Acute Management of Calcium Disorders

Acute management of hypercalcemia and hypocalcemia is an important part of small-animal emergency practice. In addition to hypercalcemia of malignancy and hyperparathyroidism, vitamin D toxicosis is becoming more common in companion animals as new and improved rodenticides and human pharmaceutical preparations (vitamin D analog skin creams) become more available. This article provides complete details regarding the emergency management of life-threatening hypercalcemia with focus on vitamin D intoxication. At the other end of the spectrum, hypocalcemic emergencies, such as periparturient hypocalcemia (eclampsia), may be less common but are often life threatening. This article contains guidelines for the emergency management of hypocalcemia. In summary, the urgent care of calcium disorders in small animals is reviewed.     

Vitamin D toxicity. Initial site and mode of action

Two groups of weanling pigs, injected with 45Ca, were fed diets containing optimal calcium and phosphorus, and vitamin D3 at 1320 IU/kg feed in the control group, and 825,000 IU/kg feed in the test group. The groups were further subdivided with 2 pigs in each subgroup, with survival times of 1, 2, 3, 4, 7, and 14 days. Pigs fed the high level of vitamin D3 lost weight and anorexia, weakness, rough hair coat and labored breathing were observed. Hypercalcemia began at 12 hours and progressed rapidly after 2 days. Radioisotope sutdies interpreted in the light of histopathologic findings indicated that bone was the primary source of increased plasma calcium. Calcium was released at a rapid rate into blood from prelabeled bone which was undergoing necrosis; it was also removed from blood and deposited into bone at a slower rate due to decreased apposition. Histopathologic examination of bones from test pigs showed regressive changes in the osteocytes, chondrocytes and osteoblasts which bean within 1 day of treatment and resulted in evidence osteopenia within 7 days. Arrested osteocytic osteolysis led to the appearance of cementing lines and to chondroid core retention. Further regressive changes in the osteocytes resulted in osteocytic death and osteonecrosis with subsequent osteoclasia and osteopenia. Retardation and arrest of cartilage maturation as well as osteoblastic deficiency contributed to the osteopenia. The osteopenia was further evidenced by decreased specific gravity and ash content per unit volume of humerus. The initial negative effect on the osteocytes, chondrocytes and osteoblasts is attributed to a direct toxic effect of excessive dietary vitamin D3 since hypoparathyroidism and hypercalcitoninism, which occur secondarily to hypercalcemia, could not account for the rapid appearance of this effect, nor are they known to induce osteocytic death. The release of bone calcium and the resulting hypercalcemia in vitamin D3 toxicosis is therefore due to a direct toxic effect of the vitamin, or its metabolites, on the osteocyte resulting in osteonecrosis. It is not due to increased resorption as has been reported previously from both in vivo and in vitro investigations. Degeneration, with subsequent inflammation, but without calcification, was observed in the kidneys and in the lungs. Epithelial cells, basement membranes, and smooth muscle were affected. This conclusively demonstrates that degeneration is the primary soft tissue lesion in vitamin D3 toxicosis, and that the subsequent calcification is therefore dystrophic. Degenerative changes occurred in the parathyroid glands within 1 day of treatment resulting in necrosis, inflammation and atrophy within 4 days. Relative fibrosis was seen as the parenchyma receded. The parathyroid gland changes were considered a direct effect of vitamin D3 toxicity since they occurred with only mild hypercalcemia and since necrosis of parathyroid cells has not been demonstrated with hypercalcemia either in vivo or in vitro.     

Hypercalcemia associated with gastric pythiosis in a dog

A 20-month-old castrated male Labrador Retriever with a 3-month history of anorexia, weight loss, and vomiting was evaluated. Plasma biochemical abnormalities included marked hyperglobulinemia and hypercalcemia. Serum levels of parathyroid hormone, parathyroid hormone-related protein, 25-hydroxyvitamin D, and 1,25-dihydroxyvitamin D were either low or within reference intervals. Gastric wall thickening and abdominal lymphadenomegaly were observed with abdominal ultrasonography. Cytologic evaluation of a sample obtained via fine-needle aspiration of the gastric wall revealed pyogranulomatous inflammation and numerous poorly stained hyphae. Partial gastrectomy was performed, and a diagnosis of gastric pythiosis was made by immunohistochemical staining of infected gastric tissue, as well as by immunoblot serology. This case demonstrates that diagnostic samples for cytologic evaluation can be obtained by fine-needle aspiration of Pythium insidiosum-infected tissues and that a presumptive diagnosis can be made by examination of a Romanowsky-stained smear. Furthermore, pythiosis should be considered as a differential diagnosis for hypercalcemia, especially in young dogs with inflammatory lesions that have a granulomatous component. The mechanism for the hypercalcemia in this dog was not determined; however, calcium concentrations normalized after surgical resection of the gastric lesion.     

