Specific clinical manifestations of Nocardia: A case report and literature review.

Nocardiosis is a rare bacterial infection of either the lungs (pulmonary) or body (systemic) that usually affects immunocompromised individuals. It is caused by Gram-positive, aerobic actinomycetes of the Nocardia genus. Multiple high-density sheet shadows in both lungs along with nodules or cavities are the most common presentations of nocardiosis, whereas a large pulmonary mass is considered to be rare. However, there is no specificity in the clinical manifestation of the disease. Therefore, isolation and identification of Nocardia strains is the only reliable diagnostic method. The present study describes the cases of two male patients of Asian descent with nocardiosis. Chest computed tomography scans showed a suspected tumor mass in both patients. Microscopic analysis and culturing of tissue samples obtained using a bronchoscope detected the presence of Nocardia wallacei. Neither patient showed signs of immunosuppression. The present study aimed to improve the understanding of lung nocardiosis and demonstrated that pulmonary nocardiosis should be suspected in the case of non-immunocompromised patients with a large mass in the lung. Furthermore, a review of the literature on infection with Nocardia was conducted.

Introduction

Nocardiosis is an rare, opportunistic bacterial infection caused by Nocardia species that predominantly affects the respiratory tract of immunocompromised patients (1). Nocardia species are Gram-positive, actinomycetes. The genus Nocardia includes >80 species, of which >30 have been shown to cause disease in humans. Lung nocardiosis is the most common type of nocardiosis, although the infection can spread through the bloodstream to other areas of the body (2). Due to the rise in invasive surgical techniques, immunosuppressive therapies, and acute respiratory distress syndrome, the incidence of nocardiosis has been increasing (3–5).

The common clinical manifestation of pulmonary nocardiosis include a cough and fever (6). In addition, 50% of pulmonary nocardiosis cases are complicated by skin or intracranial dissemination (6). Chest X-ray or computed tomography (CT) imaging of the lungs typically show pleural effusion, masses, infiltrates, cavities and nodules (6). However, since its clinical manifestations lack specificity, it is easily misdiagnosed, and isolation and identification of Nocardia strains is considered the only reliable diagnostic method. Treatment of nocardiosis typically involves antibiotics: A previous study demonstrated that Nocardia species were sensitive to sulfonamide, amikacin, cefotaxime, ceftriaxone, minocycline, fluoroquinolones and linezolid (6).

The present study aimed to improve the understanding of lung nocardiosis by assessing two cases of lung nocardiosis in patients admitted to the Beijing Shijitan Hospital (Beijing, China), and by carrying out a review of the literature on infection with Nocardia. The present study was approved by the Medical Ethics Commitee of Beijing Shijitan Hospital, Capital Medical University (Beijing, China). Written informed consent was obtained from the patients.

Case reports

Case 1

The first patient was a 52-year-old male who presented with paleness, a feeling of tiredness for 6 months and a fever for 7 days. The patient was admitted to the Beijing Shijitan Hospital on July 5th, 2011 with no history of medical illnesses. Blood tests showed that the white blood cell (WBC) count was 4.09×109/l (normal range, 3.5–9.5×109/l), the blood platelet (PLT) count was 68×109/l (normal range, 125–350×109/l), and the hemoglobin (Hb) levels were 73 g/l (normal level, 130–175 g/l). Results of an indirect immunofluorescence assay (EUROBlotMaster II; EUROIMMUN Medical Diagnostics (China) Co., Ltd., Beijing, China) were positive for anti-nuclear antibodies (1:160; speckled pattern) and negative for anti-extractable nuclear antigen antibodies. The bone marrow biopsy was normal. Considering the high probability of immune-associated hematocytopenia, the patient was treated with 40 mg/day oral prednisone (Zhejiang Xianju Pharmaceutical Co., Ltd., Xianju, China) once daily and discharged from the hospital on August 25th, 2011.

