- 1Division of Neurology, Department for Small Animals, Vetsuisse Faculty, University of Zurich, Zürich, Switzerland
- 2Division of Radiation Oncology, Department for Small Animals, Vetsuisse Faculty, University of Zurich, Zürich, Switzerland
Introduction: A variety of treatment options have been described for canine meningoencephalitis of unknown origin (MUO). Few studies focused on radiation therapy as a second line immunomodulating treatment, implicating its effective use. However, a standard radiation therapy protocol is lacking, and further research will help to evaluate the effect of different dose regimens.
Methods: Ten dogs diagnosed with MUO based on MRI and CSF findings were prospectively enrolled. The dogs were treated with a shortened whole brain radiation therapy protocol (5 × 4 Gy) in combination with prednisolone. Neurologic changes were quantified using an established scoring scheme. Follow-up MRI and CSF examination was scheduled three months after radiation therapy. Overall survival and time to progression were calculated. Histopathology of the brain was performed in case of death.
Results: Seven dogs were diagnosed de novo and three had a history of relapsing MUO. Neurological status improved in all 10 dogs during radiation therapy, with 4/10 returning to normal shortly after radiation therapy. Three dogs died within the first three months after radiation therapy. At follow-up MRI lesions completely resolved in two dogs, partially resolved in five dogs, and progressed in one dog. After follow-up MRI, dogs were further treated with prednisolone monotherapy (two dogs) and additional immunosuppressant drugs (five dogs). Overall, four dogs showed disease progression, with a mean time to progression of 691 days (95%CI: 396–987) and mean overall survival for all dogs was 723 days (95%CI: 436–1011) (both medians not reached). Histopathology confirmed MUO in three dogs but was suggestive for oligodendroglioma in one dog. Radiation induced side effects were not seen.
Conclusion: Shortened whole-brain radiation therapy could be an additional treatment option for MUO in conjunction to prednisolone, specifically for cases that require rapid relief of symptoms and with relapsing history.
1. Introduction
Meningoencephalitis of unknown origin (MUO) is a common central nervous system (CNS) disease in dogs and considered fatal if left untreated (1–3). While MUO can affect dogs of any breed, sex and age, small, toy and terrier breeds are most commonly affected (4). A large proportion, up to 56%, of affected dogs die or are euthanized, despite aggressive treatment (5). Regardless of the type of treatment, the mortality rate is highest within the first three months after diagnosis and ranges between 26 and 33% (3, 5–7). MUO is believed to be the result of an aberrant immune response against the CNS, but the exact pathomechanism is still incompletely understood (2, 8–10), which prohibits identifying more effective treatment strategies. In general, MUO-treatment bases on immunosuppressing the patient. Glucocorticoids, such as prednisolone are considered a cornerstone of therapy (4). A systematic review by Granger et al. indicated a possible benefit of a second-line immunosuppressive medication (11). Additionally, there is limited data that multi-drug immunomodulation may allow for faster dose-reduction of prednisolone (12), leading possibly to less glucocorticoid-associated side effects. In recent years, researchers have focused on the effect of second line immunosuppressants including azathioprine, cyclosporine, cytosine arabinoside, mycophenolate and others (2, 4). Yet, no preferred immunosuppressive strategy has been identified, mirroring the heterogenicity of the disease, as well as the varying inclusion criteria and drug regimens (4, 11). The remaining high mortality rate within the first months and various adverse effects of medical treatment highlight the need for continuous investigation in MUO treatment strategies.
So far, only three studies, investigated the effect of radiation therapy in conjunction to glucocorticoid treatment on MUO, with a total of 17 dogs (13–15). They demonstrated radiation therapy (RT) in addition to glucocorticoid treatment to be a feasible treatment option with rapid clinical improvement, including dogs refractory to medical therapy (15). However, a standard radiation therapy protocol is lacking as described protocols varied in delivered doses, fractions, and treatment times. Total doses between 30 and 49.5 Gy, divided into fractions of 2.4–4.0 Gy have been investigated.
Herein we wanted to evaluate a short, lower dose whole brain radiotherapy protocol in conjunction to prednisolone treatment in dogs diagnosed with focal or multifocal MUO. We delivered a total of 20 Gy in 4 Gy-fractions over five days. During follow-up, we investigated the outcome after treatment based on clinical-neurologic examinations, as well as MRI and CSF examinations.
