Calcium and Phosphate Metabolism Lecture VIII PDF

Summary

This lecture covers the processes of calcium and phosphate metabolism within the human body. It includes a detailed look at the roles of these essential minerals within bone tissues, and the cellular processes controlling bone formation and breakdown. Key aspects of bone formation, the structure of bone, and regulation mechanisms are explored.

Full Transcript

Calcium and Phosphate
Metabolism

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Bone Physiology

Function of Bone

Structural support
Protection of internal organs and soft tissues from damage
Locomotion
60% inorganic
10% water
Mineral storage
30% organic
Production of blood cells
Endocrine regulation

Bone undergoes continuous turnover/remodeling
through life
About 20% of bone is undergoing remodeling at any
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Bone - Inorganic Portion (67%)

Hydroxyapatite Crystals Ca10(PO4)6(OH)2
Embedded in collagen matrix
Approx. 60–70% dry weight of bone

Provides structural strength
Facilitates bone regeneration

Other Ions Present
Na+, K+, Mg2+, CO32-, Ba2+, Zn2+
Reduce the crystallinity of bone
minerals
Alter solubility Facilitating bone Universit
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 Bone – Organic Portion (aka osteoid) (33%)
Collagenous Proteins
Type I collagen (28%)
Ligaments and Tendons
Triple helix Structure

Provides structural support
Contributes to mechanical properties of bone
Flexibility
Resistance to tensile forces.

Also Other forms Type III, IV

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 Bone – Organic Portion (aka osteoid) (33%)
Non-collagen structural proteins

Proteoglycans – Macromolecules with core polypeptide and glycosaminoglycan (e.g. Hyaluronic
acid)
Organization of Bone Extracellular Matrix, Collagen Fibrillogenesis
Sialoproteins — highly glycosylated and sulphated phosphoprotein
Mineralization and Bone Formation

Bone specific proteins
Osteocalcin—Bone Formation and Osteoclasts Activity
Osteonectin—Modulate GF Activity, Cell adhesion, Mineralization
Osteopontin—Regulates Bone Formation, Migration, Adhesion, and Mineralization
RANKL (Receptor Activator of Nuclear Factor κ-B Ligand)—Regulation of Bone Resorption

Growth factors and cytokines (Trace)

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Bone Remodeling
Osteoclasts dissolve bone
Large multinucleated giant cells

Osteoblasts produce bone
Have receptors for PTH, CT, Vitamin D, cytokines, and growth factors
Main product is collagen

When osteoblasts become encased in bone, they become osteocytes

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 Bone Cells
Osteoblasts Osteoclasts
Bone Formation
Bone Resorption
Synthesis of matrix proteins
Degradation of proteins by
Type I collagen
enzymes
Osteocalcin
Acidification
OtherBone Proteins
Mineralization
Activation of osteoclasts via RANKL RANK is activated by RANKL, and
production this leads to cells differentiation
to osteoclasts

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Bone Remodeling

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2nd Response to Regulating Bone Remodeling

Wolff’s Law
Bone grows or remodels in response to the forces or stresses placed on it.

Appositional growth
Growth in diameter is controlled by the amount of mechanical stress and gravity
placed on the bone

Heavy usage leads to heavy bones; non-use leads to atrophy (bone loss)
Astronauts lose bone mineral density as a result of spending time in space
Paralysis or prolonged immobilised

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 Wolffs Laws Law On Bone Explained

Piezoelectricity – Tissues Response Whereby:
Bone Generates an Electric Charge in Response to Applied Mechanical Stress
Action potential Generated
Osteocytes Release Factors that Stimulate Osteoblastic Activity
Bone growth and Increased Density to Withstand Forces Placed on it

Absence of mechanical forces osteoclastic activity increased
Weaker and less dense bone

Natural Mechanical Stress Applied to Femur Altered after Total Hip Replacement
Metal Implant Carries Some of the Load Reducing Stress on Femur
Phenomenon is known as Stress Shielding
Loss of Bone Mass Through Resorption After Hip Transplant
Occur Around the Implant Resulting in a Loosening of the Prosthetic Implant

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Controlling Bone Remodeling
Hormones PTH and Calcitonin
Determines whether and when bone remodeling occurs.

Mechanical Stress
Determines where remodeling occurs. High stress areas grow appositionally.

