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Case Report

Use of Cyclosporine and Itraconazole as Palliative Treatment for Proventricular Dilatation Disease in Psittacine Birds

by
Laura M. Kleinschmidt
1,2,
Sharman M. Hoppes
2,
Jeffrey M. B. Musser
3,
Ian Tizard
3 and
J. Jill Heatley
2,*
1
Saint Louis Zoo, One Government Drive, Saint Louis, MO 63110, USA
2
Department of Small Animal Veterinary Clinical Sciences, Texas A&M University, College Station, TX 77845, USA
3
Department of Veterinary Pathobiology, MS #4456, Texas A&M University, College Station, TX 77843, USA
*
Author to whom correspondence should be addressed.
Vet. Sci. 2025, 12(5), 459; https://doi.org/10.3390/vetsci12050459
Submission received: 21 February 2025 / Revised: 16 April 2025 / Accepted: 28 April 2025 / Published: 12 May 2025
(This article belongs to the Section Veterinary Biomedical Sciences)
Versions Notes

Simple Summary

Proventricular dilatation disease (PDD) is a neurologic syndrome of birds caused by the infectious agent Psittacine Bornavirus (PaBV). Clinical disease may be based on T-cell-mediated immune response to PaBV within the central and peripheral nervous system. Clinical disease may result in multiple neurologic disorders and life-threatening morbidity. Treatment of PDD with antivirals and non-steroidal anti-inflammatories has thus far been non-curative and unsuccessful long-term. Cyclosporine is an immunosuppressant drug that decreases cell-mediated immune responses by inhibiting T-cell proliferation and decreasing cytokine production. In avian species, cyclosporine is a potent immunosuppressant with T-cell-specific action. A pilot study performed in PaBV-infected cockatiels showed increased weight gain and a lack of morbidity or mortality following experimental PaBV infection and cyclosporine treatment at 10 mg/kg orally every 12 h. In this case series of six psittacine birds affected by PDD, cyclosporine at this dose alleviated or reduced clinical signs in multiple birds without severe sequelae. Further prospective research is indicated to better evaluate cyclosporine use in birds with PDD.

Abstract

Proventricular dilatation disease (PDD) is a neurologic syndrome of birds caused by the infectious agent Psittacine Bornavirus (PaBV). Clinical disease may be based on the T-cell-mediated immune response to PaBV within the central and peripheral nervous system, similar to Borna disease virus, a closely related mammalian virus. Lymphoplasmacytic infiltrations may occur in ganglia, nerve plexuses, peripheral nerves and the central nervous system of the infected bird. Clinical disease may result in multiple neurologic disorders and life-threatening morbidity. Treatment of PDD with antivirals and non-steroidal anti-inflammatories has thus far been non-curative and unsuccessful long-term. Cyclosporine is an immunosuppressant drug that decreases cell-mediated immune responses by inhibiting T-cell proliferation and decreasing cytokine production. In avian species, cyclosporine is a potent immunosuppressant with T-cell-specific action. A pilot study performed in PaBV-infected cockatiels showed increased weight gain and a lack of morbidity or mortality following experimental PaBV infection and cyclosporine treatment at 10 mg/kg orally every 12 h. In this case series of six psittacine birds affected by PDD, cyclosporine at this dose alleviated or reduced clinical signs in multiple birds without severe sequelae. Itraconazole was used concurrently in these cases to prevent secondary fungal infections during immunosuppression but may have had a synergetic effect when used in combination with cyclosporine. Further prospective research is indicated to better evaluate cyclosporine use in birds with PDD. However, these preliminary clinical findings suggest that cyclosporine and itraconazole administration is a treatment option for palliation of PDD in psittacine patients, especially those refractory to other treatments.

