Calcium

Question 1

What are functions of Calcium?

Answer 1

• Structure
• Protection
• Huge repository of calcium
• Muscle function/contraction
• Cell signalling
• Blood coagulation cascade

Question 2

What is involved in Calcium Homeostasis?

Answer 2

• ​Achieved through interaction between calciotropic hormones and their effector tissues in the kidney, intestine and bone. Key to this is the calcium-PTH axis
• Vitamin D and vitamin D receptors expressed within nucleus of parathyroid cells, play important role in calcium homeostasis

Question 3

What are the forms of Calcium distributed through the body?

Answer 3

• Calcium Hydroxyapatite
• Calcium Phosphate
• Intracellular Calcium
• Plasma Calcium - bound calcium to Proteins and Anions, Ionised Calcium

Question 4

What are reference ranges for calcium?

Answer 4

• Ionised calcium = 1.13-1.32 mmol/L

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• Adjusted calcium = 2.20-2.60 mmol/L

Question 5

What is Hypocalcaemia and Hypercalcaemia?

Answer 5

• Hypocalcaemia = Adjusted calcium <2.20 mmol/L
• Hypercalcaemia = Adjusted calcium >2.60 mmol/L

Question 6

What is the equation for Adjusted Calcium?

Answer 6

Measured [Ca] + (40 - [albumin]) x 0.02) = Adjusted [Ca]

Question 7

What are some drawbacks to Adjusted Calcium?

Answer 7

• Relationship poor at extremes of relationship
• Population specific – based on ‘healthy’ population
• ?Use in ITU – ionised more useful.
• Ionised calcium clinically more useful but impractical
• Method specific – BCP/BCG (albumin); calcium (NM-BAPTA/AZ-III/CPC)

Question 8

Where is Parathyroid Hormone secreted from?

Answer 8

• PTH is synthesised, stored and secreted by chief cells which are in parathyroid glands.
• Concentration of PTH in plasma determined by its synthesis and secretion by parathyroid glands
• Magnesium is essential for secretion of PTH parathyroid gland
• PTH acts directly on bone and kidney
• Indirectly on intestine to regulate [Ca2+] and [PO4]

Question 9

Which organs metabolise and clear PTH?

Answer 9

Metabolism and clearance determined by liver and kidneys

Question 10

Which are features of the calcium sensing receptors?

Answer 10

• G-protein coupled receptor
• Expressed in parathyroid and renal tubules of kidney

Question 11

Which intracellular signalling pathways are triggered by Calcium Sensing Receptors?

Answer 11

There are 2 major pathways depending on the ionised [calcium]

• Hypo – AC/cAMP pathway
• Hyper – PLC/IP3/DAG pathway

Question 12

Describe the process of calcium regulation from detection by the calcium sensing receptor?

Answer 12

• CaSR in the parathyroids detects reductions in extracellular Ca2+ and leads to the release of PTH
• PTH acts on the PTH1 receptor (PTH1R) to increase resorption of Ca2+ from bone, promote urinary Ca2+ reabsorption and increase expression of the renal 1-α-hydroxylase (1αOHase) enzyme, which converts the 25-hydroxyvitamin D (25D) precursor metabolite to biologically active 1,25-dihydroxyvitamin D (1,25(OH)2D).
• The elevated levels of 1,25(OH)2D increase absorption of dietary calcium by acting on the intestinal vitamin D receptor (VDR).
• CaSR in the renal cortical thick ascending limb also acts independently of PTH to regulate urinary Ca2+ reabsorption
• Increases in Ca2+ and 1,25(OH)2D concentrations lead to negative feedback on the parathyroid glands, thereby inhibiting further PTH release.

Question 13

How is Calcium transported through the body?

Answer 13

• Calbindin-D is vital in transport of calcium from lumen to lamina propria (ileum and duodenum are main sights for absorption)

Question 14

Where is the Calcium Sensing Receptor expressed in the kidneys?

Answer 14

CaSR is expressed in the following portions of the nephron:

• Apical membrane of the proximal tubule (60-70 % Ca2+ reabsorbed here), where it regulates 1,25(OH)2D synthesis and inorganic phosphate (Pi) excretion
• Basolateral membrane of the cortical thick ascending limb of the loop of Henle
• Apical membrane of the distal convoluted tubule, where it regulates Ca2+ reabsorption

Question 15

What is the action of Calcium Sensing Receptor in the mammary glands?

