Department of Small Animal Clinical Sciences
(B12) Cobalamin: Diagnostic use and therapeutic considerations
- Cobalamin deficiency in Gastrointestinal Disease
- Cobalamin Therapy
- Doses and route of administration
- Further Reading
Cobalamin (Vitamin B12) is a water-soluble, cobalt-containing vitamin with an important role in biochemical processes referred to as single carbon transfers. During these reactions, functional units such as methyl groups (-CH3) are transferred onto or between biologically important compounds. Cobalamin is a co-factor for at least three enzymes that carry out these types of reactions, acting as a transitional carrier of the single carbon group. A typical reaction catalyzed by a cobalamin dependant enzyme, methionine synthase, is illustrated in figure 1. Single carbon biochemistry is an area of great interest in the human population, as deficiencies in the activity of these enzymes may be associated with hyperhomocysteinemia. Hyperhomocysteinemia is a recognized risk factor for cardiovascular disease. Deficiency in cobalamin may also be associated with demyelinating neuropathies, dementia and megaloblastic anemia (Pernicious Anemia) in human patients.
In companion animal medicine, most attention to cobalamin has been directed towards its use as a diagnostic marker for gastrointestinal disease. Recent evidence from studies at the Gastrointestinal Laboratory have also shown that supplementation of cobalamin is important to get the best response to therapy for gastrointestinal disease.
Figure 1 (on TAMU website: http://vetmed.tamu.edu/gilab/research/cobalamin-information ) A typical cobalamin dependant reaction, where a methyl group (-CH3) is added to homocysteine to make methionine
In animals with reduced cobalamin absorption, regardless of the cause, it is reasonable to expect that eventual depletion of bodily cobalamin stores will occur and cobalamin deficiency will ensue. As all cells in the body require cobalamin for single carbon metabolism, it has been hypothesized that cobalamin deficiency may actually contribute to the clinical signs and manifestations of gastrointestinal disease in some patients. Studies of radiolabelled cobalamin in cats have demonstrated that the half-life of this compound is significantly reduced with gastrointestinal disease.
While the serum concentration of cobalamin is used diagnostically, the reactions catalyzed by cobalamin dependant enzymes occur in the mitochondria, making it difficult to assess the state of cobalamin availability in the patient. Tissue-level deficiency of cobalamin is associated with an increase in the urinary and serum concentrations of an organic acid called methylmalonic acid, which is an alternative product of a cobalamin dependant pathway within the mitochondria. Using this compound as a marker of cobalamin deficiency, we have been able to demonstrate that cats and dogs with very low serum cobalamin do indeed have a significant tissue-level cobalamin deficiency (Figure 2.). Interestingly, in cats, there was no change in serum concentration of homocysteine (see figure 1. Elevation in homocysteine is expected with cobalamin deficiency due to reduced methionine synthase activity) even in the face of extreme cobalamin deficiency. In dogs, preliminary evidence suggests that there is an increase in serum homocysteine concentration with reduced serum cobalamin concentration.
Figure 2: (on TAMU website: http://vetmed.tamu.edu/gilab/research/cobalamin-information ) Serum concentrations of methylmalonic acid are extremely high in cats with cobalamin deficiency, when compared to clinically healthy cats with normal serum cobalamin.
As described above, there is compelling evidence that significant tissue-level cobalamin deficiency is present in some companion animal patients with gastrointestinal disease. The significance of this finding for the clinical management of these patients is also becoming clearer. A recent study has examined the effect of cobalamin supplementation on the outcomes of treatment for feline patients with severe cobalamin deficiency and histories suggesting chronic gastrointestinal disease.5 In this study, serum concentrations of methylmalonic acid normalized following parenteral cobalamin supplementation, indicating that cobalamin deficiency was the cause of the high methylmalonic acid in serum. There was an overall weight gain in these patients, and a decrease in the frequency of clinical signs such as vomiting and diarrhea. During the course of the study, there was no change to the therapeutic regime other than the introduction of parenteral cobalamin supplementation.