After 2 months, the routine blood tests of the patient showed no improvement in WBC count, and the patient was subsequently treated with prednisone combined with 400 mg/day ciclosporin A (North China Pharmaceutical Co., Ltd., Shijiazhuang, China). After 4 months, no improvement in WBC counts were observed. The patient was admitted again to the hospital presenting with fever (maximum temperature of 40°C) that had lasted for several days. There was no rigor, cough, expectoration, dyspnea or diarrhea. The patient felt progressively more tired and had a poor appetite. When no changes were observed following treatment with anti-infective therapy (0.5 g oral levofloxacin once daily; Daiichi Sankyo Pharmaceutical Co., Ltd., Shanghai, China) for 7 days, the patient was discharged and visited the hospital as an outpatient.

On visiting the hospital as an outpatient, the temperature of the patient was 38.6°C. The patient was malnourished and his mucocutaneous zone was slightly pale, with no yellowing or cyanosis. The patient's breathing sounded harsh, but there were no rhonchus, rales or pleural friction sounds. The heart and abdomen were normal.

A chest CT scan (Fig. 1) showed a shadow of effusion and consolidation. Following admission, routine blood tests showed that the WBC count was 6.3×109/l, red blood cell (RBC) count was 1.64×1012/l (normal range, 4.3–5.8×1012/l), Hb levels were 50 g/l, PLT count was 45×109/l, and serum tests showed that albumin (ALB) levels were 31.1 g/l (normal range, 40–55 g/l), lactate dehydrogenase levels were 896 U/l (normal range, 40–240 U/l) and serum C-reactive protein (CRP) levels were 137 g/l (normal range, 0–5 g/l). Results of the tumor marker test, hepatitis B virus (HBV) test (Abbott Trading Shanghai Co., Ltd., Shanghai, China), tubercle bacillus antibody test (Mp Biomedicals Asia Pacific Pte., Ltd., Singapore, purified protein derivative (PPD; used to diagnose latent tuberculosis) test (5 TU; Chengdu Institute of Biology, Chinese Academy of Sciences, Sichuan, China) and blood and sputum culture tests were negative.

Figure 1.

Chest computed tomography scan (July 4th, 2011) of case 1 showed a shadow of effusion and consolidation in the upper right lung.

Considering that the patient most likely suffered from a bacterial and fungal infection as a result of long-term use of glucocorticoids and immunosuppressive agents, the patient received once daily (q.d.) intravenous (IV) administration of 400 mg fluconazole (Beit Lunan Pharmaceutical, Co., Ltd., Shandong, China), 20 mg amphotericin B (Shanghai Asia Pioneer Pharmaceuticals Co., Ltd., Shanghai, China) and 0.4 g moxifloxacin (Bayer, Shanghai, China), and twice daily (b.i.d.) IV injection with ceftizoxime (Shenzhen Zhijun Pharmaceutical, Co., Ltd., Guangzhou, China). The temperature of the patient fluctuated between 37.5 and 38.5°C. A subsequent chest CT scan revealed that the sheet shadow in the upper right lung had enlarged and contained cavitation (Fig. 2). Routine blood tests demonstrated that the WBC count was 5.3×109/l, neutrophils were at 75.7% (normal range, 40–75%), RBC count was 2.63×1012/l, Hb levels were 83 g/l and PLT count was 43×109/l; therefore, the treatment was changed to IV injection with 4.5 g piperacillin (Shijiazhuang Pharmaceutical Group, Co., Ltd., Shijiazhuang, China) and tazobactam (CSPC Zhongnuo Pharmaceutical, Co., Ltd., Shijiazhuang, China) b.i.d. The patient presented with a high fever (maximum temperature of 40.2°C) on July 22nd, 2011. The patient also presented with dual ankle pain and an occasional cough with expectoration, in the absence of any rigor. The sputum culture showed Nocardia asteroides and the treatment was adjusted as follows: Piperacillin and tazobactam combined with 0.96 g b.i.d. oral sulfamethoxazole (Beijing Shuguang Pharmaceutical Factory, Xian, China) and 200 mg b.i.d. oral voriconazole (Pfizer Deutschland GmbH, Berlin, Germany).