Answer 15

• CaSR in the mammary gland detects reductions in Ca2+, which leads to increased PTH-related peptide (PTHrP) secretion from mammary epithelial cells into the circulation.
• PTHrP acts on the PTH1R to increase bone resorption, which in turn releases Ca2+ for milk production.

Question 16

What are the parathyroid hormone actions?

Answer 16

Bone

• Osteolysis
• Differentiation of osteoclasts
• Regulation of osteoblasts (bone remodelling)
• Bone resorption or formation (depends on duration of exposure and concentration

Kidneys

• Reabsorption of Ca2+
• Inhibition of phosphate reabsorption
• Hydroxylation of 25(OH) vitamin D
• Bicarbonate excretion (inhibits Na+-H+ anti-porter activity

Question 17

How can PTH Mobilisation be described?

Answer 17

PTH mobilisation of calcium is biphasic

• A rapid phase involving existing cells
• Long term response dependent on proliferation of osteoclasts

Question 18

What happens to Serum and Urinary Calcium in the event of increased PTH?

Answer 18

• Increase in serum total and free calcium
• Urinary calcium is increased when larger filtered load of calcium from bone resorption and intestinal reabsorption overrides increased tubular reabsorption of calcium
• In absence of disease the increase in serum calcium reduces PTH secretion through negative feedback loop maintaining homeostasis.

Question 19

What is PTH related peptide?

Answer 19

• Synthesized in various tissues including keratinocytes, lactating mammary tissue, placenta and foetal parathyroid glands
• Actions similar to PTH and binds to PTH receptors
• Important in regulating Ca2+ fluxes between foetal and maternal circulations, Ca2+ concentrations in breast milk and a role in foetal development
• Tumour marker
• RR <1.8 pmol/L

Question 20

How does PTHrP differ to PTH?

Answer 20

• PTHrp does not increase renal 1α-hydroxylase enzyme activity

Question 21

What is Calcitonin?

Answer 21

• Produced by parafollicular C-cells of thyroid gland. It is a 32 amino acid peptide
• Inhibits bone resorption by acting on the osteoclast
• Not significant in the regulation of normal calcium homeostasis

Question 22

What can Calcitonin be used for in management?

Answer 22

Its potent anti-resorptive effect has led to its use in treating

• Paget’s bone disease
• Osteoporosis
• Hypercalcaemia
• Osteogenesis imperfecta

Question 23

What can lead to deviations in Calcium Homeostasis?

Answer 23

Hypercalcaemia

• Increased GI absorption
• Increased bone resorption
• Decreased bone mineralisation
• Decreased urinary excretion

Hypocalcaemia

• Decreased GI absorption
• Decreased bone resorption
• Increased bone mineralisation
• Increased urinary excretion

Question 24

What are reference ranges for Hypocalcaemia?

Answer 24

• Mild adjusted calcium: >2.0-<2.2 mmol/L
• Moderate adjusted calcium: 1.8-2.0 mmol/L
• Severe adjusted calcium: <1.80 mmol/L

Question 25

What are causes of Hypocalcaemia?

Answer 25

• Hypothyroidism: Magnesium deficiency, Post-surgical damage or neck irradiation, Infiltrative (e.g haemachromatosis,wilson’s disease and metastases), Genetic (DiGeorge syndrome)
• Parathyroid hormone resistance: Pseudohypoparathyroidism
• Abnormalities of vitamin D metabolism: Vitamin D deficiency
• Deficient A1-hydroxylase enzyme activity: Chronic Kindey disease, Acidosis, Vitamin D-dependant rickets type 1
• Vitamin D resisitance: Vitamin D-dependant rickets type 1
• Others: Spurios, Acute Pancreatitis, Sepsis, Blood trnasfusion, Rhabdomyolysis, Bisphosphonate therapy, Hungry bone syndrome

Question 26

How does CKD affect calcium metabolism?

Answer 26

• Fall in calcium: Decreased conversion 25(OH)D to 1,25(OH)2D
• Increase in phosphate: Kidneys not excreting excess. FGF-23 has role in monitoring phsopahate
• Increase in PTH: Stimulated by low calcium. Continual stimulation of parathyroid glands leads to secondary hyperparathyroidism
• Patients with end stage renal failure can become hypercalcaemic. Probably due to development of autonomous PTH secretion from prolonged hypocalcaemic stimulus
• Such hypercalcaemia may manifest for the first time in a renal transplant patient who becomes able to metabolise vitamin D normally leading to Tertiary hyperparathyroidism

Question 27

What is Pseudohypoparathyroidism (PHP)?