1. Introduction

This clinical case series evaluated cyclosporine as a palliative treatment for birds affected by proventricular dilatation disease (PDD). PDD is a neurologic syndrome of birds caused by the infectious agent Psittacine Bornavirus (PaBV) [1,2,3,4,5,6]. PaBV is a neurotropic virus with a predilection for gastrointestinal ganglia, but it can affect many nerves throughout the body [7]. Over 80 species of psittaciformes as well as passeriformes, coliiformes, pelecaniformes, piciformes, anseriformes, falconiformes, and accipitriformes have been reported to be infected with avian bornaviruses [2,3,6,8,9,10,11,12,13,14,15]. Proposed transmission routes include vertical transmission (eggs) and horizontal transmission of viral particles in respiratory secretions, feather dust, feces and urine [2,3,6,16,17]. The presence of PaBV does not always result in clinical disease; the time between infection and presentation of clinical disease is variable, and some avian species appear to clear of or tolerate the virus without clinical disease [2-3Clinical disease is thought to be based on the T-cell-mediated immune response to the presence of PaBV within the nervous system, similar to Borna disease virus (BDV), a closely related mammalian virus with a similar immune-mediated mechanism of disease production [2,3,6,14,18,19,20]. Lymphoplasmacytic infiltrates develop in affected enteric ganglia, enteric nerve plexuses, brachial, vagus, optic, and sciatic nerves and/or the central nervous system [2,11,13,14,18,19,20,21]. Clinical disease presentations include gastrointestinal and neurologic clinical signs [2,6,11,13]. Gastrointestinal clinical signs include regurgitation, delayed crop emptying, poor gastrointestinal motility, enteric bacterial overgrowth or dysbiosis, diarrhea, voluminous or gas-containing stools, and, rarely, the passage of undigested seeds or other foodstuffs [2,6,19]. Neurologic clinical signs include behavioral changes such as seizures or tremors, blindness, and ataxia manifested as gait change or inability to grip or perch normally [3,6,19,22]. Definitive diagnosis of PDD may be challenging antemortem. Classic diagnostic findings include a dilated proventriculus and/or other portions of the gastrointestinal tract on lateral radiograph, PaBV-positive RT-PCR (reverse transcriptase polymerase chain reaction) testing of cloacal swabs, positive serological reaction, and/or histopathologic lymphoplasmacytic infiltrates within the myenteric ganglia and nerves of the central, peripheral, or autonomic nervous system on necropsy [2,6,11,13,14,18,19,20,23]. Treatment of PDD has thus far been non-curative and unsuccessful long-term, although treatment modalities are still being actively investigated [2,3,20,24]. Antiviral therapies have not been demonstrated to be effective in the treatment of PDD [2,3,20]. Non-steroidal anti-inflammatories (NSAIDs) including meloxicam and celecoxib have been used historically with variable results [2,3,24]. To limit the progression of disease and decrease the morbidity and mortality associated with PDD in avian patients, new treatment options must be explored.
Cyclosporine decreases cell-mediated immune responses by inhibiting T-cell proliferation via calcineurin inhibition of growth cycles and decreasing cytokine production [3,25]. Cyclosporine has been used to treat immune-mediated and inflammatory diseases in veterinary medicine, including inflammatory bowel disease, atopic dermatitis, perianal fistulas, hemolytic anemia, thrombocytopenia, and uveitis [25]. Known side effects of cyclosporine include leukopenia secondary to immunosuppression, hepatotoxicity, and nephrotoxicity [25]. Cyclosporine has been used in experimental treatment of BDV in rats with promising results [7,26,27,28]. Cyclosporine is a proven potent immunosuppressant with T-cell-specific action in avian species that has been used to induce immunosuppression at doses up to 100 mg/kg intramuscularly in gallinaceous birds [29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44]. Bioavailability of cyclosporine varies based on the route of administration and formulation; thus, compounded formulations of cyclosporine cannot be recommended based on possible bioavailability differences [25]. In Pekin ducks, a pharmacokinetic study revealed that cyclosporine was metabolized and cleared faster than in a comparative mammalian species; therapeutic plasma levels in the bloodstream were maintained for less than 8 h following 10 mg/kg intravenous dosing [45]. Thus, increasing the dose to at least 60 mg/kg every 24 h or decreasing the dose interval to every 6–8 h was recommended for cyclosporine use in avian species [45]. Unfortunately, a high dose, 3–4 times daily dosing [45], is not reasonable for most parrot owners to accomplish and could interfere with the human–parrot bond. Additional pharmacokinetic or pharmacodynamics studies to assess the best dosing protocols have not been performed in avian species.
