The serum cobalamin concentration is measured by an automated chemiluminescence competitive binding immunoassay system [35,36,37]. The reference interval for feline serum cobalamin concentration is 290–1500 ng/L and values <290 ng/L are considered subnormal [35,37]. A serum cobalamin concentration <100 ng/L represents the lower limit of detection of the chemiluminescent assay system for cats [29,37]. For serum cobalamin assessment, samples should be promptly stored at −20 °C. However, this vitamin remains stable for 5 days if samples are refrigerated at 6 °C even if they are not protected from light [17,38].

The direct influence of diet on serum cobalamin concentration can depend on several factors, and age, sex, and breed play important roles. Older cats frequently show decreased absorption of this vitamin, probably related to a decreased ability to digest it due to reduced ileal and pancreatic function [39,40]. Kittens show lower serum cobalamin concentration during the first months of life; this may be related to the immaturity of the microbiota, the gastrointestinal tract, and the pancreas. A gradual increase in cobalamin serum level is observed in young cats during the first year of age, when microbiota, gastrointestinal tract, and pancreas complete their development [41]. Male cats usually show significantly higher serum cobalamin concentrations than females [39]. Higher concentrations of vitamin B12 have been recorded in pure-breed cats than mixed-breed cats [42,43]. Barron et al. (2009) reported that the median serum cobalamin concentration in healthy cats is lower in older and mixed cats, but not in male cats, contrary to what was suggested by Hill et al. (2018) [44].

The serum cobalamin concentration does not accurately reflect the real availability of cobalamin, because cobalamin-dependent metabolic reactions occur within cells, mainly in the cytoplasm and mitochondria [15]. Methylmalonyl-CoA mutase catalyzes the formation of succinyl-CoA from methylmalonyl-CoA, which is produced by the catabolism of odd-chain fatty acids and amino acids. Succinyl-CoA is a key molecule in the citric acid cycle. A lack of intracellular cobalamin leads to reduced enzyme activity and an intracellular and subsequent systemic accumulation of methylmalonic acid (MMA), resulting in methylmalonic acidemia [29]. This molecule can also inhibit the activity of carbamoyl phosphate synthetase I, an enzyme of the urea cycle that normally metabolizes ammonia to carbamoyl phosphate. When this metabolic process is impaired, plasma ammonia concentrations typically increase [17] and neurological disorders can occur [45]. Therefore, the MMA concentration in cat serum is particularly useful for detecting cobalamin deficiency, as it is directly related to the real bioavailability of the vitamin for intracellular enzymatic reactions [46].

Serum and urinary MMA concentrations can be determined by gas chromatography–mass spectrometry in fresh or stored samples (−20 °C) [17,35,37]. The reference interval of serum MMA concentration defined for cats is 139–897 nmol/L [29]. The limitation of MMA measurement is mainly the higher cost compared to cobalamin detection [15]. Cats with severely subnormal serum cobalamin concentrations typically show extremely elevated serum MMA concentrations; a 50-fold increase over the highest normal value has been documented [46]. Although the serum MMA concentration reflects an intracellular cobalamin deficiency, other causes of elevated MMA must be considered, such as renal failure, reduced plasma volume reduction, and abnormalities in hepatic methyl-malonyl CoA mutase activity [15,47]. In both dogs and cats, normal serum MMA concentration with low serum cobalamin status seems to be a possible clinical finding. Low serum cobalamin levels could reflect depletion and redistribution of body reserves prior to real cobalamin deficiency in the mitochondria [37,48,49]. There is a lack of available data regarding urinary MMA determination in cats. To reduce the dilution effect and the influence of renal impairment, the urinary MMA-to-creatinine ratio should be considered. In cats, the reference range has been defined as 0.22–0.51 mmol/mol creatinine [3]. While a correlation between serum cobalamin deficiency and increased urinary MMA concentration has been observed in cats, no significant correlation has been detected between serum and urinary MMA concentrations [3,50]. In dogs, measuring urinary MMA concentration appears to be more advantageous due to its high stability in urine; in this species, urinary levels appear to be more concentrated than serum levels (urinary MMA concentration can be up to 40 times higher than serum concentration) [17].

In humans, total plasma homocysteine levels are used in the diagnosis of cobalamin deficiency. Cobalamin represents an essential cofactor for the enzyme methionine synthase, which is essential for the synthesis of methionine from homocysteine. Cobalamin deficiency blocks this reaction by promoting homocysteine accumulation. When not enough cobalamin is available, the pathway is blocked and homocysteine accumulates within the cells and plasma [51]. In humans, hyperhomocysteine is related to cobalamin deficiency [52], whereas in dogs, homocysteine can be used mainly in the diagnosis of familiar cobalamin deficiency specifically in the Chinese Shar-Pei [53], but only after other diseases have been ruled out [54]. In cats, homocysteine is not used as a diagnostic marker [15,55], because cobalamin deficiency is not associated with hyperhomocysteinemia in this species [29,30,37]. Even when the serum cobalamin concentration is extremely low or undetectable, the homocysteine level will fail to diagnose cobalamin deficiency probably because methionine is commonly added to commercial diets for cats, since it is generally the most limited amino acid in their diet [29]. A recent study evaluated serum cobalamin concentrations in healthy tigers (Panthera tigris) and tigers affected by pancreatic insufficiency-like syndrome. The results showed much lower B12 concentrations in both healthy and affected tigers than in domestic cats, although reference ranges for serum cobalamin concentrations in tigers have not yet been established [56]. Another study was conducted on cheetahs (Acinonyx jubatus) to establish reference ranges of species-specific biomarkers of gastrointestinal disease, including cobalamin and MMA. The measured ranges were 470–618 ng/L and 365–450 nmol/L for cobalamin and MMA, respectively, showing that even between closely related species such as the domestic cat and cheetah, there can be differences in gastrointestinal biomarkers [57].