2. Materials and methods
This prospective pilot study included 10 dogs with diagnosis of MUO. For the study, dogs were recruited between December 2019 and February 2022 at the Division of Neurology, Vetsuisse Faculty, University of Zurich. For all dogs, owners' informed consent was obtained for treatment and follow-up. Dogs were treated under approval of the Animal Ethics Council of the Canton of Zurich, Switzerland (Permit Number: ZH026/20).
2.1. Case selection
Clinical and neurologic examinations were performed by residency-trained or board-certified veterinary neurologist. In all dogs, complete blood cell count and serum biochemistry was performed.
Diagnosis of MUO was based on previously established inclusion criteria (11). The following inclusion criteria had to be fulfilled (1) evidence of focal or multifocal brain lesions during the neurological examination; (2) abnormal cerebrospinal fluid (CSF) (reference interval: <5 white blood cells (WBCs)/μL and/or total protein: <0.3 g/L, respective abnormal CSF cell differentiation) collected from the cerebromedullary cistern. In case the CSF total protein was determined by a Pandy test, a clear CSF was considered normal. Abnormal protein content was detected by turbidity and rated with maximum “+++”. In case CSF did not prove inflammation, diagnosis had to be confirmed by pathology; (3) relevant infectious diseases ruled out by testing from serum or CSF; (4) evidence of focal or multifocal intra-axial lesions in MRI, according to previously reported features (16–20).
MRI of the brain was performed with a high field scanner (1.5 or 3.0 T). Sequences included at least T2W images in transverse, sagittal and dorsal planes, T2W FLAIR in transverse plane and T1W transverse images acquired pre- and post-contrast medium application. MRIs were reported by a board-certified radiologist and reviewed by a board-certified neurologist.
Based on previously described MR imaging features of granulomatous meningoencephalitis (GME) (2, 16, 19), necrotizing leukoencephalitis (NLE) (2, 16, 21–23) and necrotizing meningoencephalitis (NME) (2, 16, 20, 22, 24) we grouped our cases into these subclassifications of MUO.
Dogs were not included if they presented with optic neuritis or spinal MUO only, or when their CSF analysis revealed eosinophilic or neutrophilic predominance.
Follow-up MRI was scheduled three months after the end of radiation therapy by a 3 Tesla MRI (Philips Ingenia scanner, Philips AG, 8027 Zurich, Switzerland). To allow for accurate comparison between the lesions prior and after radiation therapy, follow-up MRI included at least the same sequences.
2.2. Treatment
Whole-brain radiation therapy was delivered with photons of a 6 MV linear accelerator (Clinac iX, Varian, Palo Alto, California) equipped with a 5-mm leaf-width multileaf-collimator, using intensity-modulated radiation therapy (IMRT). Treatment planning was performed using Eclipse treatment planning software (Varian Oncology Systems, Palo Alto, California), applying AAA-algorithm (10.0.28). Radiation was planned isocentrically, with heterogeneity correction, by a board-certified radiation oncologist. Planning-CT and daily treatments were performed under general anesthesia in sternal recumbency. Reproducible positioning was accomplished with both, an individually shaped vacuum cushion and a custom-made bite block. The target was the whole brain, extended by a planning target volume of 2 mm (PTV) and dose was prescribed at the ICRU reference point and delivered in a protocol of 5 × 4 Gy (20 Gy total dose). According to the Swiss law and routine in our clinic, the IMRT treatment plans were dosimetrically verified using a phantom and a medical physicist approved all plans. All dogs received prednisolone, but no other immunosuppressive medication during radiation therapy.
2.3. Follow-up examinations and outcome
To quantify neurologic changes, the results of the neurologic examination were scored along a previously published scoring scheme (3) at the time of presentation, immediately before the first radiation therapy, after the end of radiation therapy and at the time of follow-up MRI and CSF examination. Progression free interval and overall survival from beginning of radiation therapy to time point of writing this study were documented.