Immunosuppressant effects of cyclosporine could increase the likelihood of fungal infections such as aspergillosis; thus, in the clinical case series presented, low-dose itraconazole was given prophylactically. Itraconazole increases plasma concentrations of cyclosporine via the induction of liver enzymes (cytochrome P450) in animals, as occurs for other azole drugs in vitro [25,36]. Azole antifungals have been used in dogs to reduce the necessary dose of cyclosporine [25]. Therefore, itraconazole may have a synergistic effect when used in combination with cyclosporine [15,46,47]. Itraconazole was chosen based on commercially available liquid formulations, but other antifungal azole drugs may also be acceptable for this purpose as well as aspergillosis prophylaxis. However, the synergism of any azole drugs with cyclosporine is ultimately unproven in birds.
The purpose of this clinical case series was to evaluate cyclosporine treatment as a palliative treatment for birds affected with PDD, which has been pursued at the Texas A&M University Zoological Medicine Service for more than twenty years. In large part, the dosing protocols shared here were based on a pilot study in experimentally PaBV-infected cockatiels; healthy adult cockatiels had been inoculated by intramuscular and oral routes with the M24 strain of PaBV genotype 4, previously shown to induce PDD in cockatiels [22,24]. These studies were reviewed by the Texas A&M University Institutional Animal Care and Use Committee and conducted based on approved animal use protocol #2011-024. Control, meloxicam, and cyclosporine treatment groups of four parrots each were either not treated, dosed with 0.5 mg/kg meloxicam orally every 12 h, or dosed with cyclosporine at 10 mg/kg orally every 12 h, respectively. Birds treated with meloxicam became ill within the first month, showing clinical signs of weight loss, regurgitation, and lethargy, and died or were euthanized based on the severity of symptoms on days 61, 78, 95 and 117 [24]. Necropsy findings were consistent with PDD including poor body condition and an enlarged proventriculus and ventriculus [24]. Mild encephalitis and ganglioneuritis, comprised of lymphoplasmacytic infiltrates, occurred within the ventriculus and heart; most of the 15–19 tissues tested were RT-PCR-positive for PaBV in the four birds. Based on these unexpected results in the meloxicam-treated PaBV-infected birds, a separate control study in four healthy cockatiels was performed with the same dose of meloxicam but without inoculation with PaBV [24]. These birds lacked signs of illness throughout the study and, on necropsy, had occasional lymphoid foci in the liver but lacked lesions suggestive of PDD. One bird was PCR-positive for PaBV only within the adrenal gland. In the experimentally PaBV-infected cockatiels, control and cyclosporine-treated birds remained clinically healthy during the study. No untoward clinical signs were noted during cyclosporine treatment, and treated and control birds were euthanized at 153 and 151 days for necropsy, respectively. Compared to the control group, birds that received cyclosporine had increased in weight by the end of the study. Three cyclosporine-treated birds had subtle histologic lesions of PDD on necropsy, and all 19 tissues tested were RT-PCR-positive for PaBV in all birds. Of the four control birds, one bird had histologic lesions consistent with PDD, and in two birds, 19 of 19 tissues sampled were PCR-positive for PaBV, while the remaining two birds had 6 out of 19 tissues PCR-positive for PaBV. In this pilot study, neither meloxicam nor cyclosporine decreased the organ PCR-positive rate for cockatiels infected with PaBV, but cyclosporine was effective in preventing the manifestation of PDD clinical signs [22,24]. Based on these preliminary studies, cyclosporine and itraconazole treatment was used as a palliative option in birds with severe clinical signs of PDD that had not responded to treatment with NSAIDs. We report six of these cases below, which were exempted from ethical review based on Texas A&M University College of Veterinary Medicine guidelines and based on alignment with ARRIVE 2.0 guidelines for transparent reporting of animal case studies.

