Blood Physiology PDF

Summary

This document provides a comprehensive overview of blood physiology. It covers the composition, types, and functions of blood components, like red blood cells, white blood cells, and platelets. The lecture notes also discuss blood plasma, plasma proteins, and factors affecting erythropoiesis, including diet and hormones.

Full Transcript

# BLOOD PHYSIOLOGY (Lecture 1)

By Dr. Eman Elbassuoni

Professor of Physiology

Faculty of Medicine

## Blood

- Blood is the vital fluid tissue that circulates inside blood vessels
- Represents 8% of body weight, or 5.6 L

### Functions of blood:

- **Transport function:** O2, CO2, nutrients, waste products, hormones
- **Defensive function:** White blood cells and antibodies
- **Hemostasis:** Stoppage of bleeding.
- **Homeostasis:** Keeping the internal environment (extracellular fluid) of the body constant for optimum function of the cell (PH, osmotic pressure, volume, gases, minerals, temperature, nutrients).

## Composition of Blood

| Component | Percentage by Volume | Percentage by Weight |
|--------------------------|-----------------------|----------------------|
| Whole Blood | 100% | 100% |
| Plasma | 55% | 55% |
| Forme Elements | 45% | 45% |

### Plasma (55% by weight)

- Contains:
- **Water:** 91%
- **Proteins:** 7%
- Albumins (57%)
- Globulins (38%)
- Fibrinogen (4%)
- Prothrombin (1%)
- **Other Solutes:** 2%
- Ions
- Nutrients
- Waste products
- Gases
- Regulatory substances

### Formed Elements (45% by volume)

- Contains:
- **Leukocytes:** <1% (percentage by number of cells)
- Neutrophils (60%-70%)
- Lymphocytes (20%-25%)
- Monocytes (3%-8%)
- Eosinophils (2%-4%)
- Basophils (0.5%-1%)
- **Platelets:** <1%
- **Erythrocytes:** >99%

## Types of Blood Cells:

- **Red Blood Cells (Erythrocytes)**
- Helps in O2 and CO2 exchange
- **White Blood Cells (Leukocytes)**
- Fights against infections
- Includes: neutrophils, eosinophils, basophils, lymphocytes, and monocytes.
- **Platelets (Thrombocytes)**
- Helps in blood clotting

## Blood Plasma (55% of the blood)

- Yellow clear fluid consisting of:
- **Water:** 91%
- **Proteins:** 7%
- Albumin
- Globulin
- Fibrinogen
- Prothrombin
- **Other Substances: ** 2%
- Ions (Na+, Ca++, Cl-, and others)
- Nutrients
- Waste Products
- Gases
- Regulatory substances (hormones and vitamins)

## Plasma Proteins

| Type | Concentration | Function | Site of Formation |
|-----------|---------------------------------|---------------------------------------------------------------------------------------------------|--------------------|
| Albumin | 4 gm/100 ml plasma (Highest) | - Colloidal osmotic pressure due to its highest concentration. - Transport of some substances. | Liver |
| Globulins | 2.5 gm/100 ml plasma | - Defensive function (α, β, γ globulins). - Transport of some substances. | Liver |
| Fibrinogen | 0.4 gm/100 ml plasma (Highest) | - Blood clotting. - Plasma viscosity due to its highest MW. | Liver |
| Prothrombin | 10 mg/100 ml plasma | - Blood clotting. | Liver |

- ** Albumin/Globulin (A/G) Ratio**
- This is the ratio between albumin and globulin concentration in blood = 1.2 - 1.7 (Albumin = 1.2-1.7/ Globulin)
- **Decreases in:**
- Liver disease due to decreased formation of albumin (↓ Albumin / ↓ Globulin)
- Kidney disease due to loss of albumin in urine (↓ Albumin / ↓ Globulin)
- Infection due to increase globulin concentration (↑ Albumin / ↑↑ Globulin)

## Red Blood Corpuscles (Erythrocytes)

- Non-nucleated circular biconcave discs containing the red respiratory pigment (hemoglobin)
- Average lifespan of 120 days.
- Concentration of hemoglobin in Red Blood Cells is 34%.
- Chief ion inside Red Blood Cells is Potassium (K+).
- Also contains:
- Carbonic anhydrase enzyme
- Glucose-6-phosphate dehydrogenase (G-6-PD).