2.4. Histopathology
Animals that died or have been euthanized underwent histopathologic examination of the brain to reach a definitive diagnosis, to determine the character and extend of inflammation and to assess the effect of radiation therapy on healthy CNS parenchyma. The examination was performed by a board-certified veterinary pathologist.
2.5. Statistical analysis
Descriptive statistics were used in the analysis of dogs and disease characteristics.
Time to progression was calculated from the first day of radiation therapy to the date of first-documented neurologic progression (clinical or imaging-based). Dogs showing no symptoms of deterioration, no progressive lesions on MRI or that were alive at the time of data analysis closure were censored. Dogs not progressing or alive at completion of data-analysis were censored. Overall survival was calculated from the first day of radiation therapy to the date of death. Dogs still alive at completion of data analysis were censored at last verified date alive as defined by follow-up exam or follow up phone call with the owners. All dogs that were dead at the end of the study were recorded as events. Survival plots were generated according to the Kaplan-Meier product-limit method. Survival estimates were presented as medians with the corresponding 95% confidence intervals (95% Cis).
3. Results
3.1. Study population
Ten dogs were enrolled prospectively in this study. Their signalment is given in Table 1. The mean age at diagnosis was 5.2 years (range 1.3–9).
Seven dogs were newly diagnosed with MUO, and three dogs (dog 1, 2, and 6) were diagnosed with a MUO relapse. These three dogs were treated with variable immunosuppressive medication before enrollment in the study. Further information is given in Table 1. For the study purpose, immunomodulating medication other than prednisolone was stopped before inclusion.
3.2. Pre-treatment neurodisability score, MRI, and CSF findings
General clinical examination and blood results were unremarkable in all dogs. The neurodisability score varied among the study population and ranged between 3 and 7 (mean 4.9) prior to radiation therapy (Figure 1).
Figure 1. The line diagram shows the progression of the neurodisability score of the dogs examined. The x-axis shows the time course, and the y-axis shows the disability score at the time of the examination.
MRI revealed focal lesions in two and multifocal lesions in eight dogs. After contrast admission, enhancement was observed in all cases with variable pattern. Mild to moderate mass effect was reported in six dogs. We recognized four dogs with a mild foramen magnum herniation. One dog did have an additional mild caudal transtentorial herniation. Further details on MRI characteristics including imaging based subclassification into GME, NLE, and NME are reported in Table 2. We identified two cases of suspected NLE, which shared also features of GME due to the involvement of cerebral and cerebellar cortical gray matter.
The CSF total nucleated cell count ranged between 0.7 and 542.6 leukocytes per μL. In two dogs (dog 1 and 8) the cell count was normal. In both, MUO was later confirmed by histopathology. In one dog only a small amount of CSF could be collected, precluding counting of the exact cell count. However, a lymphocytic pleocytosis was confirmed by a board-certified clinical pathologist. CSF total protein count varied between 0.2 and 1.53 g/L, with normal protein levels in four dogs. In one dog CSF total protein was not measured due to low CSF volume obtained. In another dog total protein was semiquantitively determined by Pandy‘s test. The test was rated strongly positive (+++). For further details on CSF results, the reader is referred to Table 2.
Infectious diseases were tested negative in all dogs. Infectious disease testing varied among the patients depending on additional clinical symptoms, season, traveling history and availability of body fluids. For further details on the individual infectious disease testing the reader is referred to Table 1.
3.3. Radiation therapy
In the seven dogs with newly diagnosed MUO radiation therapy was initiated after a mean of 9.3 days (SD 3.6 days; range 6–16 days). In the remaining three dogs, time to relapse was 474, 802, and 111 days, respectively, and RT was started after a mean of 26 days (SD 23.5 days; range 6–52 days) after confirmation of relapse. In the time between MUO diagnosis and beginning of radiation therapy all dogs were treated with prednisolone monotherapy. After infectious diseases were ruled out, dogs were treated orally with 2 mg/kg prednisolone every 24 h. The dose was reduced after two weeks to 1 mg/kg per day. Further reductions were made approximately every six weeks by 25% in order to achieve the lowest effective dose.