Answer 27

• Resistance to PTH and various other glycoprotein hormones.
• PTH resistance at the kidney so patients so hyperparathyroid bone disease

Question 28

What is Ellsworth-Howard test?

Answer 28

Involves measurement of serum and urinary phosphate and cAMP after intravenous administration of parathyroid extract; used in the diagnosis of pseudohypoparathyroidism. 6-30min urine collections and corresponding serum samples

• Normally 10-12 fold increase in cAMP, fall in TmP/GFR of 20%
• Pseudo type I: <5-fold increase in cAMP, <10% fall in TmP/GFR
• Pseudo type II: normal response to cAMP, <10% fall in TmP/GFR

Question 29

What are symptoms of Hypocalcaemia?

Answer 29

• Paraesthesia
• Circumoral numbness
• Cramps
• Anxiety
• Tetany are followed by convulsions
• Laryngeal stridor
• Dystonia
• Psychosis

Question 30

What are clinical signs of Hypocalcaemia?

Answer 30

• Chvostek’s sign: Gentle tapping over the facial nerve causes twitching of the ipsilateral facial muscles
• Trousseau’s sign: Inflation of the sphygmomanometer cuff above systolic pressure for 3 minutes induces tetanic spasm of the fingers and wrist

Question 31

What are ECG changes of Hypocalcaemia?

Answer 31

• Prolongation of the QT-interval
• Narrowing of the QRS complex
• Reduced PR interval
• T wave flattening and inversion
• Prominent U-wave

Question 32

How is Hypocalcaemia treated?

Answer 32

Treat underlying condition

• Acute symptomatic patient (10-20 mL 10 % calcium gluconate over 5 mins, Follow with continuous infusion of 9-18mmol/2L/24 h)
• Magnesium replacement
• Cholecalciferol (Vitamin D3)
• Alfacalcidol (1-α hydroxylated vitamin D3) - Given when 1-αhydroxylation defective (1-4 µg/day) e.g. hypoparathyroidism, VDDR I
• Calcitriol (1,25(OH)2 vitamin D3) - 0.75-2.25 µg/day

Question 33

What are reference ranges for Hypercalcaemia?

Answer 33

• Mild adjusted calcium >2.60-<3.0 mmol/L
• Moderate adjusted calcium 3.0-3.5 mmol/L
• Severe adjusted calcium >3.5 mmol/L

Question 34

What are causes of Hypercalcaemia?

Answer 34

• Parathyroid hormone mediated: Sporadic (adenoma, hyperplasia or carcinoma) , familial , Ectopic parathyroid hormone in malignancy, tertiary hyperparathyroidism
• Malignancy: Humoral hypercalcaemia of malignancy, Local osteolysis, Ectopic parathyroid hormone in maignancy, calcitriol related hypercalcaemia
• Vitamin D related: Granulomatous disease, Vitamin D intoxication
• Endocrine Disorders: Thyrotoxicosis, Adrenal insufficiency, Pheochromacytoma, VIPoma (Verner-Morison) syndrome
• Drugs: Thiazide diuretics, Lithium, Milk-Alkali syndrome, Vitmain A, Parathyroid Hormone
• Others: Coexisting malignancy and primary hyperparathyroidism, immobilisation, Acute renal failure, Chronic renal failure treaed with calcium and calcitriol or vitamin D analogues, Renal Transplant

Question 35

What are types of Hyperparathyroidism?

Answer 35

• Primary: One or more parathyroid glands secrete excess parathyroid hormone
• Secondary: Increased secretion of this hormone is a response to lowered ionised calcium as a result of kidney, liver, or bowel disease
• Tertiary: State of autonomous secretion of parathyroid hormone usually occurs as a result of longstanding chronic kidney disease

Question 36

What is Primary Hyperparathyroidism?

Answer 36

One or more of the four parathyroid glands secrete excess PTH, resulting in hypercalcaemia

• Parathyroid gland adenoma
  
  • 1 gland: 80 %
  • 2-3 glands: 10-11 %
  • ≥4 glands <10 %
• Parathyroid carcinoma is rare (~1 %).

Question 37

What are typical biochemical features of Primary Hyperparathyroidism?

