Invasive aspergillosis in a user of inhaled cocaine: rhinosinusitis with bone and cartilage destruction

INTRODUCTION

Aspergillosis is an infection caused by saprophytic fungi of the genus Aspergillus, which typically occurs in immunosuppressed patients^1,2. The main routes of entry are the respiratory tract, skin, cornea, and ear, and the infection may be localized or disseminated by contiguity or vascular invasion^2,3. Patients with an impaired immune system or with disrupted anatomical and physiological barriers are at a high risk of developing the invasive form of the disease, characterized by fungal hyphae in tissues, which is associated with high mortality rates⁴.

Rhinosinusitis caused by Aspergillus is clinically similar to bacterial sinusitis. It rarely affects immunocompetent patients^1,5. It was described in young individuals with predisposing factors to fungal colonization and proliferation, such as atopia; nasal polyps; and a history of allergic rhinitis, asthma, and recurrent sinusitis². In more severe cases, tissue necrosis and destruction may occur^2,5. In a recent study regarding the distribution of different Aspergillus species in chronic sinus invasion, it was observed that Aspergillus flavus was the most predominant species worldwide, with the exception of the United States, where Aspergillus fumigatus was found to predominate⁶.

Cocaine abuse may lead to chronic rhinosinusitis; it can result in soft tissue and bone destruction, due to ischemia secondary to vasoconstriction, chemical irritation, trauma, changes in mucociliary mechanism, secondary infections, and local decrease in humoral and cellular immunity^7,8. Cocaine users are predisposed to bacterial and fungal infections, such as aspergillosis. We report a case of rhinosinusitis with severe nasal damage and cutaneous involvement, secondary to cocaine inhalation, in an immunocompetent patient diagnosed with locally invasive aspergillosis (IA).

CASE REPORT

A 28-year-old female patient from Rio de Janeiro, who was a user of inhaled cocaine for the last six months, reported an erythematous lesion in the nose, which evolved with septal ulceration and perforation. The patient could not estimate the time of lesion emergence; she had no fever or other symptoms at presentation and had no history of rhinosinusitis.

A clinical examination revealed perinasal erythema and extensive damage of the columella, septum, and nasal floor, which was covered with a greenish-yellow material (Figures 1A and B). A biopsy sample obtained from the nasal floor showed extensive necrosis with several hyphae when analyzed with hematoxylin-eosin stain and Grocott’s methenamine silver stain (Figure 2A). Culture analysis using Sabouraud’s agar allowed the growth of an A. flavus colony (greenish-yellow, with a velvet texture, and transparent reverse). Microscopic analysis of the fungal colony showed long and grouped conidiophores with thick and clear walls. Globous and fertile (phialides) vesicles were observed in virtually all the fields (Figure 2B). Complementary tests, including T cluster of differentiation 4 (CD4)⁺ and CD8⁺ cell counts, showed normal results. Result of the serology test was negative for anti-human immunodeficiency virus (HIV).

FIGURE 1 A: Erythema and infiltration of the nose. B: A green-yellowish material on the nasal floor along with septal ulceration and perforation. 

FIGURE 2 A: Grocott stain analysis of the tissue sample obtained from the nasal floor. Numerous, septated, regular, branching hyphae are observed within the necrotic tissue, devoid of inflammation (100× magnification). B: Left. A greenish-yellow colony, velvet texture, transparent reverse. Right. Microscopic analysis shows long and grouped conidiophores with thick and clear walls. Globous and fertile (phialides) vesicles are observed. C: Computed tomography of the face: extensive damage of the nasal septum and turbinates, except for the superior turbinate, and thinning and erosion of the septum and the internal maxillary sinus wall, communicating with the left nasal antrum and nasal fossa. 

Computed tomography (CT) of the face revealed extensive damage of the nasal septum and turbinates, except for the superior turbinate, and thinning and erosion of the septum and the internal maxillary sinus wall, communicating with the left nasal antrum and nasal fossa. Opacity and edema of the mucosa were observed in the frontal, ethmoidal, and maxillary sinuses (Figure 2C).

Treatment consisted of itraconazole 400mg/day for 10 months and surgical debridement. Clinical and radiological improvement was observed in the patient, who later underwent surgical repair of the nasal cavity and achieved good esthetic results (Figure 3).