In all dogs the whole brain was considered as radiation target (mean volume 68.5 cm3, ±SD 15.8 cm3, range 50.7–93.2 cm3). The near-maximum dose (D2%) to the PTV was 20.5 Gy (mean); ±SD 0.3 Gy; the median dose (D50%) to the PTV was 20 Gy (mean); ±SD 0 Gy and the near-minimum dose (D98%) to the PTV was 18.9 Gy (mean); ±SD 0.7 Gy). The mean treatment time was six days (range 5–7 days).
3.4. Follow-up and outcome
3.4.1. Short term follow-up
The neurodisability score decreased in all but one dog between diagnosis and start of radiation therapy and further decreased during and after RT (Figure 1).
3.4.2. Follow-up MRI and CSF
Follow-up MRI was performed in 8/10 dogs. Results of the follow-up MRI and CSF findings are reported in Table 2. MRI images demonstrating complete and partial resolution of the lesions are shown in Figures 2, 3, respectively. Follow-up CSF examination was performed in 8/10 cases.
Figure 2. MRI of a 9-year-old Chihuahua (dog 10). Complete resolution of lesions is visible. In the upper row the brain is imaged at the time of diagnosis (A–C) and in the bottom row the brain is imaged at the corresponding levels three months after radiation therapy (D–F). The sequences are from left to right in a rostro-caudal direction at the level of the optic chiasm (A, D), the rostral colliculi and medial geniculate bodies (B, E) and the cerebellar nuclei (C, F). Transverse FLAIR (TR = 11,000 ms, TE = 125 ms, TI = 2,800 ms, ST = 2.5 mm) (A, B, D, E) and T2w (TR = 5,774 ms, TE = 100 ms, ST = 2.5 mm) (C, F) images are provided. TR, Time of Repetition; TE, Time of Echo; TI, Time to Inversion; ST, Slice Thickness. Multifocal, bilateral, asymmetrical, poor defined, hyperintense lesions, mainly affecting the white matter are visible (A–C). The lesions are in complete remission at the time of follow up—MRI (D–F).
Figure 3. MRI of a 4-year-old Chihuahua (dog 9). Partial resolution of lesions is visible. In the upper row the brain is imaged at the time of diagnosis (A–C) and in the bottom row the brain is imaged at the corresponding levels three months after radiation therapy (D–F). The sequences are from left to right in a rostro-caudal direction at the rostral commissure (A, D), the lateral ventricles, caudate nucleus, internal capsule and body of the corpus callosum (B, E) and the optic chiasm (C, F). Transverse FLAIR (TR = 11,000 ms, TE = 125 ms, TI = 2,800 ms, ST = 2.5 mm) (A–F) images are provided. TR, Time of Repetition; TE, Time of Echo; TI, Time to Inversion; ST, Slice Thickness. A large, single, irregular, and apparently well-delineated, hyperintense lesion within the left forebrain is visible, mainly affecting the white matter (A–C). The lesions are partially resolved at the time of follow-up MRI (D–F).
Follow-up MRI and CSF examination was not performed in two dogs, because they did not reach the 3-month follow-up time. Follow-up MRI and CSF examination were not performed after three, but five months in two cases, due to restrictions related to the coronavirus pandemic.
3.4.3. Outcome
At the time of writing 6/10 dogs are still alive. No dog was lost to follow-up. Median follow-up time for the dogs still alive was 1,033 days (95% CI: 28–2,029), mean 779 days (range 317–1,082 days).
Overall, four dogs showed progression: mean time to clinical progression for all dogs was 691 days (95%CI: 396–987), median not reached. Mean overall survival for all dogs was 723 days (95%CI: 436–1,011), again, median not reached. The Kaplan-Meier curves for the time to progression and the overall survival time are given in Figures 4, 5, respectively.
Figure 4. Time to progression Kaplan-Meier curves of the 10 dogs: mean time to progression was 691 days (95%CI: 396–987), median not reached. The tick marks represent censored cases, the vertical dotted lines mark 1 and 2 years.
Figure 5. Overall survival Kaplan-Meier curves of the 10 dogs: mean overall survival was 723 days (95%CI: 436–1,011), median not reached. The tick marks represent censored cases, the vertical dotted lines mark 1 and 2 years.
