Three cases of recalcitrant Paecilomyces keratitis in Southern California within a short period

Paecilomyces is a ubiquitous filamentous fungus commonly found in soil and air [1]. Paecilomyces rarely causes disease in humans; however, there have been increasing cases of infection in recent years [2]. Infection gives rise to a variety of clinical presentations, including but not limited to, keratitis, endophthalmitis, and cutaneous infections [2]. Established risk factors for infectious keratitis include contact lens wear [2], trauma to ocular surface [3], and chronic topical corticosteroid use [3]. The outcomes of fungal keratitis vary, and treatment is usually initiated with topical antifungal drugs [4].

The first line of treatment is topical natamycin [4]. The Mycotic Ulcer Treatment Trial (MUTT I) demonstrated the efficacy of natamycin over voriconazole in preventing corneal perforation and penetrating keratoplasty in smear or culture-proven fungal keratitis [4]. Intracameral amphotericin B has also been reported as an effective treatment in deep fungal corneal ulcers [5]. Despite consistent topical and intracameral antifungal therapy, treatment may fail. Oral posaconazole has demonstrated efficacy in treating resistant cases [6]. Even with these available treatments, infection with Paecilomyces has been associated with poor outcomes: 60% of the eyes required keratoplasty and 19%–35% resulted in enucleation of the eye [7, 8]. In this case series, we report the clinical progression of three patients with Paecilomyces keratitis, using in vivo confocal microscopy and histopathology to substantiate our clinical and microbiologic findings.

Paecilomyces is a rare but emerging cause of severe infections in humans, including keratitis [1]. Associated risk factors for Paecilomyces keratitis include previous ocular surgery, environmental trauma, and contact lens usage. Most cases of Paecilomyces keratitis are attributable to the P. lilacinus species [1]. The P. lilacinus species has become increasingly prevalent as a causal agent of infections and belongs to the genus Purpureocillium [9].

P. lilacinus has been reported to transmit through the skin, indwelling catheters, or inhalation, with a tropic propensity for ocular structures. Interestingly, both in our report and the existing literature, contemporaneous P. lilacinus keratitis cases appear to present in geographically distinct clusters, suggesting that environmental factors play a role in pathogenesis [10]. Although the exact source of P. lilacinus has not been identified in our report, the observation that all three patients presented with the same infection during the same time of year suggests a shared etiology. Possible common sources, such as soil from gardening, water damage, and recent travel were explored, but no commonality was determined. Nevertheless, the patients shared characteristics that may have predisposed them to infection, including immunocompromised status, systemic disease, and usage of topical steroids. The clinical diagnosis of P. lilacinus infection is based on positive fungal culture and histopathology of corneal lesions. P. lilacinus can also be identified through its ability to sporulate in infected tissue [1, 10].

In the present study, IVCM was used in conjunction with histopathological assays and microbiologic testing to determine morphological changes in the cornea consistent with fungal keratitis. IVCM is a non-invasive imaging modality used for direct visualization of potential causative pathogens and associated cellular changes in real-time, on living organisms [11]. In patients with fungal keratitis, IVCM can be used to image corneal infiltrates with deep stromal involvement that are not accessible through scrapings alone. With a sensitivity and specificity of 67% and 100%, respectively, IVCM is a reliable and accurate way to diagnose fungal keratitis [12]. A prior study demonstrated a correlation between confocal and histopathologic findings in Paecilomyces spp. Keratitis [13]. Similarly, in our study, real-time confocal microscopy identified features of a filamentous fungus like spores and septate hyphae, corroborating positive fungal culture in all 3 cases. Furthermore, clinical resolution of infectious keratitis was supported by lack of confocal identification of fungal elements. This was further confirmed by histopathology in 2 of the 3 cases that underwent optical PKP after a long period of quiescence.

Timely management of fungal keratitis remains challenging. Negative or delayed culture results can impede accurate diagnosis [14]. Even with an accurate diagnosis, antifungal medications poorly penetrate the cornea. In the event of P. lilacinus-mediated keratitis, urgent medical intervention is needed to maintain corneal integrity and prevent the infection from spreading. In the discussed cases, the usage of steroids early in the treatment course may have negatively affected ocular outcomes. Our cases indicate that aggressive medical and surgical therapy is indicated given the recalcitrant nature of keratitis caused by this organism.

The Mycotic Ulcer Topical Treatment Trial I demonstrated that topical natamycin was more effective than topical voriconazole in preventing corneal perforation and therapeutic corneal transplants. It also showed significantly better visual acuity and ability to clear culture positivity after 6 days in patients receiving topical natamycin [15]. Unfortunately, P. lilacinus demonstrates resistance to conventional antifungal medication and patients often experience poor outcomes [1] despite aggressive medical and surgical intervention. Several reports have noted high-dose oral posaconazole as an effective medical option for fungal keratitis recalcitrant to first-line antifungals [16‐18]. Although posaconazole has shown significant improvement on a case-by-case basis, it can cause serious side effects, including gastrointestinal complaints, headaches [18], elevated liver function tests [19], and rarely hepatotoxicity and cardiotoxicity [20]. All three patients in the present study were initially prescribed oral voriconazole, then switched to Posaconazole 600 mg for 2 weeks. The dose was lowered to 300 mg after improvement was noted. Treatment with high-dose oral posaconazole led to clinical resolution of infection that was not achieved with oral voriconazole combined with topical and local injections of antifungals. However, two of our patients experienced severe hypertension, which did not resolve with reduced dosing, prompting the discontinuation of posaconazole.

We have reported three cases of recalcitrant Paecilomyces keratitis presenting to the same institution within a short period. Recognizing the potential for corneal Paecilomyces infection and adverse systemic side effects in response to antifungal therapy is crucial to ensure prompt medical attention and appropriate treatment for these patients. Guidelines discussing the optimal treatment for primary Paecilomyces corneal infections should include points regarding the management of therapy-related side effects. Ophthalmologists should be instructed to recognize the signs and symptoms of fungal infections and associated therapies. In our series, the microbiologic diagnosis of fungal organism as a cause of infectious keratitis was corroborated by in vivo histology obtained by IVCM imaging and confirmed with histopathologic findings from the excised corneal buttons.