary involvement of Fusarium solani in a lung transplant recipient Disseminated Fusarium solani infection with endocarditis in a lung transplant recipient In vitro activity of two echinocandin derivatives, LY303366 and MK-0991 (L-743,792), against clinical isolates of Aspergillus, Fusarium, Rhizopus, and other filamentous fungi Fusarium infections in immunocompromised patients Posaconazole as salvage treatment for invasive fusariosis in patients with underlying hematologic malignancy and other conditions Infection in solid organ transplant recipients in a tertiary medical center and review of the literature Clinical significance of Scedosporium apiospermum in patients with cystic fibrosis Infection with Scedosporium apiospermum and S. prolificans Infections due to Scedosporium apiospermum and Scedosporium prolificans in transplant recipients: clinical characteristics and impact of antifungal agent therapy on outcome Pathology of hyalohyphomycosis caused by Scedosporium apiospermum (Pseudallescheria boydii): an emerging mycosis Scedosporium/Pseudallescheria infections. Semin Respir Scedosporium apiospermum fungemia in a lung transplant recipient Treatment of scedosporiosis with voriconazole: clinical experience with 107 patients Scedosporium apiospermum (Pseudoallescheria boydii) infection in lung transplant recipients Epidemiology and outcome of Scedosporium prolificans infection, a review of 162 cases Pulmonary scedosporium infection following lung transplantation In vitro drug interaction modeling of combinations of azoles with terbinafine against clinical Scedosporium prolificans isolates Disseminated Scedosporium apiospermum infection in renal transplant recipient: long-term successful treatment with voriconazole: a case report Human metapneumovirus infection in adults Successful outcome of human metapneumovirus (hMPV) pneumonia in a lung transplant recipient treated with intravenous ribavirin Diagnosis of human metapneumovirus infection in immunosuppressed lung transplant recipients and children evaluated for pertussis Human metapneumovirus in lung transplant recipients and comparison to respiratory syncytial virus A newly discovered human pneumovirus isolated from young children with respiratory tract disease A prospective study comparing human metapneumovirus with other respiratory viruses in adults with hematologic malignancies and respiratory tract infections Human metapneumovirus in a haematopoietic stem cell transplant recipient with fatal lower respiratory tract disease Respiratory failure associated with human metapneumovirus infection in an infant posthepatic transplant Impact of human metapneumovirus and human cytomegalovirus versus other respiratory viruses on the lower respiratory tract infections of lung transplant recipients Human metapneumovirus infection in lung transplant recipients: clinical presentation and epidemiology Frequency of human metapneumovirus infection in hematopoietic SCT recipients during 3 consecutive years Long-term study on symptomless human metapneumovirus infection in hematopoietic stem cell transplant recipients Human metapneumovirus infection in a hematopoietic transplant recipient Human metapneumovirus infection in a hematopoietic stem cell transplant recipient with relapsed multiple myeloma and rapidly progressing lung cancer Brief communication: fatal human metapneumovirus infection in stem-cell transplant recipients Brief report: Lymphocytic choriomeningitis virus transmitted through solid organ transplantation-Massachusetts Transmission of lymphocytic choriomeningitis virus by organ transplantation A new arenavirus in a cluster of fatal transplantassociated diseases Severe acute respiratory syndrome (SARS) in a liver transplant recipient and guidelines for donor SARS screening An indolent case of severe acute respiratory syndrome