Clinical assessment as well as follow-up MRI and CSF examination were unremarkable in dog 4 and dog 10. At the time of writing, they are still in complete remission (1,033 and 340 days after beginning of radiotherapy, respectively), medicated with solely prednisolone at this point.
Five dogs were treated with a second immunosuppressive drug. In dog 3 with new lesions (disease progression) on MRI mycophenolate mofetil was started (11.8 mg/kg twice daily). In the four other dogs with incomplete remission (dog 2, 5, 6, and 9) ciclosporin was added. Dosages varied between 3.1 and 7.1 mg/kg twice daily.
Three dogs (dog 1, 8, and 5) were presented because of acute neurological deterioration 45, 59, and 814 days after beginning of radiation therapy. At this time treatment was made by prednisolone only in all dogs except dog 5, which was additionally treated with ciclosporin and cytosine-arabinoside. In all dogs relapse was clinically suspected or confirmed based on imaging criteria. The dogs were euthanized on owner's request. Relapse was histopathologically confirmed in all dogs.
Dog 7 was presented 25 days after the beginning of radiation therapy due to reduced general condition, apathy, weight loss, and severe polyuria and polydipsia. A (diabetic) ketoacidosis was diagnosed, and euthanasia of the dog performed based on the owner's request. Surprisingly, glioma was suspected based on histopathologic findings in necropsy.
3.5. Histopathology
Dog 1 was diagnosed with a chronic, moderate, and multifocal to diffuse and granulomatous meningoencephalitis. Perivascular cuffs were seen in multifocal areas of the cerebral cortex, subcortical white matter, and basal nuclei as well as in the cerebellum. Inflammatory cells were dominated by lymphocytes and macrophages. Immunohistochemistry was not performed.
Dog 8 was diagnosed with a chronic, high-grade, necrotizing encephalitis. Bilateral, asymmetric, necrotic lesions were seen within the cerebral white matter, transitioning into the thalamus. Inflammation was sparse and mild, dominated by macrophages. Interestingly no CD3+ T-lymphocytes were recognized by immunohistochemistry.
Dog 5 was diagnosed with a chronic, severe, and multifocal, necrotizing, lymphohistiocytic leukoencephalitis. Perivascular cuffs were found in the frontal cortex, internal capsule, corona radiata and among various white matter tracts of the brainstem. Inflammatory cells were dominated by lymphocytes and macrophages. Next to those lesions there were also focal-extensive, necrotic areas within the cerebral white matter containing few mononuclear cells. These areas matched the lesions seen on the first MRI examination and follow-ups. They were in line with chronic, burned-out lesions of necrotizing leukoencephalitis. In contrast, no specific changes suggestive for radiation associated side effects were identified.
No definitive diagnosis could be made for dog 7. Histopathological evaluation revealed a single, chronic, malacic lesion extending from the right thalamus to the pons with distinct astrocytic gliosis. Inflammatory infiltrates were not seen. Indeed, IHC was negative for CD3 and CD20. In the perivascular parenchyma only few Iba-1 positive macrophages were proven. In contrast, a mildly increased density of oligodendrocytes (positive for Olig2) was recognized in the periphery and within the lesion. The most likely diagnosis by the pathologist was an oligodendroglioma.
4. Discussion
We evaluated a small group of dogs with an imaging diagnosis of MUO that were treated with whole brain radiation and combined prednisolone therapy. All dogs in our study improved neurologically during the therapy, three dogs relapsed, and five dogs needed additional immunosuppressive treatment. Hence the effect of prednisolone and combined radiation therapy might be considered a temporary one.
Currently, only three studies including 17 dogs in total have evaluated the effect of brain radiation for MUE in conjunction to prednisolone treatment (13–15). In contrast to our currently used protocol, previous protocols were given with higher total doses and more, albeit smaller fractions. Muñana and Luttgen treated the lesions of dogs with higher (antitumor) total doses of 40–49.5 Gy, applied in 2.4–4.0 Gy fractions (14). In a previous study by our group on the other hand, the whole brain was irradiated with a classical whole-brain-irradiation protocol, as used to palliate brain metastasis in humans, with 10 fractions of 3 Gy (15). Although the radiotherapy protocols in the dogs treated differed, response rates were high and median survival times ranged between 404 and 476 days.