Hypercalcemia and high serum parathyroid hormone-related protein concentration in a horse with multiple myeloma

A 13-year-old gelding was examined because of weight loss, hyperglobulinemia, and hypercalcemia. Possible causes of hypercalcemia that were considered included renal failure, primary hyperparathyroidism, vitamin D toxicosis, and malignancy. There was no history of vitamin D ingestion, and serum creatinine and parathyroid hormone concentrations were normal, making renal failure and primary hyperparathyroidism unlikely. The hypercalcemia was suspected to be a result of malignancy, but thorough testing did not reveal any neoplastic disease. Eight months later, serum parathyroid hormone-related protein (PTHrP) concentration was high, supporting the suggestion that hypercalcemia was a result of malignancy. In addition, radial immunodiffusion confirmed a selective 300-fold increase in serum IgA concentration. The horse was euthanatized, and postmortem examination revealed neoplastic infiltrates in the kidneys, lymph nodes, liver, and bone marrow. Neoplastic cells had morphologic characteristics of plasma cells, and immunohistochemical staining confirmed that neoplastic cells were expressing PTHrP and IgA. The final diagnosis was multiple myeloma with expression of IgA paraprotein.     

Parathyroid hormone-related protein (PTHrP) produced by dog lymphoma cells

Parathyroid hormone-related protein (PTHrP) was investigated in a canine lymphoma case with hypercalcemia by means of immunoradiomentric assay (IRMA) and molecular analysis. The plasma calcium level of the patient dog was 13.7 mg/dl. The PTHrP concentration examined by IRMA was 6.1 pmol/L in the plasma sample from the dog, but it was undetectable (< 1.1 pmol/L) in plasma samples from 4 lymphoma cases without hypercalcemia or 5 normal dogs. The PTHrP concentration examined in the culture supernatant of the lymphoma cells from this case was 1.3 pmol/L, whereas those of the lymphoma cells from a lymphoma case without hypercalcemia was undetectable. PTHrP mRNA was clearly detected not only in the lymphoma cells from this dog with hypercalcemia but also in lymphoma cells from 4 lymphoma cases without hypercalcemia and 2 canine lymphoma cell lines.     

Endocrine Causes of Calcium Disorders

Endocrine diseases that may cause hypercalcemia and hypocalcemia include hyperparathyroidism, hypoparathyroidism, thyroid disorders, hyperadrenocorticism, hypoadrenocorticism, and less commonly pheochromocytoma and multiple endocrine neoplasias. The differential diagnosis of hypercalcemia may include malignancy (lymphoma, anal sac carcinoma, and squamous cell carcinoma), hyperparathyroidism, vitamin D intoxication, chronic renal disease, hypoadrenocorticism, granulomatous disorders, osteolysis, or spurious causes. Hypocalcemia may be caused by puerperal tetany, pancreatitis, intestinal malabsorption, ethlyene glycol intoxication, acute renal failure, hypopararthyroidism, hypovitaminosis D, hypomagnesemia, and low albumin. This article focuses on the endocrine causes of calcium imbalance and provides diagnostic and therapeutic guidelines for identifying the cause of hypercalcemia and hypocalcemia in veterinary patients.     

Primary Hyperparathyroidism Associated With Atypical Headshaking Behavior in a Warmblood Gelding

A 14-year-old Zweibrücker Warmblood gelding was presented for evaluation of lethargy and headshaking. The horse had a history of bouts of lameness in different limbs and back problems. It also had many mild colic episodes in the past. Results of repeat laboratory tests had shown persistent hypercalcemia (4.8 mmol/L; reference interval [RI]: 2.0–3.2 mmol/L) for 1.5 years and later on hypophosphatemia (0.4 mmol/L; RI: 0.5–1.3 mmol/L) and mild hypermagnesemia (1.0 mmol/L; RI: 0.5–0.9 mmol/L). Parathyroid hormone (PTH) concentration was within the RI. Other causes of hypercalcemia, such as renal failure, vitamin D toxicosis, and granulomatous disease, and nutritional secondary hyperparathyroidism were ruled out. Furthermore, there was no evidence of neoplastic disease. Parathyroid hormone–related protein was measured but inconclusive. A diagnosis of primary hyperparathyroidism was established on the basis of hypercalcemia, hypophosphatemia, low fractional excretion of calcium, and high fractional excretion of phosphorus in combination with a PTH secretion refractory to high calcium levels. Because of the bad prognosis, the owner decided to euthanize the horse. Results of postmortem examination were unremarkable. Hypercalcemia should always be considered abnormal, and further examinations need to be performed to proof hypercalcemia and subsequently find the cause. The main differential diagnoses are renal insufficiency and humoral hypercalcemia of malignancy, but also rare diseases, such as hyperparathyroidism, have to be taken into account.     

