The neutrophil/lymphocyte ratio (NLR), which is the absolute count of neutrophils (NEU) divided by the absolute count of lymphocytes (LYM), is a marker of systemic inflammation obtained from a complete blood count. Typically, as an inflammatory disease progresses, the neutrophil count in the blood rises while the lymphocyte count, which indicates the patient's immune status, tends to fall^7,8. The platelet-lymphocyte ratio (PLR), a haematological marker of inflammation, is determined by dividing the total platelet count (PLT) by the LYM. It has been proven to be another inflammatory marker in human studies, often complementing the NLR^9,10.

Recent research indicates that mean platelet volume (MPV) holds promise as a diagnostic indicator for inflammatory conditions^11,12. As a marker of activated platelets, MPV has shown associations with various inflammatory diseases¹³. In addition, the ratio of mean platelet volume to platelet count (MPV/PLT) is used in human medicine to diagnose and evaluate the prognosis of various infectious and inflammatory conditions^14,15.

In light of these considerations, it was hypothesised that haematological indices ‒ including NLR, PLR and MPV/PLT ‒ vary according to the clinical severity of feline infectious peritonitis (FIP) and may serve to determine the severity of the disease. Furthermore, the study aimed to evaluate the levels of haematological indices in relation to clinical severity in cats with FIP. Haematological indices, which are widely used in human medicine and relatively new in veterinary medicine, offer several advantages in the assessment of disease prognosis. These include ease of measurement and cost-effectiveness. Given these advantages, haematological indices may offer the potential for seamless integration into veterinary clinics and hospitals to determine disease severity in cats with FIP. In conclusion, in addition to determining the severity of disease in cats with FIP, haematological indices have the potential to play a role in determining the prognosis of the disease in further studies and to have prognostic significance for survival or mortality during hospital admission.

Animals: The study material consisted of cats admitted to the Small Animal Clinic of the Faculty of Veterinary Medicine, Atatürk University. The diagnosis of FIP was based on clinical signs (fever, vomiting, malaise), detection of coronavirus antigen in septic or non-septic abdominal-thoracic fluid using an ELISA test kit (Asan Easy Test FCoV, Korea), and cats with an A:G ratio of less than 0.8 were also tested for possible parasitic infections associated with FIP. Cats (n=8) with an A:G ratio between 0.8 and 0.6 were classified as early stage FIP, while those with an A:G ratio below 0.6 (n=7) were classified as late stage FIP. The healthy group consisted of clinically healthy cats presented for vaccination and antiparasitic treatment.

Blood sampling and laboratory analysis: Before treatment, blood samples were meticulously obtained through careful venepuncture, employing 21-gauge needles inserted into the jugular vein. The acquired blood was then divided into serum and anticoagulant (EDTA) tubes for further analysis. Complete blood count (CBC) analyses were conducted using an automated haematology analyser (Abacus Junior Vet5®, Hungary). The NLR, PLR, and MPV/PLT were calculated using the following formulas:

NLR = absolute counts of neutrophils/absolute counts of lymphocytes

PLR = absolute counts of platelets/absolute counts of lymphocytes

MPV/PLT = mean platelet volume/absolute counts of platelets.

Statistical Analysis: The study data were subjected to statistical analysis using a one-way ANOVA followed by post hoc tests to compare NEU, LYM, NLR, PLT, PLR, MPV, and MPV/PLT between healthy and early and late-stage FIP groups. Prior to analysis, a normal distribution was confirmed using the Kolmogorov-Smirnov test. Statistical analysis was performed using SPSS 27.0 with a significance level of P <0.05.

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Table 1: Demographic findings of cats in the control, FIP (Early stage) and FIP (Late stage)

Haematological analysis revealed notable findings: the neutrophil count in cats with FIP exhibited a statistically significant increase compared to the control group. In addition, within the FIP cohort, the neutrophil count increased significantly in the late stage compared to the early stage, with statistical significance highlighted. Conversely, the PLT count showed a decreasing trend as the severity of the infection progressed. It was particularly notable that a significant decrease in platelet count compared with the control group was only observed in the late stages of the disease. Among the haematological indices, NLR demonstrated a statistically significant increase in response to FIP. However, it is important to note that NLR levels remained unchanged throughout the severity of the disease (Table 2).