The rationale of using ionizing radiation for inflammatory conditions is based on the strong radiosensitivity of immune cells. Cells of the immune system often undergo apoptosis within 3–5 h of relatively low doses of radiation (25). In lymphoma treatment for example, total lymphoid irradiation to a dose of 30–40 Gy leads to a long-lasting T-cell depletion, which also can be used to treat autoimmune disease (26).
The exact pathophysiology of MUO remains unknown. However, the disease shares histopathological similarities with multiple sclerosis (MS) in people (27–29) and is characterized by lymphocyte infiltration of central nervous parenchyma. Especially T-cells are thought to play a major role (30), supported by elevated interferon-gamma (IFNγ) and interleukin-17 (IL17) mRNA levels and protein in brain tissue (31) and higher amount of IL-17 producing T-cells in the peripheral blood of affected dogs (32).
Immunohistochemistry was performed in all, but one dogs that underwent necropsy and histopathological evaluation within the first three months after radiotherapy. Interestingly, in dog 8 no CD3+ T-lymphocytes were observed. The lack this cell population might reflect the chronicity of the necrotizing lesions, but also could provide evidence for the radiation-induced apoptosis in lymphoid cells.
Despite incomplete understood pathophysiology, immunosuppressive agents are the mainstay of therapy (2, 4). Glucocorticoids, such as prednisolone, have proofed to be the most effective treatment. Based on a systematic review (11), the use of second line immunosuppressive agents is recommended as it may decreases glucocorticoid related side-effects (33) and increases treatment sufficiency. By doing so, multimodal treatment therapy has in the past shown to result in longer median survival time than glucocorticoid treatment alone (11, 12, 14, 34). However, recent studies did not show improved short-term survival in dogs treated with a second-line medication compared to sole prednisolone (6, 7). A reason for the variation of survival times among studies possibly reflects different immunosuppression protocols, with more aggressive and immunosuppressive glucocorticoid protocols may leading to longer survival times (33, 35).
The secondary immunosuppressive agents studied in MUO include antiproliferative agents (e.g., lomustine, procarbazine, cyclophosphamide), antimetabolites (e.g., cytosine arabinoside, azathioprine, mycophenolate mofetil, leflunomide) and calcineurin inhibitors (e.g., cyclosporine) (2, 4). Many of these more established medical second line immunosuppressive agents carry the risk of side effects, including gastrointestinal disturbances (36, 37), the potential risk for hepatotoxicity (38), myelosuppression (12) and more drug-specific side effects (3, 39, 40). Thus, alternative treatments for MUO are required.
In contrast, mild early radiation associated side effects of skin and hair were rarely reported by Beckmann et al. (15). Such side effects were neither noted in clinical follow-ups, nor reported by the owners in our study. This finding is in line with previous studies (14).
Four dogs in our study were euthanized, including three dogs within 59 days and one dog 814 days after beginning of radiotherapy. All dogs underwent histopathological examination of the brain. Histopathological features of radiation associated side effects were not noted in any of these dogs. For doses equivalent to 10 × 3 Gy, the commonly used protocol for whole-brain radiotherapy in people with brain metastasis, the risk of radionecrosis is very low, with an estimated risk of 0–1.6% (41, 42). This may provide further evidence for the safety of the described radiation protocol. Slow dividing and post-mitotic tissue such as the central nervous system, are more prone to late radiation side effects occurring from 6 months to years after radiation therapy. Such late side-effects are mainly attributed to injury of oligodendrocytes and endothelial cells, leading to white matter demyelination and vascular injury and depend on total dose, fraction size and target volume (43, 44). In human patients undergoing whole brain radiation therapy, vascular injury has been associated with cognitive decline (45, 46). In dogs a possible cognitive decline might not pose the same quality-of-life issues as in people. Though no side effects have been identified, we must admit that only one of the dogs that underwent histopathological evaluation was euthanized after more than 6 months and together with the small total number of dogs included into the study, we are unable to claim definitive harmlessness of the protocol.
The neurodisability score improved in all our patients already after initiation of prednisolone therapy and further improved during and after radiation therapy.