Experimental ectopic mineralization in young boars I. The role of supplemental vitamin D inthe etiology.

Young boars supplemented orally with 800, 500,300 and 100 IU of vitamin D2/kg of feed and control boars not supplemented with vitamin D2 for four months developed mineralization in the left atrial endocardium, lamina muscularis mucosae of the fundic stomach and other sites. Since low levels of supplementation with vitamin D2 did not eliminate the lesions, the levels of vitamin D2 added appeared not to be involved in the pathogenesis. All boars had mild hypercalcemia throughout the experiment, and phosphorus levels in sera were lower in all animals receiving than in those not receiving calciferol. Mild morphological lesions of rickets developed in several boars not receiving supplemental vitamin D2 and in boars supplemented with 100 an 300 IU/kg of feed.     

Salmon calcitonin as adjunct treatment for vitamin D toxicosis in a dog

Calcitonin was used in conjunction with saline diuresis, furosemide, and prednisone in treatment of a dog that consumed a rodenticide that contained cholecalciferol and has been touted as safe for nontarget species. This report shows that the rodenticide is toxic to dogs and that salmon calcitonin is a useful treatment for the often refractory hypercalcemia induced by vitamin D toxicosis.     

Uses and effectiveness of pamidronate disodium for treatment of dogs and cats with hypercalcemia

Uncorrected hypercalcemia can cause clinical signs such as polyuria, polydipsia, vomiting, diarrhea, lethargy, and depression and contributes to the development of primary renal failure and soft tissue mineralization. Treatment of hypercalcemia includes diagnosis and treatment of the underlying disease process and some combination of excracellular fluid volume expansion by administration of fluids intravenously and administration of glococorticosteroids, salmon calcitonin, and furosemide. Bisphosphonates such as pamidronate disodium also may be safe and effective in the treatment of hypercalcemia. The purpose of our study was to characterize the efficacy and safety of pamidronate in the treatment of hypercalcemia attritutable to several different disease processes in the dog and cat. Seven dogs and 2 cats were administered pamidronate at a dose of 1.05-2.0 mg/kg IV for a variety of disease processes, including neoplasia (n = 4), calcipotriene toxicity (n = 3), nocardiosis (n = 1), and idiopathic hypercalcemia with chronic renal failure (n = 1). In all the animals, IV pamidronate administration rapidly decreased serum calcium concentrations without evident toxicosis. Two animals received pamidronate several times without obvious toxicosis. On the basis of the findings in our retrospective study, pamidronate may be a safe and effective drug with which to lower both serum total and ionized calcium concentrations in patients with hypercalcemia arising from a wide variety of underlying disease processes.     

Hypercalcemia

Elevated serum calcium occurs relatively uncommonly in dogs and rarely in cats. Hypercalcemia can serve as a marker of disease that enables diagnosis but may also contribute to development of lesions and the clinical signs of disease. Specific clinical signs do not necessarily accompany hypercalcemia, and its presence will frequently be unsuspected. Fortuitous hypercalcemia is often discovered after a review of serum biochemical profile results. This article emphasizes malignancy-associated hypercalcemia and the emergence of cholecalciferol rodenticide toxicity as an important cause of hypercalcemia, as well as its treatment.     

Pseudohyperparathyroidism in a mare associated with squamous cell carcinoma of the vulva

An 18-year-old Appaloosa mare was examined because of squamous cell carcinoma of the vulva, anorexia with pronounced weight loss, and hypercalcemia. The tumor had developed rapidly over a period of 3 months and externally extended ventrally involving the perineum and the dorsal aspect of the udder. Necropsy examination demonstrated a large primary squamous cell carcinoma of the vulva, perineum, and mammary gland with metastases to the supramammary, sublumbar, deep inguinal, and mediastinal lymph nodes. No gross renal lesions were observed and, histologically, there was only mild vacuolation of renal tubular epithelium. Based on the normal concentration of serum parathyroid hormone, the absence of evidence of hypervitaminosis D, and normal renal function, a diagnosis was made of hypercalcemia of malignancy or pseudohyperparathyroidism. The mechanism responsible for hypercalcemia was not determined, but the histologic type of the neoplasm and the clinical course suggested possible production of a humoral hypercalcemic factor by the neoplasm, similar to that demonstrated in certain types of human squamous cell carcinoma.     