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Calcium
and
Phosphate

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Phosphate
Found in Bone, ATP, cAMP, proteins etc – regulate cell fnc

Total body phosphate = 500-800g [85-90% skeleton]

Plasma phosphate = 3- 4.5 mg/dl (0.9 -1.3mM)

Circulates as Orthophosphate (PO4)

Free filtered by kidney – 85% reabsorbed

15% excreted as urinary buffer

Absorbed in intestine by Na+ transporter

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Calcium
Total Calcium in body = 1100g (90% in skeleton)
Total Plasma Calcium in plasma = 2.2-2.6mmol/L

Function
Nerve and muscle excitability, Neurotransmission
Excitation-contraction coupling in muscle
Enzyme co-factor, Bone
Second Messenger, Fertilisation, Mitosis

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 Body Requirements
Age (in years) Calcium Requirement
1–3 500mg
4-8 800mg
9 - 18 1300mg
19 - 50 1000mg
51+ 1500mg (Post Menopausal Women)

*Pregnant and lactating women are recommended a daily calcium intake of
1000mg.

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Plasma Calcium Regulation
Plasma calcium totals 2.4 mM (9.4 mg/dl)
Free calcium is 1.2 mM

Free ionised calcium is tightly
regulated (5%)
Too low = Neuronal hyper-excitability
Too high = Neuronal depression

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Total Calcium Measurement can be Mis-leading

Low Albumin:
Malnutrition, liver disease, or nephrotic syndrome
Total calcium levels might appear falsely low
However the levels of ionized calcium remain unchanged

Corrected calcium provides a more accurate reflection of calcium status by adjusting for
albumin levels
Estimate a patient's true calcium levels in the blood, accounting for variations in serum
albumin levels

Corrected calcium (mg/dL) = measured total Ca (mg/dL) + 0.8 (4.0 - serum albumin
[g/dL])

4.0 -average albumin level: 0.8 - correction factor Universit
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Calcium Transport in the Blood
Ionized fraction depends on pH:
protein binding decreases as pH decreases

Alkalosis: increased calcium binding to
protein;
decreased ionised fraction
pH 7. 45 Hpocalcaemic effects
Each 0.1 decrease in pH increases ionized
pH 7.35 calcium by 0.05 mmol/L

Acidosis: decreased calcium binding to
protein; Universit
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increased ionised fraction
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Calcium Homeostasis
Three systems: bone, kidney, intestine
Three hormones: parathyroid hormone, calcitonin, vitamin D

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Regulated Tightly Intracellular and
ICF - [Ca2+] = 10-7M
Extracellular
ECF [Ca2+] = 10-3M
1: 10,000 Ratio [Ca ]
2+

Intracellular Increase Rapidly for Cell Function
Stored in Mitochondria and ER

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Parathyroid Hormone (PTH)
Produced by Parathyroid gland (4)
Located under thyroid
Chief cells

Primary function to regulate [Ca2+] in ECF
Low Ca → inc secretion of PTH
2+

→ PTH act on bone, kidney and intestine
→ Increases plasma [Ca2+]

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Parathyroid Hormone (PTH)

Polypeptide 84 amino acid residues
Peptide fragments can be active for hours Universit
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Acts via cAMP second messenger ofGalway.
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Regulation of PTH secretion

Ca2+ sensing receptors on chief cell

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Regulation of PTH Secretion

Ca sensing receptors on chief cell
2+

Normal or Increased ECF [Ca2+] – Inhibition of PTH
Ca2+ binding → activates PLC →  IP3/Ca2+ → Inhibits PTH

Decreased ECF [Ca2+] – Rapid increase in PTH
 Ca2+ bound →  PLC activation →  IP3/Ca2+ → No PTH Inhibition

Long-term effects - alter gene transcription, synthesis, storage of PTH

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PTH on Bone
PTH receptors on osteoblasts (not osteoclasts)

Initially PTH cause increase bone formation (briefly)
Basis for PTH in trt osteoporosis

Long-lasting effect to increase bone resorption
↑osteoclast activity indirect via cytokines release from osteoblast
↑ no of osteoclasts; ↓ no of osteoblasts

Increase Ca2+ and Phosphate to ECF
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Filtered at glomerulus - calcium enters the proximal
tubule

Proximal Convoluted and Proximal Straight Tubule
60%–70% of the filtered calcium is reabsorbed

Cortical segments of the loop of Henle
20% of the filtered calcium is reabsorbed

Distal convoluted tubule
Approx. 10% of the filtered calcium is
reabsorbed
PTH sensitive
 Distal Convoluted Tubule

Calcium enters the cell via TRPV5 channels

Binds calbindin D-28k intracellular

Exits the cell by 2 pathways:
Sodium/calcium exchanger (NCX1)
Calcium (ATPase PMCA4)

PTH stimulate calcium absorption via activation of
TRPV5, NCX1
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PTH on Kidney and Intestine
Intestine

Indirect action to stimulate Ca2+ absorption

Via Activation of Vitamin D

Stimulates 1α-hydroxylase and conversion of 25-hydroxycholecalciferol to 1,25-
hydroxycholecalciferol

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