Clinical follow-up as well as MRI and CSF examinations revealed that only two dogs underwent complete remission. In those dogs, therapy was continued by tapering the dose of prednisolone. In the other dogs established second line medications were added to the prednisolone treatment, including cyclosporine in four and mycophenolate mofetil in one dog. A reason for that finding might be the fact, that radiation therapy was applied to the brain only. As stated above, this leads to a fast killing of inflammatory cells within the brain parenchyma but does not necessarily suppress the recruitment of inflammatory cells from the periphery. In human medicine this problem has been faced by total lymphoid radiation using even lower radiation doses (47–49).
Despite few prognostic indicators have been identified for short-term survival, the overall clinical course of MUO is often progressive and unpredictable. In many affected dogs the response to standard immunosuppressive therapy might be temporary.
Independently from chosen treatment protocol, 26–33% of the affected dogs are reported to die within the first 3 months after diagnosis (3, 5–7). Similar to these results, 3/10 dogs died or were euthanized within 59 days after start of radiotherapy in our study. A recent publication identified obtundation at presentation as risk factor for early euthanasia in dogs with MUO (7). In line with this study, all three dogs that have been euthanized within the first 3 months after radiotherapy in our study, presented obtunded.
Steroid responsive meningitis arteritis (SRMA) is another immune-mediated, inflammatory disease in dogs. As in MUO, immunosuppression by prednisolone is considered the mainstay therapy (50). Few data on the management of relapsing SRMA cases is available, using medications in conjunction to prednisolone that are also described in MUO (50–52). One of these studies has shown, that increasing prednisolone dosage was not sufficient to control clinical signs in 40% of the cases (51). The reason for this finding remains unknown. However, reduced sensitivity to glocorticoids has been noticed in people as well, including patients with multiple sclerosis (53, 54).
In the lack of a standard treatment protocol, yet only a few treatment studies included dogs with relapsing MUO (55). Similar to SRMA, it‘s reasonable to conclude that relapsing MUO may require the combination of prednisolone with other immunosuppressive drugs.
Our results show that radiotherapy might be beneficial in dogs that are considered (partially) refractory to medical treatment alone. All three dogs, that were considered relapses showed a quick response to radiotherapy in combination with prednisolone, leading to a neurodisability score of 0 in two of them and 0.5 in one of them by the end of radiotherapy. This compares to preliminary findings were in 11/14 dogs refractory to medical treatment improvement was observed after RT (56). Since the specific effect of radiation on inflammation is not yet understood we do not know if the non-responding groups in medical and radiation treatment overlap. It may well be possible that dogs failing one treatment would respond to the other.
Recently a study highlighted, that early death might be related to medical side effects in ~20% of dogs that die or are euthanized (7). Similar to previous results (15), radiation associated side effects were neither noted in short, nor in long-term follow-up in our study. In contrast, glucocorticoid-induced diabetes mellitus was the cause for euthanasia in one dog in our study. Based on histopathological findings an oligodendroglioma has been diagnosed in this dog. As the histopathological diagnosis of immune mediated encephalitis was not part of our inclusion criteria, we still included the case in our results. The patient had the worst neurodisability score at the time of diagnosis and by the end of radiotherapy (7 and 4, respectively). The inclusion of the dog with suspected oligodendroglioma reflects the poorly understood etiopathogenesis of MUO, the lack of accurate, non-invasive antemortem diagnostic tests and, as in this case, effective treatment.
Based on previously published MR imaging features, we identified four dogs with suspected GME, five dogs with suspected NLE and one dog with suspected NME. Please note, that one of the dogs with GME was diagnosed with oligodendroglioma in pathology. Interestingly, two dogs fit predominantly the imaging features of NLE, but also shared features GME due to the involvement of cerebral and cortical gray matter (Table 2). Both dogs were French Bulldogs and have been diagnosed with relapsing MUO before included into our study (Table 1). One of these dogs underwent histopathologic examination of the brain, which also identified features of GME. Classically, NLE has been described in French Bulldogs (22, 57, 58). However, the overlap of necrotizing and granulomatous encephalitis has been noted recently, suggesting that the transitions between necrotizing and granulomatous variants of MUO might be flowing and less distinct in some cases (59).
A complete remission was achieved in two dogs, both with imaging features of GME. However, we believe that our study population is too small to draw definitive conclusions on the response to radiotherapy specified to the variants of MUO.