Figure 2.

Chest computed tomography scan (July 15th, 2011) of case 1 showed the sheet shadow in the upper right lung had enlarged and contained cavitation.

A bronchoscopy revealed that the bronchial mucosa in the apicoposterior segment of the upper right lung lobe was slightly congested and edematous, and contained yellow purulent secretions. Following irrigation, there was no hemorrhage or neoplasm in the bronchial lumen. The biopsy results indicated some epithelioid cell granuloma, small-foci infarction, and nuclear fragmentation in the tissue (Fig. 3). A subsequent chest CT scan showed progressive pneumonia and that the shadow of consolidation had markedly enlarged and a cavity had formed (Fig. 4).

Figure 3.

Biopsy results for case 1 indicated epithelioid cell granuloma, small-foci infarction, and nuclear fragmentation in the tissue. (Hematoxylin staining; magnification, ×200).

Figure 4.

Chest computed tomography scan (August 4th, 2011) of case 1 showed progressive pneumonia and enlargement of the shadow of consolidation along with cavity formation.

After reviewing the results of the drug sensitivity tests, treatment was changed to IV injection with 3.0 g cefoperazone and sulbactam (Pfizer Deutschland GmbH) once every 12 h (q12h) and 0.96 g four times a day (q.i.d.) oral sulfamethoxazole for 4 days, followed by 500 mg q12h imipenem and cilastatin (Hangzhou MSD Pharmaceutical Co., Ltd., Hangzhou, China) combined with 0.96 g q.i.d. oral sulfamethoxazole. The temperature of the patient fluctuated between 36.2 and 39.2°C, and his cough and expectoration did not improve. The patient received repeated bronchoscopy examinations and bronchoalveolar lavage, after which his temperature gradually returned to normal. After 11 days of treatment, the chest CT scan revealed the large mass in the upper right lung lobe had decreased with fewer cavities in it and that the pneumonia had improved (Fig. 5). The patient continued treatment with 0.96 g three times a day (t.i.d.) oral sulfamethoxazole and 0.1 g t.i.d. oral cefdinir (Jinkang Pharmaceuticals, Co., Ltd., Tianjin, China) following discharge from the hospital on August 25, 2011. One month follow-up following discharge, the patient had no fever, cough, or expectoration. Another chest CT scan showed that the lesion in the right lung had been markedly resorbed (Fig. 6).

Figure 5.

Chest computed tomography scan (August 15th, 2011) of case 1 showed the large mass in the upper right lung lobe had decreased with fewer cavities and pneumonia had improved.

Figure 6.

Chest computed tomography scan (September 9th, 2011) of case 2 showed the lesion in right lung had markedly decreased and the cavity disappeared.

Case 2

The second patient was a 37-year-old male who complained of having an intermittent cough and expectoration for >1 month. The patient also located a cervical neck mass during that time. The patient was admitted to the Beijing Shijitan Hospital on July 3rd, 2014 with no history of previous medical illnesses, although he had been exposed to occupational dust as a carpenter for 3 years.

The patient suffered from a cough and had a small amount of white sputum without obvious inducement prior to the intermittent cough and heavier expectoration 1 month later. There was no fever, night sweats, fatigue, chest tightness or chest pain. The patient subsequently located a 4×6 cm mass on the right side of his neck. A neck ultrasound revealed a hyperechoic mass with no echo in the right side of the neck. Within a few days, the patient felt a progressive increase in the size of the mass and noticed yellow phlegm in his sputum. A chest CT scan showed central occupying lesions in the upper and the middle right lung with obstructive pneumonia. The lesions were considered to be malignant and had metastasized into the bilateral lungs. The scan showed cancerous lymphangitis, multiple lymph node metastasis and large amounts of pleural effusion in the right lobe (Fig. 7). Thoracentesis was performed and a biopsy of the neck mass was conducted, guided by ultrasound. The fluid culture showed growth of Nocardia, and the biopsy showed inflammatory granuloma and abscesses (Fig. 8). Bronchoscopy revealed only a few ciliated pseudostratified epithelial cells, RBCs, and individual segmented cells. The patient received treatment as follows: A total of 2 g b.i.d. IV drip cefminox (Meiji Seika Kaisha, Ltd., Tokyo, Japan) for 10 days and 2 tablets b.i.d. sulfamethoxazole trimethoprim (Beijing Double-Crane Pharmaceutical, Co., Ltd., Beijing, China) orally for 2 days. Following treatment, the neck mass was only marginally reduced.