2. Case Series

This report describes clinical cases in which cyclosporine was used to treat proventricular dilatation disease (PDD)—associated clinical signs in multiple large psittacine birds at Texas A&M University Zoological Medicine Service (TAMU-ZMS). The cyclosporine used in these cases was the commercially available liquid formulation Atopica® (Elanco Animal Health, IN, USA). Signalment, clinical presentation, flock history, diagnostics, treatment, and outcomes are presented below. Cloacal swab testing via PaBV RT-PCR and serologic testing was performed at the Schubot Exotic Bird Health Center Laboratory (Table 1); all RT-PCR-positive cases were genotype PaBV-4. Parameters monitored for health assessment before and during treatment in each case are provided in Table 1 and Table 2. For all cases, a complete blood count (CBC) and plasma biochemistry panel were recommended before beginning treatment, and at two weeks, 1, 2, and 3 months after beginning treatment to monitor white blood cell counts and organ function. Medical progress checks to include CBC and plasma biochemistries were then recommended quarterly during the course of treatment. However, financial concerns may have limited client compliance with these recommendations.

2.1. Case 1: Green Wing Macaw (Ara Chloropterus)

A juvenile intact male green wing macaw was donated to Schubot Exotic Bird Health Center in 2007 with a history of exposure to birds affected by PDD. At the time of donation, the individual showed no clinical signs of PDD, was RT-PCR- and Western-blot-negative, and was otherwise apparently healthy. Crop biopsy findings were consistent with a diagnosis of PDD. In 2011, the macaw became acutely ill. During a routine exam three weeks prior to the onset of clinical illness, the patient had been clinically normal and serologically negative for PaBV. The patient was hospitalized, and supportive care was initiated. Injectable meloxicam (0.5 mg/kg BID, Metacam, Boehringer Ingelheim, St. Joseph, MO 64506, USA) was given for two days without any clinical effect. On day three, cyclosporine (10 mg/kg PO BID, Atopica, Elanco, Greenfield, IN 46140, USA) and celecoxib (10 mg/kg PO SID, Celebrex, Pfizer, New York, NY 10017, USA, compounded by Texas A&M University Small Animal Hospital Pharmacy, College Station, TX 77845, USA) were initiated. These treatments were continued for three days, but the patient continued to decline despite treatment. The patient was ultimately euthanized and submitted for necropsy. Necropsy results revealed histologic evidence of PDD in multiple organs including the gastrointestinal tract. Serology testing and RT-PCR of samples taken at necropsy were positive for PaBV.

2.2. Case 2: Umbrella Cockatoo (Cacatua Alba)

A 4-year-old intact female umbrella cockatoo presented to TAMU-ZMS in June 2013 with the complaint of increased chick-like behavior progressing to regurgitation and weight loss. The patient had been exposed to two other birds in the household that had died from PDD in March and May of 2013. A cloacal/choanal swab was RT-PCR-positive for PaBV. The patient was started on cyclosporine (10 mg/kg PO BID), itraconazole (2.5 mg/kg PO SID, Sporanox, Titusville, NJ 08560, USA), and meloxicam (0.5 mg/kg PO BID, Metacam, Boehringer Ingelheim, St. Joseph, MO 64506, USA). The owner gave the medications for approximately 1 month but felt that the medications had not made a clinical difference. However, clinical examination after the treatment period revealed no change in body condition score and an increase in body weight compared to the start of treatment. Based on concerns about quality of life, the owner elected for humane euthanasia. On necropsy, histologic lesions consistent with PDD were present in the gastrointestinal tract, but no lesions were noted in other systems. The brain was PaBV RT-PCR-positive.

