IB Biology SL: Theme B - Form & Function

B3.2 - Transport

Moving Life's Essential Fluids: Blood in Animals, Sap in Plants

🫀 Introduction to Transport Systems

As organisms evolved and grew larger, simple diffusion became insufficient for transporting materials throughout the body. Multicellular organisms needed specialized transport systems to move oxygen, nutrients, hormones, and waste products efficiently over long distances.

In this topic, we explore two major transport systems:

🫀 ANIMAL TRANSPORT

Blood circulatory system with heart, blood vessels, and blood

🌱 PLANT TRANSPORT

Vascular tissue system with xylem and phloem

Both systems solve the same fundamental problem: how to deliver essential materials to every cell and remove waste products efficiently, despite the limitations imposed by diffusion distance and surface area-to-volume ratios.

PART 1: TRANSPORT IN ANIMALS - THE CIRCULATORY SYSTEM

🩸 Blood Vessels: The Transport Network

Overview of Blood Vessels

The circulatory system contains approximately 60,000 miles (100,000 km) of blood vessels! These vessels form a closed network that transports blood throughout the body.

There are THREE main types of blood vessels: Arteries, Veins, and Capillaries. Each has a unique structure perfectly adapted to its specific function.

🔴 ARTERIES: Carrying Blood Away from the Heart

Function

Arteries transport blood AWAY FROM the heart to the body's tissues and organs. Blood travels at HIGH PRESSURE in arteries.

Most arteries carry oxygenated blood (rich in O₂, low in CO₂). Exception: Pulmonary artery carries deoxygenated blood from the heart to the lungs for oxygenation.

Structure

Artery walls have THREE layers (like all blood vessels), but each layer is thicker and stronger than in veins:

1. Tunica Intima (Inner Layer)

Single layer of endothelial cells (squamous epithelium)
Provides smooth surface to reduce friction and blood clotting
Minimizes resistance to blood flow

2. Tunica Media (Middle Layer) - THICKEST LAYER

Thick layer of smooth muscle cells
Elastic fibers (elastin)
Functions:
- Smooth muscle contracts/relaxes to control blood flow (vasoconstriction/vasodilation)
- Elastic fibers allow arteries to stretch when blood surges from heart
- Elastic fibers recoil to maintain pressure between heartbeats

3. Tunica Externa (Outer Layer)

Collagen fibers (tough connective tissue)
Provides structural support and prevents rupture under high pressure
Anchors artery to surrounding tissues

Key Structural Features

✓ Thick Walls

Much thicker than veins. Withstand and maintain high blood pressure (~120/80 mmHg at rest).

✓ Small Lumen (Central Space)

Relatively narrow compared to wall thickness. Maintains high blood pressure.

✓ NO Valves

High pressure ensures blood flows in one direction—no backflow risk. (Exception: semilunar valves at heart exit)

✓ Circular Cross-Section

Maintains round shape even when cut (due to thick walls).

✓ Pulse Present

Can feel rhythmic expansion and recoil with each heartbeat.

🔵 VEINS: Returning Blood to the Heart

Function

Veins transport blood TOWARD (into) the heart from the body's tissues. Blood travels at LOW PRESSURE in veins.

Most veins carry deoxygenated blood (low in O₂, high in CO₂). Exception: Pulmonary veins carry oxygenated blood from the lungs to the heart.

Structure

Vein walls also have the same THREE layers, but they're thinner and less muscular than arteries:

1. Tunica Intima (Inner Layer)

Single layer of endothelial cells
Smooth surface for blood flow
Forms valves at intervals

2. Tunica Media (Middle Layer) - THIN

Thin layer of smooth muscle (less than arteries)
Few elastic fibers
Less need to push blood (low pressure system)
Less need for elastic recoil

3. Tunica Externa (Outer Layer)

Collagen fibers
Provides support (though less robust than arteries)

Key Structural Features

✓ Thin Walls

Much thinner than arteries. Only need to withstand low pressure (~0-10 mmHg).

✓ Large Lumen

Wide central space (larger than arteries). Reduces resistance to blood flow. Can hold more blood (~70% of blood volume is in veins!).

✓ VALVES Present

Semilunar (pocket) valves at intervals. Prevent backflow of blood (especially important in limbs where gravity opposes blood flow). Open when blood flows toward heart, close to prevent backflow.

✓ Irregular/Collapsed Shape

May appear flattened or oval when cut (thin walls collapse). Shape varies with blood volume.

✓ NO Pulse

Blood flows smoothly without pressure surges—no detectable pulse.