Figure 7.

Chest computed tomography scan (June 25th, 2014) of case 2 showed central lesions in the upper right lung and middle lung mass with obstructive pneumonia. The lesions were considered to be malignant and had metastasized into the bilateral lungs. The scan showed cancerous lymphangitis, multiple lymph node metastasis, and a large amount of pleural effusion in the right lobe.

Figure 8.

Neck mass biopsy for case 2 showed inflammatory granuloma and abscesses showed inflammatory granuloma and abscesses. (Hematoxylin staining; magnification, ×200).

The temperature of the patient was 36.5°C, pulse was 75 bpm, respiration was 20 bpm, and blood pressure was 125/75 mmHg. The skin and mucous membranes were not pale or yellow. The patient had a 4×6 cm mass on the right side of the neck, abnormal skin color, and elevated skin temperature. The left lung sounded clear, whereas the right breath sound was lower than the left, although the bilateral lung sounds indicated no rhonchus, bubbles or pleural friction. The heart rate was 75 bpm, with a normal heart rhythm and no cardiac murmur. The abdomen of the patient was soft but not tender.

Following admission to the Beijing Shijitan Hospital, routine blood tests revealed that the WBC count was 8.91×109/l, neutrophil count was 80.4%, Hb levels were 88 g/l, and PLT count was 45×109/l. Serum tests demonstrated that the ALB levels were 32.6 g/l, the alkaline phosphatase levels were 288 U/l (normal range, 45–125 U/l), and γ-glutamyl transferase levels were 90 U/l (normal range, 10–60 U/l). Serum CRP levels were 98 g/l, the erythrocyte sedimentation rate was 77 mm/h (normal, <20 mm/h) and D-dimer levels were 2,276.0 ng/ml (normal, <243 ng/ml). The 1,3-β-D glucan detection test (Beijing Jin Shanchuan Technology Development, Co., Ltd., Beijing, China), HBV test, tubercle bacillus antibody test, PPD test (5 TU) and sputum culture were negative. Pleural fluid examination showed that the Reye's reaction was positive, specific density was 1.025, WBC count was 1.8×109/l, multinucleated cells were at 9% and monocytes were at 91%. The patient then received an abdominal CT enhanced scan that showed multiple metastases in the right lobe of the liver (Fig. 9), indicating that the liver was involved in the disease. The final diagnosis was disseminated Nocardia infection (involving the skin, lung, liver and mediastinum).

Figure 9.

Abdominal computed tomography enhanced scan (July 7th, 2014) of case 2 revealed multiple metastases in the right lobe of the liver.

Following second admission to the Beijing Shijitan Hospital, the patient was administered two tablets b.i.d. oral sulfamethoxazole trimethoprim combined with 2 g q.i.d. IV drip ceftriaxone (Bristol-Myers Squibb Pharmaceutical, Co., Ltd., New York, NY, USA). The neck mass was reduced and the patient's temperature returned to normal. Another chest CT scan revealed that the lesions in the upper and the middle right lung had markedly resorbed (Fig. 10).

Figure 10.

Chest computed tomography scan (July 9th, 2014) of case 2 showed the lesions in the upper and the middle right lung had markedly resorbed.