### Red Blood Cells Count:

- **In adult males:** 5-6 million per cubic mm ( due to androgen hormone that stimulate its formation & increase male musculature which need more oxygen)
- **In adult females:** 4-5 million per cubic mm (due to menstruation)
- **In newly born:** 7 million per cubic mm (due to intrauterine oxygen lack & to increase the iron coming from damaged RBCs that can be used for recycling and reformation of new RBCs due to poor iron in the milk.)

### Functions of Red Blood Cells:

1. Hemoglobin carry O₂ to and take CO₂ from tissues.
2. Hemoglobin has buffering action (85% of blood buffering action).
3. Red Blood Cells contain carbonic anhydrase enzyme which is important for CO₂ carriage.
4. The biconcave shape of Red Blood Cells increases the surface area and helps the exchange of gases between Red Blood Cells and tissues.

## Gas Exchange in Humans

- Diagram showing a cycle of red blood cells moving through the body to the lungs and back, carrying oxygen and carbon dioxide.

## Erythrocyte Membrane:

- Keeps hemoglobin inside, preventing:
- Increase in the load on the heart (heart failure).
- Hemoglobin increases blood viscosity
- Increase in blood volume due to increased plasma colloidal osmotic pressure.
- Obstruction of renal tubules (renal failure)

- **Contains the specific agglutinogens that determine blood group.**

- **Plastic nature** allows Red Blood Cells to compress passing in the narrow capillaries and resume their normal shape on leaving these capillaries without rupture.

## Formation of Red Blood Cells (Erythropoiesis)

### Sites of Red Blood Cell formation:

- **In the fetus,** they are formed in the liver and spleen.
- **In the last three months of fetal life and after birth,** they are formed in the bone marrow of all bone until adolescent.
- **By the age of 20,** they are formed by the bone marrow of the upper parts of the humerus and femur and of membranous bones.
- **After the age of 20 years,** they are formed in the bone marrow of membranous bone (skull, vertebra, sternum, and ribs).

- Rate of erythropoiesis must be equal to the rate of Red Blood Cell destruction to maintain normal Red Blood Cell count.
- After 120 days (average lifespan), Red Blood Cells are engulfed and hemolysed by reticulo-endothelial cells, mainly the spleen.

## Factors affecting erythropoiesis:

1. **Oxygen supply to tissues:**
- Hypoxia occurs in:
- Hemorrhage (due to Red Blood Cell loss)
- High altitude (due to decrease O2 tension around)
- Heart failure (blood don't reach tissue properly)
- Oxygen lack (hypoxia) releases erythropoietin hormone from (mainly) the kidney, stimulating bone marrow to increase production of Red Blood Cells (↑erythropoiesis rate.)

2. **Diet:**
- **Protein:** High biological value containing essential amino acids, essential for formation of globin of hemoglobin.
- **Iron:**
- Average daily intake of iron is 20 mg.
- Most of the diet iron is in the ferric state, poorly absorbed. Ferrous iron is better absorbed.
- Ferric iron is reduced to ferrous in the stomach by HCI and Vitamin C (Fe 3+ → Fe 2+)
- Intestinal epithelial cells contain Apoferritin protein that combines with the ferrous iron to form ferritin. Iron that is absorbed enters the small intestine (duodenum) in this form (Fe2+ + Apoferritin → Ferritin).
- The blood containing transferrin protein carries iron to the bone marrow to form part of Red Blood Cells hemoglobin or to the liver to be stored.
- Excessive oxalates, phytic acids, and phosphates in the diet precipitate iron and will decrease its absorption.
- **Vitamins:**
- **Vitamin B12:**
- Extrinsic factor. Important for Red Blood Cell nuclear maturation and cell division.
- Responsible for myelination of the nerves and integrity of the digestive system mucosa.
- Units with intrinsic factor, secreted by the mucous membrane of the stomach, to form intrinsic factor-Vit B12 complex (Intrinsic factor-Vit B12 → intrinsic factor-Vit B12 complex).
- The intrinsic factor protects vitamin B12 from digestion by gastric enzymes and facilitates its absorption in the lower part of the ileum.
- Stored in the liver and released slowly as needed by the bone marrow, for new red cell formation.
- **Folic Acid:**
- Same importance as Vitamin B12.
- Important for Red Blood Cell nuclear maturation and cell division.
- **Vitamin C:**
- Stimulates tissue growth and metabolism in general, including the bone marrow.
- **Trace Elements:**
- Copper and cobalt act as cofactors for hemoglobin formation.
- **Hormones:**
- Specific: Erythropoietin hormone
- Non-specific: thyroid hormones (↑ metabolism in general)
- Male sex hormones (Androgen) increase erythropoietin hormone and hence stimulate erythropoiesis.