💪 How Blood Returns Against Gravity:

Low pressure in veins isn't enough to push blood upward from legs. Three mechanisms help:

Skeletal muscle pump: Muscle contractions squeeze veins, pushing blood toward heart
Valves: Prevent backflow between muscle contractions
Respiratory pump: Pressure changes during breathing help draw blood toward heart

🟢 CAPILLARIES: The Exchange Vessels

Function

Capillaries are the sites of material exchange between blood and tissues. They connect arteries to veins, forming vast networks throughout tissues.

What's exchanged? Oxygen, carbon dioxide, nutrients (glucose, amino acids), hormones, waste products (urea), water. Exchange occurs by diffusion and pressure filtration.

Structure

Capillaries have the SIMPLEST structure—perfectly adapted for exchange:

✓ ONE Cell Thick

Wall consists of single layer of endothelial cells (flattened squamous epithelium). No smooth muscle, no elastic tissue, no collagen. Minimizes diffusion distance—extremely short (~ 0.5-1 μm).

✓ Very Small Diameter

Lumen diameter: 5-10 μm (micrometers). Just wide enough for red blood cells to pass single-file. Forces RBCs close to capillary walls for efficient gas exchange.

✓ Highly Permeable

Thin walls allow rapid diffusion. Small gaps between cells allow plasma to leak out (forming tissue fluid). Some capillaries have pores (fenestrations) for even faster exchange.

✓ Extensive Networks (Capillary Beds)

Billions of capillaries throughout the body. Every cell is within ~2-3 cells of a capillary. Creates enormous total surface area for exchange.

✓ Slow Blood Flow

Blood slows down in capillaries (network increases cross-sectional area). Provides more time for exchange to occur.

✓ NO Valves

Flow is unidirectional—no backflow risk due to continuous connection between arterioles and venules.

🔑 Key Principle:

Capillaries are optimized for EXCHANGE, not transport. Their structure (thin walls, small diameter, extensive networks, slow flow) maximizes the rate of material exchange with tissues.

📊 Comparison: Arteries vs. Veins vs. Capillaries

Feature	Arteries	Veins	Capillaries
Function	Carry blood AWAY from heart	Carry blood TO heart	Exchange materials with tissues
Blood Pressure	HIGH (~120/80 mmHg)	LOW (~0-10 mmHg)	MEDIUM (decreasing)
Wall Thickness	THICK (3 layers, thick muscle & elastic tissue)	THIN (3 layers, but thin)	VERY THIN (1 cell thick)
Lumen Size	SMALL (narrow)	LARGE (wide)	VERY SMALL (5-10 μm)
Valves	NO (except near heart)	YES (prevent backflow)	NO
Pulse	YES (can be felt)	NO	NO
Blood Type	Oxygenated (except pulmonary artery)	Deoxygenated (except pulmonary veins)	Both (transition from O₂-rich to O₂-poor)
Shape When Cut	Round/circular	Irregular/collapsed	Very small dots

💓 Pulse: Measuring Heart Activity

What is Pulse?

The pulse is the rhythmic expansion and recoil of arteries caused by the surge of blood pumped from the heart with each heartbeat.

Pulse rate = Heart rate. Measuring pulse is an easy, non-invasive way to assess cardiovascular health and fitness!

⚙️ How Pulse is Generated

1. Ventricular Contraction (Systole)

Heart's ventricles contract, forcefully ejecting blood into arteries (aorta and pulmonary artery)

2. Pressure Wave

Sudden surge of blood creates a pressure wave that travels through arterial walls

3. Artery Expansion

Elastic fibers in artery walls stretch to accommodate increased blood volume

4. Elastic Recoil

Between heartbeats, elastic fibers recoil, maintaining blood pressure and flow

5. Wave Propagation

This expansion-recoil cycle travels as a wave through arterial system. Can be felt where arteries are close to skin surface

📍 Where to Measure Pulse

Pulse can be felt at various pulse points where arteries pass close to the skin surface:

🖐️ Radial Pulse (Wrist)

Most common site. Radial artery on thumb side of wrist. Easy to locate and measure.

🫱 Carotid Pulse (Neck)

Carotid artery on side of neck. Strong, easy to find during/after exercise.

💪 Brachial Pulse (Elbow)

Brachial artery inside elbow. Used for blood pressure measurement.

🦵 Femoral Pulse (Groin)

Femoral artery in groin area. Strong pulse.