Discussion

Nocardia are Gram-positive, slow growing, aerobic filamentous bacteria that are widely distributed in the soil. Nocardia belong to the Actinobacteria class (2). The morphology of Nocardia is similar to that of Actinomyces israelii; however, the end of the hyphae do not show coliform dilatation, and Nocardia are weakly positive for modified Kinyoun's acid-fast staining. The hyphae is able to agglomerate to form actinomycetic grains. To date, no Nocardia infections have been reported to spread between humans; therefore, nocardiosis is considered an acquired infection that spreads predominantly through the respiratory tract (7). Occasionally, nocardiosis can cause hematogenous dissemination (7), but it is rare that soft tissue infection is caused directly by cutaneous injury (2). The prevalence of nocardiosis has specific seasonal variations and geographical distribution (8).

Of the cases of nocardiosis, 30% are caused by opportunistic bacteria, which demonstrates that nocardiosis is an exogenous and opportunistic infection (9). The most common bacterial species associated with human nocardiosis are N. asteroides and Nocardia brasiliensis (2), and N. asteroides in particular (10). Impaired cell-mediated immunity is an important risk factor for nocardiosis, and the majority of patients with the infection have chronic diseases or abnormal immune function (11). A previous study reported that >50% of patients with nocardiosis were immunocompromised from various conditions (12). Common causes of nocardiosis were chronic pulmonary diseases, including chronic obstructive pulmonary diseases, human immunodeficiency virus (HIV) infections (2), neoplastic disease, diabetes mellitus (10), alcohol abuse, use of systemic corticosteroids and use of immunosuppressive agents (13,14). Case 1 in the present study had a long history of systemic corticosteroid and immunosuppressive drug use, both of which are risk factors for nocardiosis.

Clinical manifestations of Nocardia lack specificity (15). In China, 68.8% of patients with nocardiosis have pneumonia in the early stages (9). Lung nocardiosis often manifests as chest pain, coughing, sputum, dyspnea, fatigue and loss of appetite (9). Some patients present with hemoptysis (16) or subacute pneumonia (7). In a previous study, non-HIV-infected patients with lung nocardiosis presented with elevated WBC counts and neutrophil ratios (17). Endobronchial nocardiosis is less common, and it is difficult to distinguish lung Nocardia in patients with normal immune function but with pneumonia and lung abscesses (17). According to a previous report, Nocardia in the lungs of patients with normal immune function is associated with bronchial stone disease (18). A previous study demonstrated that 50% of lung nocardiosis infections were able to spread to extrapulmonary tissues, predominantly via the bloodstream but also through the lymphatic system (19). When hematogenous dissemination occurs, patients may present with brain abscesses, subcutaneous abscesses, pericarditis or other symptoms (10,16). Case 2 in the present study lacked typical respiratory symptoms upon examination, and presented with only a mild cough and a small amount of white phlegm.

The imaging characteristics of lung nocardiosis in both cases lacked specificity, which means the disease is pleomorphic. The most common imaging characteristics are pulmonary opacities, nodules and/or a mass, and some patients may have symptoms combined with pleural effusion (9). The pathological manifestations of nocardiosis are pyogenic or necrotic changes, and the typical pathological change is liquefaction necrosis with abscess formation; therefore, low-density areas or cavities often appear in the pulmonary opacities and nodules, which is an important manifestation that is also characteristic of bacterial pneumonia (20). Consistent with a previous report (13), the most common CT manifestations of pulmonary nocardiosis in the present study were air-space consolidation and nodules. The patients complained of only a fever without a cough and sputum during the course of the disease, although chest radiographic imaging showed pulmonary opacities, predominately present in the right lung, that gradually progressed into large areas of consolidation with cavity formation to a diameter of 15 cm. These characteristics were not consistent with the typical pathological manifestations. The initial treatment strategy had no positive effect on the patient and his condition worsened. Following treatment with an effective antibiotic therapy together with physical therapy, the patient did not show any signs of the disease being disseminated throughout the body via the bloodstream.