Answer 37

• Increased PTH
• Long Hx of moderate hypercalcaemia
• Development of nephrolithiasis
• Plasma PO4 low in 50% cases
• Hyperchloraemic metabolic acidosis
• Normal ALP seen in 50% of cases

Need to confirm Dx with clinical and radiological evidence

Question 38

What are indications for parathyroid surgery in PHPT?

Answer 38

• Serum calcium 0.24 mmol/L above the upper limit of the normal range, for patients younger than 50 years of age
• Men and peri-menopausal or postmenopausal women ≥50 years of age who have T scores of −2.5 or lower at a central bone densitometry site or in the distal third of the radius or who recently have had a fragility fracture
• GFR <60 mL/min/1.73 m2
• Renal stones, and a urine calcium level of >400 mg per day (10.0 mmol per day)

Question 39

What causes Hypercalcaemia in Malignancy?

Answer 39

• Erosion of bone by secondaries
• Production of PTH like substance e.g. PTHrP
• Prostaglandin produced by tumour
• Production of osteoclast activating factor
• Coincidence of hyperparathyroidism
• Ectopic PTH

Question 40

What is Familial Hypocalciuric Hypercalcaemia?

Answer 40

• Autosomal dominant
• Patients are heterozygous for inactivating mutations in the calcium sensing receptor (CaSR)
• Set point for PTH increased, mild PTH dependent hypercalcaemia develops with hypocalciuria
• In FHH inappropriate avid reabsorption of Ca2+
• Largely asymptomatic (accounts for 2 %)

Question 41

What are symptoms and signs of FHH?

Answer 41

• Lethargy
• Polydipsia
• Pancreatitis

Neonates with two mutations present with severe life threatening hypercalcaemia

Question 42

How is FHH differentiated from PHP?

Answer 42

UCa/Cr Cl ratio = (U[Ca] (mmol/L) x P[Creat] (µmol/L) / (P[Ca] (mmol/L) x U[Creat] (mmol/L)

Ca/Cr Cl ratio:

• <0.01 in FHH
• >0.015 in PHP

Question 43

What are signs and symptoms of Hypercalcaemia?

Answer 43

• Tiredness
• Malaise
• Dehydration
• Depression
• Renal colic from stones
• Polyuria or nocturia
• Haematuria
• Hypertension occurs
• May have bone pain. Hyperparathyroidism mainly affects cortical bone
• Bone cysts and locally destructive ‘brown tumours’ occur but only in advanced disease
• Bone disease may be more apparent when there is coexisting vitamin D deficiency
• Abdominal pain
• Chondrocalcinosis and ectopic calcification (rare)
• Corneal calcification (long-standing hypercalcaemia)

Question 44

What are ECG changes in Hypercalcaemia?

Answer 44

Hypercalcaemia speeds up repolarisation

• Mild: Broad based tall peaking T waves
• Severe: Extremely wide QRS, Low R wave, Disappearance of p waves, Tall peaking T waves.

Question 45

What is the treatment of Hypercalcaemia?

Answer 45

Mandatory if the patient is seriously ill or if Ca2+ >3.0 mmol/L

• Rehydrate 4-6 L of 0.9 % saline on day 1, and 3-4 L for several days thereafter
• IV bisphosphonates: Treatment of choice in malignancy and of undiagnosed cause. Zolendronate (4 mg) in 0.9 % saline and Pamidronate (60-90 mg) in 0.9 % saline
• Prednisolone (30-60 mg daily): Used in granulomatous disease
• Calcitonin (200 units i.v. 6-hourly, maximum use 5 days): Has short-lived action

Question 46

What are requirements for patients before the use of Bisphosphonates?

Answer 46

• Ensure eGFR >60 mL/min/1.73 m2
• [Ca2+] fall after 24-72 hours, lasting for approximately two weeks

Question 47

What are imaging techniques for Hypercalcaemia?

Answer 47

• Abdominal X-rays may show renal calculi or nephrocalcinosis
• High-definition hand X-rays can show sub-periosteal erosions in the middle or terminal phalanges
• DEXA bone density scan is useful to detect bone effects in asymptomatic patients with HPT in whom conservative management is planned
• USS which, though insensitive for small tumours, is simple and safe
• High-resolution CT scan or MRI (more sensitive)
• Radioisotope scanning using technetium (99mTc)sestamibi: 90 % sensitive in detecting adenomas