📊 Normal Pulse Rates

Population	Resting Pulse Rate (beats per minute)
Adults (at rest)	60-100 bpm (average ~70-75 bpm)
Athletes (at rest)	40-60 bpm (lower due to higher cardiac efficiency)
Children (6-15 years)	70-100 bpm
Infants	100-160 bpm
During Exercise	Can reach 120-200+ bpm (depends on intensity and fitness)

📈 Factors Affecting Pulse Rate:

Exercise/Physical activity: Increases pulse (muscles need more O₂)
Emotional state: Stress, anxiety, excitement increase pulse
Temperature: Heat increases pulse; cold decreases it
Body position: Standing > sitting > lying down
Fitness level: Fit individuals have lower resting pulse
Age: Younger = generally higher pulse
Caffeine/stimulants: Increase pulse rate

❤️ Coronary Arteries: Feeding the Heart

What are Coronary Arteries?

Coronary arteries are specialized blood vessels that supply oxygen-rich blood to the heart muscle (myocardium) itself.

The heart pumps blood to the entire body, but it also needs its own blood supply! Coronary arteries branch directly from the aorta (just above the heart) to nourish the heart muscle.

🫀 The Two Main Coronary Arteries

Left Coronary Artery

Supplies blood to left side of heart
Branches into:
- Left anterior descending (LAD): Supplies front/anterior wall of left ventricle
- Left circumflex: Supplies back/lateral wall of left ventricle and left atrium
Critical: Supplies most powerful chamber (left ventricle)

Right Coronary Artery

Supplies blood to right side of heart
Branches to:
- Right ventricle
- Right atrium
- Part of interventricular septum
- SA node and AV node (heart's pacemakers) in many people

⚠️ Coronary Artery Disease (CAD)

What is CAD?

Coronary Artery Disease (also called coronary heart disease or ischemic heart disease) occurs when coronary arteries become narrowed or blocked, reducing blood flow to the heart muscle.

Cause: Atherosclerosis

Atherosclerosis is the buildup of plaque (fatty deposits) on the inner walls of arteries.

Plaque consists of: cholesterol, fats, calcium, cellular waste, and fibrin (clotting material)

How Atherosclerosis Develops

1. Endothelial Damage

Inner lining of artery damaged by high blood pressure, smoking, high cholesterol, diabetes

2. Cholesterol Accumulation

LDL cholesterol ("bad" cholesterol) deposits in damaged area, forming fatty streaks

3. Inflammatory Response

White blood cells accumulate, trying to "clean up" cholesterol. Forms growing plaque

4. Plaque Growth & Calcification

Plaque grows larger, hardens with calcium deposits. Artery narrows, becomes less elastic

5. Reduced Blood Flow

Narrowed artery reduces oxygen supply to heart muscle, especially during exertion

6. Potential Rupture → Heart Attack

If plaque ruptures, blood clot forms → complete blockage → myocardial infarction (heart attack)

Symptoms of CAD

Angina (chest pain): Pressure, tightness, or pain in chest during exertion or stress
Shortness of breath: Especially during physical activity
Fatigue: Due to reduced oxygen delivery to tissues
Heart attack: Sudden, severe chest pain; radiating pain to arm, jaw, neck; nausea; cold sweat

🛡️ Risk Factors & Prevention

Risk Factors

High cholesterol (high LDL, low HDL)
High blood pressure (hypertension)
Smoking
Diabetes
Obesity
Physical inactivity
Unhealthy diet (high in saturated/trans fats, salt, sugar)
Chronic stress
Family history
Age (risk increases with age)

Prevention Strategies

Healthy diet (fruits, vegetables, whole grains, lean protein)
Regular exercise (150 min/week moderate activity)
Maintain healthy weight
Don't smoke
Limit alcohol
Manage stress
Control blood pressure
Control cholesterol
Manage diabetes (if present)
Regular check-ups

💊 Treatments for CAD:

Medications: Statins (lower cholesterol), blood thinners (prevent clots), beta-blockers (reduce heart workload). Procedures: Angioplasty with stent (opens blocked artery), coronary artery bypass grafting (CABG) - surgery to create new blood pathways.

PART 2: TRANSPORT IN PLANTS - VASCULAR TISSUE SYSTEM

🌱 Plant Transport System Overview

Why Do Plants Need Transport Systems?

Like animals, plants are too large for diffusion alone to move materials efficiently. They need specialized vascular tissues to transport substances over long distances.

Three Main Reasons:

Size: Many plants are very tall (some trees > 100m!). Diffusion is too slow over such distances.
Surface Area:Volume Ratio: As plants grow larger, their SA:V ratio decreases. Cannot rely on diffusion to supply all cells.
Metabolic Demands: Roots don't photosynthesize (no glucose, no O₂ production). Leaves don't absorb water/minerals. Materials must be transported between organs.