Our study population comprised two dogs suffering from epileptic seizures. The prognosis to achieve a good seizure outcome is generally considered poor in dogs with structural epilepsy (60), including MUO (61). Despite only one of the dogs in our study had anticonvulsive medication (Levetiracetam 20 mg/kg q8h), both became seizure free. The reasoning for the treatment with Levetiracetam was made on previous investigations, highlighting a slightly beneficial outcome when used in structural epilepsy (62). Although our study sample is too small to draw definitive conclusions, radiotherapy may also have contributed to this outcome. Significantly longer duration of seizure-freedom has been observed in dogs with brain tumors undergoing radiotherapy compared to medical treatment alone (63). However, the reason for this finding remained unclear.
Our study has several limitations. First, this study was designed in a small scale and without a control group receiving sole prednisolone or in combination with a second immunosuppressive drug. Second, radiotherapy was not performed alone, but in conjunction to prednisolone therapy. For these reasons, the entire benefit of RT cannot be quantified in our study. However, due to the fast improvement of the neurodisability score in conjunction with improved lesion pattern seen on MRI in most of our dogs, we assume a complementary therapeutic effect on immunosuppressive medication as it has been also reported in previous publications (14, 15). Another limitation is the lack of histopathological confirmation at inclusion. In one dog oligodendroglioma was suspected based on post-mortem histopathological findings.
The histopathological suspicion of an oligodendroglioma in one of our cases shows, that there still is a risk to include different CNS diseases like neoplasia.
Comparative prospective studies are needed to better understand the value of radiotherapy for the treatment of MUO vs. drug treatment options. To proof the potential benefit of second line medication in overcoming glucocorticoid associated side effects, future treatment protocols (using chemotherapeutics like cytarabine) should include scoring systems (64).
In conclusion, our results support that radiotherapy may serve as fast, additional treatment option in conjunction to glucocorticoid treatment for dogs with meningoencephalitis of unknown origin without overt safety issues. It could be considered in dogs being refractory to medical treatment alone or suffering from severe medical side effects.
Data availability statement
The original contributions presented in the study are included in the article/supplementary material, further inquiries can be directed to the corresponding author.
Ethics statement
The animal study was reviewed and approved by Animal Ethics Council of the Canton of Zurich, Switzerland. Written informed consent was obtained from the owners for the participation of their animals in this study.
Author contributions
RH was responsible for data collection regarding clinical, neurological, and laboratory data, their interpretation and drafting, and writing the manuscript. KB contributed to data collection and writing and helped to draft the manuscript. MK performed radiation therapy. FS contributed to conception, design and data collection, and gave critical input. Furthermore, he was involved to raise funding of the study. CR performed radiation therapy and contributed to conception, design, and writing and finalized the version to be published. Furthermore, she was involved to raise funding of the study. All authors have read and approved the final version of the manuscript.
Funding
Albert-Heim-Stiftung provided funding to this study (AHS project number 145).
Acknowledgments
The authors thank Anna Oevermann (Dipl. ECVP) for performing histopathology and expertise in case discussion. Preliminary data of this study were presented at the 34th ESVN-ECVN Symposium by RH.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher's note
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Keywords: MUO, MUE, encephalitis, inflammation, radiotherapy, canine, brain
Citation: Herzig R, Beckmann K, Körner M, Steffen F and Rohrer Bley C (2023) A shortened whole brain radiation therapy protocol for meningoencephalitis of unknown origin in dogs. Front. Vet. Sci. 10:1132736. doi: 10.3389/fvets.2023.1132736
Received: 27 December 2022; Accepted: 28 February 2023;
Published: 20 March 2023.
Edited by:
John Henry Rossmeisl, Virginia Tech, United StatesReviewed by:
Thomas Flegel, Leipzig University, GermanyThomas Robert Harcourt-Brown, University of Bristol, United Kingdom
Copyright © 2023 Herzig, Beckmann, Körner, Steffen and Rohrer Bley. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Robert Herzig, cm9iZXJ0LmhlcnppZyYjeDAwMDQwO3V6aC5jaA==
†These authors have contributed equally to this work and share last authorship