2.3. Case 3: Umbrella Cockatoo (Cacatua Alba)

A 4-year-old intact female umbrella cockatoo was donated to the Schubot Exotic Bird Health Center in 2007 based on exposure to PaBV. The patient was clinically ill on arrival, with a low body condition score and occasional regurgitation. Histological examination of crop biopsy revealed histologic lesions consistent with PDD. RT-PCR and serology were also positive for PaBV at the time of presentation. The patient was started on meloxicam (0.5 mg/kg PO BID). The individual was also hand-fed to maintain weight once to twice daily as needed for four years. In 2009, the patient developed a dilated proventriculus on radiographs. In June 2010, the patient presented to TAMU thin, regurgitating, depressed, dehydrated, and losing weight. Complete blood count revealed leukocytosis, and a review of radiographic images revealed persistent proventricular dilatation. The administration of cyclosporine (5 mg/kg PO BID), itraconazole (2.5 mg/kg PO SID), and marbofloxacin (5 mg/kg PO SID, Zeniquin, Zoetis, Parsippany, NJ 07054, USA) was initiated. The patient improved over the next three weeks, with returned appetite, discontinued regurgitation, and weight gain. A recheck of the complete blood count revealed a decrease in leukocytosis, and a review of radiographic images showed decreased proventricular dilation. Five weeks following the start of cyclosporine, the patient presented again to TAMU weak, dehydrated, and regurgitating. Supportive care was initiated, but the patient died two days following presentation. Necropsy revealed PDD lesions through the GI tract and brain. PaBV RT-PCR of multiple organs at the time of necropsy was positive for PaBV. Although the patient had an active case of PDD, gout also severely affected the heart and pericardial sac and was widely disseminated. A combination of chronic administration of non-steroidal anti-inflammatories, long-term hand-feeding formulas, and the initiation of cyclosporine may have contributed to renal damage and, thus, the development of gout and ultimately death in this patient.

2.4. Case 4: Green Wing Macaw (Ara Chloropterus)

A juvenile intact male green wing macaw, a sibling of case 1, was donated to Schubot Exotic Bird Health Center in 2007 with a history of exposure to birds affected by PDD. At the time of donation, the individual was RT-PCR- and serology-positive for PaBV; histologic findings from crop biopsy were consistent with PDD. In 2011, caretakers noted that the patient was not performing his normal training behaviors. Radiographs revealed mild enlargement of the proventriculus. Despite the administration of meloxicam (0.5 mg/kg PO BID) for two weeks, improvement was not evident. Therefore, cyclosporine (10 mg/kg PO BID) and itraconazole (2.5 mg/kg PO SID) were initiated. The patient showed improvement to its normal attitude within 3 days of the initiation of treatment, gained weight, and the proventricular size was reduced on a recheck of the radiographs. After 3 months, the medications were discontinued. The patient continues to thrive at the Schubot Exotic Bird Health Center at the time of this publication.

2.5. Case 5: Red-Fronted Macaw (Ara Rubrogenys)

An 8-year-old intact male red-fronted macaw presented to his referring veterinarian in 2012 with a history of being PaBV RT-PCR-positive for several years and a history of multiple PDD associated deaths within his flock over several years. He was started on celecoxib (10 mg/kg PO SID) and was well for one year. However, he presented to TAMU in 2013 when he became depressed, began regurgitating occasionally, and had a decreased appetite. Radiographs revealed a dilated proventriculus. Plasma biochemistries and CBC failed to reveal abnormalities. The body condition score was graded a 1+ out of 5. Cyclosporine (10 mg/kg PO BID) and itraconazole (2.5 mg/kg PO SID) were initiated. The owner reported that within one week of starting treatment, the patient was eating better, gaining weight, and returned to its normal attitude and behaviors. After 3 months of treatment, both medications were prescribed to be administered once daily. Since that time, the patient has been on cyclosporine at a 10 mg/kg daily dose prophylactically. The owners have declined discontinuation of the medications. The patient continues to thrive at home at the time of this publication.