🌿 The Two Vascular Tissues

XYLEM

Transports:

Water and dissolved minerals (ions)

Direction:

UPWARD ONLY
Roots → Stems → Leaves

Process:

Transpiration pull

PHLOEM

Transports:

Organic compounds (sugars/sucrose, amino acids)

Direction:

BIDIRECTIONAL
From source (leaves) → to sinks (roots, fruits, growing tissues)

Process:

Translocation (pressure flow)

💧 Xylem & Transpiration: Water Transport

🔬 Structure of Xylem

What is Xylem?

Xylem is a complex vascular tissue composed of several cell types. The main water-conducting cells are xylem vessels and tracheids.

Key Structural Features of Xylem Vessels:

1. Dead Cells

Xylem vessels are formed from dead cells. At maturity, the cell contents (cytoplasm, organelles, nucleus) die and are removed, leaving hollow tubes.

2. Hollow Tubes

The empty space allows unobstructed water flow. Continuous column of water from roots to leaves.

3. Lignified Walls

Cell walls contain lignin—a tough, waterproof polymer. Provides structural support (prevents collapse under negative pressure). Creates rigid tubes that help support plant height.

4. No End Walls

Multiple xylem cells stack vertically. End walls break down to form continuous tubes. Water flows freely without barriers.

5. Narrow Diameter

Small diameter (10-200 μm) allows capillary action and maintains water column through cohesion-tension.

6. Pits in Walls

Small pores allow lateral movement of water between adjacent xylem vessels and into surrounding cells.

💨 Transpiration: The Driving Force

What is Transpiration?

Transpiration is the evaporation of water from the aerial parts of plants, mainly through stomata in leaves. It creates the "pull" that draws water up through xylem.

Interesting fact: Plants lose ~90% of water absorbed by roots through transpiration! Only ~10% is used for photosynthesis and other processes. This seems wasteful, but transpiration is essential for water transport.

The Cohesion-Tension Theory

This theory explains how water moves from roots to leaves against gravity, without any pumping mechanism:

Step 1: Transpiration Creates Tension

Water evaporates from mesophyll cells in leaves through stomata. Creates negative pressure (tension) in leaf cells and xylem at top of plant.

Step 2: Cohesion Maintains Water Column

Water molecules are cohesive (stick together via hydrogen bonds). Form continuous column in xylem. As water is pulled up from top, entire column moves upward together.

Step 3: Adhesion to Xylem Walls

Water molecules adhere (stick) to lignified xylem walls. Prevents water column from falling and helps water climb walls.

Step 4: Water Uptake from Soil

As water is pulled up, more water enters root hair cells from soil by osmosis. Replaces water lost through transpiration.

🔑 Key Points:

Water transport in xylem is PASSIVE—no ATP required!
Driven by transpiration pull (evaporation at top)
Relies on cohesion (water-water bonds) and adhesion (water-wall bonds)
Xylem vessels under negative pressure (tension)

🌡️ Factors Affecting Transpiration Rate

1. Light Intensity

Higher light → Higher transpiration. Light causes stomata to open for photosynthesis, allowing more water loss.

2. Temperature

Higher temperature → Higher transpiration. Increases evaporation rate. Water molecules have more kinetic energy.

3. Humidity

Higher humidity → Lower transpiration. Reduces concentration gradient for water vapor diffusion from leaf to air.

4. Wind Speed

Higher wind → Higher transpiration (up to a point). Wind removes water vapor from leaf surface, maintaining steep gradient. Very strong wind causes stomata to close.

5. Stomatal Density & Size

More/larger stomata → Higher transpiration. More openings for water vapor to escape.

🍬 Phloem & Translocation: Sugar Transport

🔬 Structure of Phloem

What is Phloem?

Phloem is a complex living tissue that transports organic compounds (mainly sucrose) and amino acids. Main conducting cells are sieve tube elements supported by companion cells.

Key Structural Features:

1. Sieve Tube Elements (Living Cells)

Living cells (unlike xylem). Have cytoplasm but no nucleus at maturity (to maximize space for sap flow). Have few organelles. Elongated cells stacked end-to-end forming tubes.

2. Sieve Plates

Perforated end walls between sieve tube elements. Allow sap to flow between cells. Create continuous tubes like xylem, but with some barriers.

3. Companion Cells

Living cells with nucleus and many mitochondria. Connected to sieve tube elements by plasmodesmata (cytoplasmic connections). Provide metabolic support (produce ATP for active transport). Control loading/unloading of sugars.