3. **Healthy Organs:**

- **Bone marrow:**
- A healthy bone marrow is essential for normal erythropoiesis (site for formation).
- **Liver:**
- Important for erythropoiesis as:
- Formation of globin of hemoglobin.
- Secretes 15% of erythropoietin hormone.
- Site of storage of Iron & Vit B12.
- **Kidney:**
- Secretes 85% of erythropoietin hormone in response to hypoxia, anemia, and androgen hormone.
- Patients with renal diseases or failure develop severe anemia because erythropoietin production by the liver cannot compensate for the inability of the kidney to produce the hormone.
- **Stomach:**
- Gastric HCl is needed to convert ferric iron to ferrous.
- Intrinsic factor secreted by gastric mucosa is essential for vitamin B12 absorption.
- **Small intestine:**
- The site of iron and vitamin B12 absorption.

## Anaemia

- Means decreased Red Blood Cell number or their hemoglobin content or both.

## Types and causes of Anemia:

### I. Normochromic Normocytic Anemia:

- **Haemolytic anemia**
- Occurs due to excessive haemolysis of Red Blood Cells.
- Examples:
- Incompatible blood transfusion.
- Snake venoms.
- Sensitivity to drugs.
- Infections (types of malaria)
- Antibodies against red blood cells.
- Increased fragility of Red Blood Cells (spherocytosis, sickle cell anemia and thalassemia.)
- **Aplastic anemia**
- Due to bone marrow depression.
- Examples:
- Exposure to radiation (X-rays)
- Chemotherapy
- Drugs (antibiotics with chloramphenicol)
- Destruction of bone marrow (malignant tumors)
- **Haemorrhagic anemia**
- Due to acute blood loss (haemorrhage)

### II. Microcytic Hypochromic Anemia:

- Iron deficiency anemia, either due to:
- Deficiency in the diet (commonest cause)
- Failure of iron absorption
- Absence or removal of acid-producing part of the stomach (congenital achlorohydra, partial gastrectomy)
- Excess oxalates, phytic acids, and phosphates in the diet.
- Small intestine diseases (upper part) (duodenal ulcers)
- Liver disease (site of storage of iron)
- Chronic blood loss (bleeding piles and menstruation in females)

- **Treatment:** Oral iron or injection (in case of gastric or small intestinal causes)

### III. Macrocytic (Megaloblastic) Anemia:

- Occurs due to deficiency of vitamin B12 or folic acid.
- **Vitamin B12 Deficiency (Pernicious Anemia)** due to:
- Absence of intrinsic factor (from the stomach)
- Malabsorption (due to small intestine diseases (lower part))
- Liver disease (site of storage)
- Rarely due to lack of vitamin in the diet.
- **Treatment:** Vitamin B12 injection for life.
- **Folic Acid Deficiency** due to:
- Deficiency of folic acid in the diet (especially during pregnancy)
- Failure of absorption (due to small intestine diseases)

## Polycythaemia

- Means increased number of Red Blood Cells.
- It may reach up to 6-8 million/mm3.

## Thank You

- A diagram of Red Blood Cells and other blood cells flowing through a blood vessel.