Hypercalcemia associated with malignancy in a horse

Hypercalcemia associated with malignancy was diagnosed in a 2-year-old Thoroughbred filly admitted because of weight loss and reduced exercise tolerance of approximately 2 months' duration. Laboratory findings included hypercalcemia, hypophosphatemia, anemia, marked neutrophilia with lymphopenia and eosinopenia, and normal immunoreactive parathyroid hormone concentration. At necropsy, a 53.6-kg tumor was located in the cranioventral aspect of the abdominal cavity. Gross renal lesions were not noticed. Bone tissue appeared to be normal on gross and histologic examinations. The parathyroid glands were not grossly identified at necropsy. A specific test does not exist for detection of hypercalcemia associated with malignancy. The diagnosis of hypercalcemia associated with malignancy was made on the basis of clinical history, physical examination, radiographic interpretation, laboratory findings, histologic examination, and ruling out other causes of hypercalcemia. Hypercalcemia, increased renal phosphate excretion in the presence of hypophosphatemia, absence of bone metastases, and identifying an abdominal mesenchymal tumor that may have originated from the left ovary satisfied the basic criteria for hypercalcemia associated with malignancy from a solid tumor.     

Hypercalcemia: a quick reference.

This article serves as a quick reference for hypercalcemia. Guidelines for causes, clinical signs, analysis, and diagnosis are presented in a stepwise approach.     

Ionized hypercalcemia in cats with azotemic chronic kidney disease (2012‐2018)

BackgroundHypercalcemia is associated with chronic kidney disease (CKD) in cats, but studies assessing the physiologically relevant ionized calcium fraction are lacking.ObjectivesTo describe the prevalence and incidence rate of ionized hypercalcemia, and to explore predictor variables to identify cats at risk of ionized hypercalcemia in a cohort of cats diagnosed with azotemic CKD.AnimalsOne hundred sixty‐four client‐owned cats with azotemic CKD.MethodsVariables independently associated with ionized hypercalcemia at diagnosis of azotemic CKD were explored by binary logistic regression. Cats that were normocalcemic at diagnosis of azotemic CKD were followed over a 12‐month period or until ionized hypercalcemia occurred and baseline predictor variables for ionized hypercalcemia explored using Cox proportional hazards and receiver operating characteristic curve analysis.ResultsIonized hypercalcemia (median, 1.41 mmol/L; range, 1.38‐1.68) was observed in 33/164 (20%) cats at diagnosis of azotemic CKD and was associated with male sex, higher plasma total calcium and potassium concentrations, and lower plasma parathyroid hormone concentrations. Twenty‐five of 96 initially normocalcemic (26%) cats followed for minimum 90 days developed ionized hypercalcemia (median, 1.46 mmol/L; range, 1.38‐1.80) at a median of 140 days after diagnosis of azotemic CKD (incidence rate, 0.48 per feline patient‐year). Only body condition score was independently associated with incident ionized hypercalcemia.Conclusions and Clinical ImportanceThe occurrence of ionized hypercalcemia is high in cats with CKD. Continued monitoring of blood ionized calcium concentrations is advised.     

Bone pathology in hypervitaminosis D an experimental study in young pigs.

Five groups of 4 weanling pigs were fed a diet with 1.2% calcium and 1.0% phosphorus for 8 weeks with vitamin D3 at 1, 5, 25, 125 and 625 times the recommended levels, respectively. Hypercalcemia and hypophosphatasemia developed rapidly and persisted in Group 5 and developed more slowly but steadily in Group 4. Increasing levels of vitamin D3 influenced progressively and negatively the activity of resorbing osteocytes with osteopetrosis in Groups 2 and 3 and with osteonecrosis in Group 5. Atrophy of osteoblasts further contributed to the osteopenia in Group 5. Cartilage growth activity was arrested in Group 5. The negative effect on the resorbing osteocytes, which finally lead to death of the cells, was ascribed directly to vitamin D3 toxicosis since hypoparathyroidism and hypercalcitonism, both resulting from hypercalcemia, are not known to induce osteonecrosis. Since hypercalemia was finally as severe in Group 4 as in Group 5 and since there was soft tissue calcinosis only in Group 5, the calcinosis was always considered dystrophic, an interpretation supported by the observation that degenerative histologic changes preceded soft tissue calcinosis.     