2.6. Case 6: Blue and Gold Macaw (Ara Ararauna)

A 5-year-old intact male blue and gold macaw presented to TAMU in January 2015 with a three day history of regurgitation and lethargy. This individual was part of a flock affected by PaBV, with two PDD-associated deaths in macaw cage-mates and a PaBV positive sun conure currently housed in the same room. Radiographs revealed an enlarged proventriculus. Plasma biochemistry and complete blood count abnormalities were limited to increased concentrations of creatine kinase. We attributed these increased concentrations to handling and intramuscular midazolam injection prior to sample collection. Testing for ABV via RT-PCR was negative at this time, likely based on intermittent viral shedding. The owner declined any further diagnostics. Based on the history of PDD-associated flock deaths and likelihood of PaBV exposure, the owner elected to move forward with treatment for suspected PDD. The macaw was started on meloxicam (0.5 mg/kg PO BID), enrofloxacin (21.4 mg/kg PO SID, Baytril, 50 mg/mL oral suspension, compounded by Texas A&M University Small Animal Hospital Pharmacy, College Station, TX 77845, USA), itraconazole (2.5 mg/kg PO SID), and cyclosporine (10 mg/kg PO BID). The owner noted the resolution of regurgitation and an improved attitude within 2 weeks of treatment initiation. Cycloporine dosing was reduced to once daily for 1–2 months following the initiation of treatment. The recheck examination and complete blood cell count approximately 3 months after the initiation of treatment revealed mild leukopenia as the only significant abnormality. Therefore, the cyclosporine dosing interval was increased to every 48 h. The patient continues to thrive with no recurrence of symptoms at the time of writing this paper.

3. Discussion

This case series suggests cyclosporine as a viable palliative treatment option for PDD in psittacine birds. In six clinical cases of psittacine birds affected by PDD, the use of cyclosporine reduced clinical signs and may have prevented the progression of PDD in multiple birds. Proventricular dilatation disease was diagnosed antemortem in these cases via a combination of RT-PCR PaBV-positive cloacal swabs, consistent clinical signs, lack of evidence of other etiologies of clinical signs, positive serological response, history of exposure to PaBV, and/or crop biopsy. PDD diagnosis was confirmed on necropsy for cases 1–3. Although histopathologic lesions confirm a diagnosis of PDD, antemortem crop biopsies may not be positive in all PDD cases, as lymphoplasmacytic infiltrate more commonly affects the proventriculus and ventriculus [2,6,11,13,14,18,19,20]. Thus, a clinical or presumptive diagnosis may be reached using the aforementioned criteria, as well as standard screening tests of CBC, biochemistry panel and fecal cytology and culture, in order to treat affected birds prior to death. Psittacine bornavirus is intermittently shed via the gastrointestinal tract and can thus be detected via RT-PCR testing. A PDD-affected bird may be negative on a single or multiple RT-PCR screening test as viral shedding is not known to be predictive for disease (PDD). In addition, based on our clinical experience, even clinical disease does not guarantee viral shedding of PaBV. Repeated PCR tests and serological testing are recommended if a bird is suspected of having PDD but is negative on initial PCR.