The clinical manifestations of lung nocardiosis lack specificity, which leads to misdiagnosis. Testing for pathogens in order to positively identify Nocardia is the only method for accurate diagnosis of this disease (21). Any of the following protocols can be used as test specimens: Sputum, pus, pleural effusion, puncture fluid, bronchoalveolar lavage fluid or drainage from a pulmonary abscess (9). Nocardia species are aerobic bacteria that are able to grow into visible colonies within 2–6 days in common medium at 37°C and under aerobic conditions using CO2 (9). Nocardia bacteria grow slowly; therefore, if the required time frame of 4 weeks is not provided to culture the bacteria, it can remain undetected. Use of the correct medium, prolonged culture time, and multiple cultures may improve the rate of positive results (22). In case 1, when there was no improvement following anti-infection treatment, the patient was given several bronchoscopy tests. The results from the sputum cultures revealed an astro-nocardiosis infection; these cultures had an important role in timely clinical treatment.

The treatment of nocardiosis should include the use of specific antibiotics, incision and drainage, surgical excision of the lesion and protocols to improve the immune system of the host (23,24). The selection of a specific treatment depends on numerous factors, including the host, severity of disease, lesion site, immune status and toxicity of the drug to organs (9). Sulfa drugs are the best choice for treating nocardiosis (2). The advantage of sulfa drugs is their high oral bioavailability, improved penetration and improved clustering in the lungs and central nervous system (6). Patients who are allergic to sulfa drugs, cannot tolerate them, or suffer toxic reactions from them, can choose amoxicillin-clavulanate potassium or minocycline as alternatives (25). A previous study demonstrated that Nocardia are sensitive not only to the above-mentioned drugs, but also to amikacin, ceftriaxone, and imipenem (2). For patients with pulmonary or skin nocardiosis, sulfa drug monotherapy is highly effective; however, for patients with severe immune suppression, such as organ transplant patients or patients with systemic nocardiosis, combination therapy with a polyantibiotic is suggested, such as a combination of imipenem with third-generation cephalosporins or amikacin (7,16). In vitro drug-sensitivity tests have demonstrated that Nocardia are also sensitive to linezolid (26), although clinical data on this is lacking.

Total mortality rates from Nocardia infections are high (31%) (27), and the in-hospital mortality rate is ~20% (16). The prognosis is closely associated with the diagnosis and treatment time frame, the severity of the underlying condition of the patient, and whether there is dissemination through the bloodstream. The important predictive factors of a poor prognosis are the early and frequent use of systemic corticosteroids and systemic infection (5). The majority of patient mortalities occur as a result of disseminated systemic infections, brain abscesses, or infections resulting from bacterial strains resistant to sulfa drugs (16). The early isolation and identification of Nocardia strains, and the timely and effective treatment of nocardiosis with sulfa drugs, may help to reduce patient mortality.

In summary, nocardiosis is an exogenous and opportunistic bacterial infection. The lungs are the most common target of nocardiosis and patients with hypoimmunity are more susceptible to infection (1). The clinical manifestations and image characteristics of pulmonary nocardiosis lack specificity (15), such that the disease may be misdiagnosed as other infections, including tuberculosis, bacterial pneumonia, lung abscesses, and pulmonary aspergillosis. The following patients are highly susceptible to nocardiosis and should be regularly tested: i) Patients with compromised immunity, such as HIV infection; ii) organ transplant recipients; iii) patients with long-term history of systemic corticosteroids or immunosuppressive agent use; iv) patients with tumors following chemotherapy; v) patients with chronic lung disease, diabetes or other chronic diseases; and vi) patients with a pulmonary infection following conventional anti-infective therapy, anti-tuberculosis treatment or anti-fungal therapy, which is complicated by lesions in the central nervous system, soft tissue or skin (28). Antibiotic therapy combined with aspiration and drainage by bronchoscopy is an effective treatment strategy for pulmonary nocardiosis. It is important to improve the recognition and understanding of Nocardia infection to reduce misdiagnosis, implement an effective and timely anti-infection therapy and decrease the mortality rates of nocardiosis.