Ionized Hypercalcemia in Dogs: A Retrospective Study of 109 Cases (1998–2003)

Background: Serum hypercalcemia in dogs has been reported in association with a variety of diseases. Serum-ionized calcium (iCa) concentration is a more accurate measure of hypercalcemia than total serum calcium or corrected serum calcium concentrations. The severity of hypercalcemia has been utilized to suggest the most likely differential diagnosis for the hypercalcemia.
Hypothesis: Diseases causing ionized hypercalcemia may be different than those that cause increases in total or corrected serum calcium concentrations. The severity of ionized hypercalcemia in specific diseases cannot be used to determine the most likely differential diagnosis for ionized hypercalcemia.
Animals: One-hundred and nine client-owned dogs with a definitive cause for their ionized hypercalcemia evaluated between 1998 and 2003 were included in this study.
Methods: Retrospective, medical records review.
Results: Neoplasia, specifically lymphosarcoma, followed by renal failure, hyperparathyroidism, and hypoadrenocorticism were the most common causes of ionized hypercalcemia. Dogs with lymphoma and anal sac adenocarcinoma have higher serum iCa concentrations than those with renal failure, hypoadrenocorticism, and other types of neoplasia. The magnitude of serum-ionized hypercalcemia did not predict specific disease states.
Conclusions and Clinical Importance: Serum-ionized hypercalcemia was most commonly associated with neoplasia, specifically lymphosarcoma. Although dogs with lymphosarcoma and anal sac adenocarcinoma had higher serum iCa concentrations than dogs with other diseases, the magnitude of the serum iCa concentration could not be used to predict the cause of hypercalcemia. Total serum calcium and corrected calcium concentrations did not accurately reflect the calcium status of the dogs in this study.     

Idiopathic hypercalcemia in cats

Unexplained hypercalcemia has been increasingly recognized in cats since 1990. In some instances, hypercalcemia has been associated with calcium oxalate urolithiasis, and some affected cats have been fed acidifying diets. We studied the laboratory findings, clinical course, and treatment of 20 cats with idiopathic hypercalcemia. Eight (40%) of the cats were longhaired and all 14 cats for which adequate dietary history was available had been fed acidifying diets. Clinical signs included vomiting (6 cats), weight loss (4 cats), dysuria (4 cats), anorexia (3 cats), and inappropriate urinations (3 cats). Hypercalcemia was mild to moderate in severity. and serum parathyroid hormone concentrations were normal or low. Serum concentrations of phosphorus, parathyroid hormone-related peptide, 25-hydroxycholecalciferol, and calcitriol were within the reference range in most cats. Diseases commonly associated with hypercalcemia (eg, neoplasia, primary hyperparathyroidism) were not identified despite thorough medical evaluations and long-term clinical follow-up. Azotemia either did not develop (10 cats) or developed after the onset of hypercalcemia (3 cats), suggesting that renal failure was not the cause of hypercalcemia in affected cats. Seven of 20 cats (35%) had urolithiasis, and in 2 cats uroliths were composed of calcium oxalate. Subtotal parathyroidectomy in 2 cats and dietary modification in 11 cats did not result in resolution of hypercalcemia. Treatment with prednisone resulted in complete resolution of hypercalcemia in 4 cats.     

Severe calcification of mucocutaneous and gastrointestinal tissues induced by high dose administration of vitamin D in a puppy

A three-month-old male Bull Terrier was referred to the Animal Medical Centre, Nihon University with chief complaints of subacute emesis and lethargy. Severe leukocytosis, high CRP, hypercalcemia and hypochloremia were detected. Moreover, severe calcification of gingival mucosa and abdominal skin, and abnormalities of the skeletal system were discerned. Abdominal X-ray and endoscopic examination revealed ulcer and hemorrhage on the mucosal membrane of the stomach. This might have been due to injections of high dose vitamin D at 3 and 2 weeks ago by another practioner, according to the detailed history of medication. After two months, a gastrointestinal and skin disorder disappeared, although calcification of the stomach membranes remained and abnormality of the skeletal system had worsened. Therefore, vitamin D should be carefully administrated to a puppy.     

Metastatic calcification in a dog attributable to ingestion of a tacalcitol ointment

A 22-week-old 21-kg female Bernese Mountain Dog ingested a topical antipsoriatic preparation containing the synthetic vitamin D analog tacalcitol. The dog died after a history of lethargy, recumbency, paresis of the hindlimbs, increased rectal temperature, dyspnea, and hematemesis. Histologic examination revealed metastatic calcification in the kidneys, lungs, myocardium, brain, stomach, and tear glands. The appearance of soft tissue mineralization in multiple organs is consistent with hypercalcemia derived from excessive vitamin D uptake. Oral toxicity studies for tacalcitol in the dog are not available, but the present report emphasizes the extraordinary toxic risk of drugs containing this vitamin D analog to dogs.