Antifungals were used to prevent secondary fungal infections based on the concern of immunosuppression in these cases, though the synergetic effect when used in combination with cyclosporine cannot be ruled out [25]. Long-term usage of itraconazole should be considered judiciously to discourage the development of itraconazole resistance. Cyclosporine at 10 mg/kg orally every 12 h was administered long-term in several cases without significant side effects. Side effects directly attributable to cyclosporine treatment appear to be limited to mild leukopenia in one case. Non-steroidal anti-inflammatory drugs (NSAIDs) were used in conjunction with cyclosporine and itraconazole in some cases to reduce secondary inflammatory prostaglandins rather than treat the primary immune-mediated disease process directly. Despite favorable pharmacokinetic data for some, we continue to find only anecdotal support in the literature to support NSAIDs for the treatment of PDD [48]. Controlled studies of PaBV infections have continued to fail to find support for the therapeutic use of NSAIDs for the mitigation of PDD or ABV infection [49,50]. Three cases (cases 3–5) that became refractory to treatment with an NSAID alone responded positively to cyclosporine and itraconazole treatment. Antibiotics were used on a case-by-case basis at clinician discretion and were generally based on flora overgrowth of the GI tract as diagnosed by culture or fecal cytology.
Three parrots (cases 4–6) underwent treatment and continue to thrive at the time of writing this paper. Of the three parrots that are no longer living, only one was completely non-responsive to treatment (case 1). Because this patient only received cyclosporine for 3 days, therapeutic or toxic levels were unlikely to have been achieved. The second case improved clinically based on weight gain after one month of treatment. However, because the owner elected for euthanasia, long-term effects of cyclosporine treatment in that patient are unknown. The third case initially responded to treatment, with normalized clinical status prior to decline five weeks after the initiation of treatment. Interestingly, the histopathologic exam of tissues at necropsy indicated gout as the cause of death in this patient, rather than PDD. The authors postulate that gout occurred in this patient due to long-term use of high-protein hand feeding formulas (intended for short-term use in the young of debilitated birds), chronic use of NSAIDs (which can cause renal toxicity in birds at high doses) [51], and the addition of cyclosporine, which is a nephrotoxin in mammals [25,52].
Psittacine birds affected by PDD and their owners and caretakers are faced with the possibility of what should be a long-lived companion species suffering a slow downward spiral of a wasting and neurologic disease ending in death. Despite excellent medical and husbandry management, parrots suffering from PDD may have refractory clinical illness. We suggest that, while better prevention and treatment continue to be researched, cyclosporine is a valid palliative option for management of this disease in severely clinically affected parrots. However, close clinical monitoring must be maintained during treatment due to the risks of side effects (leukopenia, hepatotoxicity, nephrotoxicity), which may increase in likelihood with chronic use of these drugs. Limitations of this study include the limited sample size, variations in individual case management, and lack of available pharmacokinetic studies of cyclosporine in Psittaciformes. Based on limited trials, increased PCR positivity and shedding of PaBV may occur after cyclosporine treatment. Additional research is recommended to further evaluate the use of cyclosporine in birds with PDD. Pharmacodynamic, pharmacokinetic, and toxicity studies would be useful to further evaluate therapeutic levels and dosing intervals of cyclosporine in parrots.