FIGURE 3 Nasal reconstruction with a skin graft over a silicone prosthesis showing a satisfactory esthetic outcome. 

DISCUSSION

Although chronic invasive fungal rhinosinusitis is uncommon in immunocompetent patients, such cases have been reported, particularly in Sudan and India, where it appears to be relatively common⁹. In Brazil, the few reported cases involved immunosuppressed patients¹⁰. To our knowledge, this is the first case of chronic invasive fungal rhinosinusitis in an immunocompetent Brazilian patient. This patient was a user of inhaled cocaine, and it is possible that cocaine abuse caused bone and cartilage destruction, facilitating fungal penetration².

Few studies have reported the effect of IA on the central portion of the face in immunocompetent individuals^1,2,4,5,11. Thus far, no study has reported its occurrence in relation to cocaine abuse.

Cocaine abuse in combination with the fungal infection led to severe rhinosinusitis and extensive destruction of the bone, internal maxillary sinus wall, cartilaginous and mucosal tissues, as well as invasion of the skin. This destructive effect was facilitated by continued cocaine abuse even after the initial clinical manifestation.

The usual presentation of fungal rhinosinusitis is nasal obstruction, disturbed smell, and postnasal drip associated with a nasal mass or polyp; it may be associated with orbital and intracranial invasion¹⁰.

In this case, IA was diagnosed by histopathologic examination, mycological culture analysis, and CT imaging. Cocaine triggered tissue destruction and probably local immunosuppression, contributing to pathogenic proliferation of opportunistic fungi, such as Aspergillus.

There has been increasing interest in preemptive antifungal therapy, which is defined as treatment that is deferred until an invasive fungal infection (IFI) can be diagnosed on the basis of substantive evidence. Early detection of diagnostic markers of a fungal infection, such as fungal nucleic acids, antigens, antibodies, or cell wall components, is essential in this regard. Galactomannan is an important diagnostic marker used in the diagnosis of IA. Another serum marker commonly used to indicate the presence of IFIs is (1-3)-b-D-glucan (BDG). However, galactomannan or beta-glucan assays are not easily available, and conventional direct microscopy, histopathology, and culture analysis are the only available techniques in most centers for the diagnosis of IA¹⁰.

Both CT and magnetic resonance (MR) images help to determine the clinical diagnosis, recurrence rate, and delineation of the extension of fungal sinusitis as well as in surgery¹⁰. Fungal sinusitis should be considered in all patients with chronic sinusitis, especially when it occurs in association with certain clinical features like intractable symptoms, despite adequate treatment for bacterial sinusitis, allergic rhinitis, asthma, nasal polyposis (non-invasive types) or fever, headache, epistaxis, diabetes, nasal mucosal ulcer, orbital apex syndrome, or proptosis (invasive types). However, the diagnosis of fungal sinusitis depends on direct microscopic examination, culture, and histopathological analysis of tissue or the cheesy material obtained from sinuses^9,10.

In our patient, etiological investigation was performed by fungal and bacterial culture analyses of the greenish-yellow material found on the nasal floor, which was removed by surgical debridement. Hyphae were observed in the tissue sample, and the mycological culture revealed the presence of A. flavus. The CT image showed extensive damage of the nasal septum and turbinates, with some exception.

Oral itraconazole was chosen to manage the patient because the patient was immunocompetent; moreover, it was the only option available for the patient at the hospital where she was treated. Since the initial response was satisfactory, treatment remained unchanged until complete clinical remission. The excellent response to itraconazole further confirmed the presence of a fungal infection. In the literature, even for immunocompetent patients, other therapeutic approaches have been proposed, such as intravenous amphotericin B followed by itraconazole and voriconazole followed by itraconazole¹².

It is possible that the inhalational form of cocaine used by the patient was contaminated with the fungus. We suggest that inhaled cocaine abuse could be one of the predisposing factors of IA in immunocompetent patients.

FINANCIAL SUPPORT

Research performed in Hospital Universitário Pedro Ernesto da Universidade do Estado do Rio de Janeiro(HUPE/UERJ), Rio de Janeiro, Brazil.