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Table 2: Results of the haematological analyses and haematological indices according to disease severity in cats with FIP

We observed a trend of lower lymphocyte counts in cats with FIP compared to the control group, although this decrease did not reach statistical significance. This finding is in aggrement with the previous studies on feline viral infections^22,23 and FIP ^24, which have reported lymphopenia as a common symptom. Previous research proposes a model for FIP pathogenesis wherein virus-induced T-cell depletion and antiviral T-cell responses act as opposing forces, with the efficacy of early T-cell responses crucially influencing infection outcomes^25,26. While this study did not analyse lymphocyte subtypes, study findings are consistent with this model. However, it is important to note the lack of statistical significance, possibly attributable to the small sample size. Therefore, conducting larger-scale studies to further investigate lymphopenia in cats with FIP is strongly recommended in this context.

The increase in NLR levels observed in cats with FIP, as compared to healthy cats, highlights its central role in signalling inflammation, similar to recent breakthroughs in human studies infected with coronavirus infection^27,28. This increase in NLR may be related to the immune response in cats, characterised by a paradoxical combination of neutrophilia and lymphopenia, as revealed in these studies. In contrast to viral infections characterised by haematological responses typically associated with neutropenia (feline panleukopenia virus, feline immunodeficiency virus, and feline leukemia virus), the unexpected neutrophilia in FIP, due to the nature of coronaviruses, highlights the remarkable efficacy of NLR as an important haematological marker for monitoring infection in coronavirus-induced infections.

The count of PLT exhibited a notably lower statistical significance in felines afflicted by late-stage FIP when compared with their healthy counterparts. Nevertheless, this decrease did not reach statistical significance in cats with early stage FIP compared to the control cohort. This observation mirrors the occurrence of thrombocytopenia in human research, particularly in cases of coronavirus-induced lung injury in the critically ill patients²⁹. Furthermore, human studies highlight thrombocytopenia as a hallmark of critical illness, signalling severe organ dysfunction and the onset of intravascular coagulopathy, often culminating in disseminated intravascular coagulation^30,31. In this framework, it is rational to posit thrombocytopenia as a late marker of inflammation to measure the severity of inflammation in cats with FIP. However, unexpectedly, there was a lack of variation in PLR both in cats affected by FIP and in relation to the severity of FIP. We did not observe any statistical variance in PLR levels between groups, probably due to lymphocyte responses rather than PLT counts. Based on study results, it is conceivable that PLR may not serve as a reliable marker for monitoring inflammation or its severity in FIP-affected cats.

In the present study, we observed a decrease in MPV levels attributed to FIP. Furthermore, this decrease persisted with worsening severity of FIP. We also observed an increase in the MPV/PLT ratio associated with FIP, but neither of these findings reached statistical significance. The reduction in MPV was consistent with findings from previous research^32,33. In addition, consistent with studies highlighting the MPV/PLT ratio as a key metric in infection surveillance^34, we documented an increase in the MPV/PLT ratio in cats with FIP. It's reasonable to attribute this to a decreased platelet count rather than an escalation in MPV. However, the statistically insignificant variation identified in analysis cautions against using MPV and the MPV/PLT ratio as robust indicators for monitoring infection in cats with FIP. Further investigation is essential to resolve this question. The major limitation of the study is that other viral agents that may affect A:G could not be tested in all cats due to economic constraints.

In conclusion, this study investigated the potential benefits of haematological indices in monitoring inflammation and its severity in cats infected with FIP. In particular, the NEU, NLR and PLT count emerged as promising metrics in this regard. Given the cost-effectiveness, accessibility, and widespread use of haematological indices, they hold the promise of becoming key parameters in monitoring inflammation and its severity in cats with FIP.

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