Author Contributions

Conceptualization, I.T. and J.J.H.; methodology I.T., J.J.H. and J.M.B.M.; investigation, J.J.H., J.M.B.M., S.M.H. and L.M.K.; data curation, L.M.K.; writing—original draft preparation, L.M.K.; writing—review and editing, L.M.K., J.J.H., S.M.H., I.T. and J.M.B.M. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

This study was exempt from ethical review under Texas A&M University College of Veterinary Medicine guidelines, as it aligns with the ARRIVE 2.0 guidelines for transparent reporting of animal case studies.

Informed Consent Statement

Written informed consent has been obtained from the owners of the involved animals to publish this paper.

Data Availability Statement

The raw data supporting the conclusions of this article will be made available by the authors on request.

Acknowledgments

The authors would like to thank Jennifer Perkins, LVT and the Schubot Exotic Bird Health Center for their support of this work.

Conflicts of Interest

The authors declare no conflicts of interest.

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Table 1. Health parameters of psittacine patients undergoing cyclosporine and itraconazole treatment.
Table 1. Health parameters of psittacine patients undergoing cyclosporine and itraconazole treatment.
CaseSurvival TimeCyclosporine DurationBody Condition ScorePatient Body Weight (g)Proventriculus: Keel RatioPaBV
RT-PCR		Gross NecropsyHistopathological Lesions of PDD
NumberDays (d)PrePostPrePostPrePostPrePostLesionsBrainGastrointestinalKidney
13 d3 d321080NDNDND+PDDNDYes ND
242 d42 d22.54024400.72ND++PDDNoYesNo
382 d82 d21.54904320.720.5++Gout, PDDYesYesND
41825 d92 d24132016600.70.5++NANANANA
5913 d913 d1+44224820.640.52++NANANANA
6400 d400 d3.54117011800.84NDNANANANA
Abbreviations: ND, not determined; NA, not applicable; +, Positive; −, Negative; Pre, values determined prior to cyclosporine treatment; Post, values determined after cyclosporine treatment; PDD, lesions of proventricular dilatation disease (PDD) were present; Gout, lesions of gout were present; Yes, histopathological lesions of PDD were present; No, no histopathological lesions of PDD were present. Survival Time, length of survival in days post-initiation of cyclosporine treatment at time of writing this paper.
Table 2. Complete blood count and plasma biochemical parameters before and after cyclosporine treatment in parrots affected by proventricular dilatation disease. Cases 5–6 include the most recent post-initiation of treatment hematological and biochemical values.
Table 2. Complete blood count and plasma biochemical parameters before and after cyclosporine treatment in parrots affected by proventricular dilatation disease. Cases 5–6 include the most recent post-initiation of treatment hematological and biochemical values.
Case
Number		Sample TimeWBC TotalHeteroLymphMonoEosBasoPCVASTBAUAGLUTPALBGLOB
Cells × 103/µLCells/µL%U/Lµmol/Lmg/dLmg/dLg/dLg/dLg/dL
1037.125.22810.75937137137145152<358.62723.92.71.1
2026.73.20421.627160226726734135533.52782.81.81.0
42 d17.810.5027.12178002898<355.02812.11.40.7
3026.720.0254.005186926753440132<3518.32162.51.41.2
47 d17.813.7063.5605340040106<359.92502.41.41.0
4030.521.6557.0151220061040205<354.42913.63.20.4
1890 d20.215.9583.232808202045426<353.23104.13.30.8
5024.517.8854.410196024524545171<357.73034.72.42.3
560 d12.910.9651.419387012945140<357.32953.22.40.9
6016.310.4324.075163001634986<352.52753.62.51.2
94 d6.74.2212.144201013448173<354.12824.43.31.1
Abbreviations: WBC, leukocyte; Hetero, heterophil; Lymph, lymphocyte; Mono, monocyte; Eos, eosinophil; Baso, basophil; PCV, packed cell volume; AST, aspartate aminotransferase; BA, bile acids; UA, uric acid; GLU, glucose; TP, total protein; ALB, albumin; GLOB, globulin; Sample time, evaluated prior to (T = 0) and after cyclosporine treatment (days (d)) following initiation of treatment.
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MDPI and ACS Style

Kleinschmidt, L.M.; Hoppes, S.M.; Musser, J.M.B.; Tizard, I.; Heatley, J.J. Use of Cyclosporine and Itraconazole as Palliative Treatment for Proventricular Dilatation Disease in Psittacine Birds. Vet. Sci. 2025, 12, 459. https://doi.org/10.3390/vetsci12050459

AMA Style

Kleinschmidt LM, Hoppes SM, Musser JMB, Tizard I, Heatley JJ. Use of Cyclosporine and Itraconazole as Palliative Treatment for Proventricular Dilatation Disease in Psittacine Birds. Veterinary Sciences. 2025; 12(5):459. https://doi.org/10.3390/vetsci12050459

Chicago/Turabian Style

Kleinschmidt, Laura M., Sharman M. Hoppes, Jeffrey M. B. Musser, Ian Tizard, and J. Jill Heatley. 2025. "Use of Cyclosporine and Itraconazole as Palliative Treatment for Proventricular Dilatation Disease in Psittacine Birds" Veterinary Sciences 12, no. 5: 459. https://doi.org/10.3390/vetsci12050459

APA Style

Kleinschmidt, L. M., Hoppes, S. M., Musser, J. M. B., Tizard, I., & Heatley, J. J. (2025). Use of Cyclosporine and Itraconazole as Palliative Treatment for Proventricular Dilatation Disease in Psittacine Birds. Veterinary Sciences, 12(5), 459. https://doi.org/10.3390/vetsci12050459

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