Dogs with exocrine pancreatic insufficiency will commonly present with subnormal serum cobalamin concentrations. Therapy with bovine pancreatic enzyme extracts is not sufficient to restore cobalamin absorption in dogs with EPI, as intrinsic factor appears to be species specific. Failure to absorb cobalamin in dogs with EPI may be due to all three potential causes of low serum cobalamin. Pancreatic secretion of intrinsic factor is reduced or absent, secondary bacterial overgrowth of the intestine is common, and the mucosa may be compromised by the presence of excessive bacterial numbers and toxic metabolites. Dogs with exocrine pancreatic insufficiency should be considered at high risk for the development of cobalamin deficiency. As clinical signs of cobalamin deficiency include chronic wasting or failure to thrive, malaise, and gastrointestinal signs such as diarrhea, serum cobalamin concentration should be measured in any dog with poor response to enzyme replacement therapy for EPI.
Cobalamin should be supplemented whenever serum cobalamin concentration is in the low normal range (approximately less than 300 ng/L) in both dogs and cats. Most commonly, cyanocobalamin is chosen for supplementation, as it is both widely available and inexpensive. Very little evidence-based information about cobalamin supplementation in dogs and cats is available. However, as in people, cobalamin deficiency leads to cobalamin malabsorption so that cobalamin should always be supplemented parenterally. Since cobalamin is a water-soluble vitamin, excess cobalamin is excreted through the kidneys and clinical disease due to over-supplementation has not been described.
We currently recommend SC injection of 250 µg per injection in cats and, depending on the size of the patient, 250-1500 µg per injection in dogs. We have recently changed our suggested dosing schedule for cobalamin supplementation: q 7 days for 6 weeks, then one dose after 30 days, and retesting 30 days after the last dose. If the underlying disease process has resolved and cobalamin body stores have been replenished, serum cobalamin concentration should be supranormal at the time of reevaluation. However, if serum cobalamin concentration is within the normal range, treatment should be continued at least monthly and the owner should be forewarned that clinical signs may recur sometime in the future. Finally, if the serum cobalamin concentration at the time of reevaluation is subnormal, further work-up is required to definitively diagnose the underlying disease process and cobalamin supplementation should be continued weekly or bi-weekly.
It should be pointed out that in rare cases cobalamin supplementation fails to increase serum cobalamin concentration for reasons that are not currently understood. In these cases another formulation of cobalamin, such as hydroxocobalamin, might be effective.
Cobalamin may also have a pharmacologic effect as an appetite stimulant. Anorectic feline patients with cobalamin deficiency often start to eat again once they are being supplemented and appetite wanes once again when cobalamin is no longer administered weekly, despite a normal serum cobalamin concentration. In these patients cobalamin supplementation should be continued on a weekly or biweekly dosing schedule.
We currently recommend that all dogs and cats with chronic histories of gastrointestinal disease should have serum cobalamin concentrations measured. This is particularly important in any case with sub-optimal response to previously instituted therapy. As cobalamin is inexpensive, water soluble and any excess is readily disposed, cobalamin supplementation should certainly be considered for any animal with a serum cobalamin concentration lower than the laboratory reference range.
- Simpson KW, Fyfe J, Cornetta A, Sachs A, Strauss-Ayali D, Lamb SV, Reimers TJ (2001), Subnormal concentrations of serum cobalamin (Vitamin B12) in cats with gastrointestinal disease, Journal of Veterinary Internal Medicine 15: 26-32
- Vaden SL, Wood PA, Ledley FD, Cornwell PE, Miller RT, Page R (1992), Cobalamin deficiency associated with methylmalonic acidemia in a cat, Journal of the American Veterinary Medical Association 200 No.8: 1101-1103
- Ruaux CG, Steiner JM, Williams DA. (2001), Metabolism of amino acids in cats with severe cobalamin deficiency. American Journal of Veterinary Research 62: 1852-1858
- Ruaux CG, Steiner JM, Williams DA. (2005), Early Biochemical and Clinical Responses to Cobalamin Supplementation in Cats with Signs of Gastrointestinal Disease and Severe Hypocobalaminemia. Journal of Veterinary Internal Medicine 19: 155-160
- Simpson KW, Morton DB, Batt RM (1989), Effect of exocrine pancreatic insufficiency on cobalamin absorption in dogs, American Journal of Veterinary Research 50: 1233-1236