4. Thin Cell Walls

Cellulose walls (NO lignin). Flexible, allowing expansion under pressure.

➡️ Translocation: Active Transport of Sugars

What is Translocation?

Translocation is the active transport of organic compounds (sucrose, amino acids) through phloem sieve tubes from sources (where made/stored) to sinks (where needed/stored).

Key Terms:

Source: Regions where sugars are produced (photosynthesizing leaves) or mobilized (storage organs like tubers)
Sink: Regions where sugars are used (roots, fruits, seeds, growing tips) or stored (tubers, bulbs)
Direction: From source to sink—can be upward OR downward

⚡ Important Difference from Xylem:

Translocation requires ATP (energy)—it's an ACTIVE process! Sugars are actively loaded into phloem at source and unloaded at sink.

📐 Vascular Tissue Arrangement in Stems & Roots

🌿 Vascular Bundles

In plants, xylem and phloem are grouped together in structures called vascular bundles. The arrangement differs in different plant organs:

General Rule:

Xylem is typically positioned TOWARD THE CENTER (inside), while phloem is positioned TOWARD THE OUTSIDE. This arrangement is consistent across plant organs.

🌳 IN STEMS

Arrangement:

Vascular bundles are arranged in a ring pattern around the outer part of the stem (in dicots).

Position in Each Bundle:

Xylem: Located on the INSIDE (toward center of stem)
Phloem: Located on the OUTSIDE (toward epidermis)
Cambium: Layer of dividing cells between xylem and phloem (allows secondary growth)

Why This Arrangement?

Structural support: Xylem's lignified walls provide rigidity to support upright growth
Ring pattern: Distributes support evenly around stem, preventing bending
Protection: Phloem is closer to outer protective layers
Efficient transport: Shorter distances for materials to move in/out of vascular tissue

🌱 IN ROOTS

Arrangement:

Vascular tissue forms a central core in the middle of the root (called the vascular cylinder or stele).

Position in Core:

Xylem: Forms a central STAR or CROSS shape in the very center of root
Phloem: Located in the spaces/pockets BETWEEN the xylem arms (alternating pattern)
NO cambium between them in young roots (different from stems)

Why This Arrangement?

Anchoring strength: Central xylem core provides strength to resist pulling forces
Water uptake: Water absorbed by root hairs can easily reach xylem in center
Protection: Vascular tissue protected by outer cortex layers
Efficient absorption: Short distance from epidermis to vascular tissue

📊 Comparison: Xylem vs. Phloem

Feature	Xylem	Phloem
Transports	Water and dissolved minerals	Organic compounds (sucrose, amino acids)
Direction	UPWARD only (roots → leaves)	BIDIRECTIONAL (source → sink)
Cell Type	Xylem vessels and tracheids	Sieve tube elements + companion cells
Living/Dead	DEAD cells at maturity	LIVING cells
Cell Contents	Empty (hollow tubes)	Cytoplasm present (no nucleus in sieve tubes)
End Walls	Completely broken down (NO end walls)	Perforated (sieve plates)
Cell Walls	Lignified (contains lignin) - thick & rigid	Cellulose only (NO lignin) - thin & flexible
Transport Mechanism	PASSIVE (transpiration pull, cohesion-tension)	ACTIVE (requires ATP for loading/unloading)
Process Name	Transpiration stream	Translocation
Position (General)	INSIDE/CENTRAL (toward center)	OUTSIDE (toward periphery)
Additional Function	Provides structural support	No structural role

🎯 Key Concepts Summary

✓ Blood Vessel Types

Arteries (thick walls, small lumen, high pressure, carry blood away from heart), Veins (thin walls, large lumen, low pressure, valves, carry blood to heart), Capillaries (one cell thick, site of exchange between blood and tissues).

✓ Pulse & Coronary Arteries

Pulse is the rhythmic expansion of arteries with each heartbeat. Coronary arteries supply oxygen to heart muscle itself. Coronary artery disease (atherosclerosis) causes narrowing/blockage, leading to angina or heart attack.

✓ Xylem Structure & Function

Xylem vessels are dead, hollow, lignified tubes that transport water and minerals upward (roots → leaves). Transport is passive, driven by transpiration pull via cohesion-tension mechanism. No ATP required.

✓ Phloem Structure & Function

Phloem consists of living sieve tube elements (no nucleus) supported by companion cells. Transports organic compounds (sucrose, amino acids) bidirectionally from source to sink. Translocation is active transport requiring ATP.

✓ Transpiration

Evaporation of water from leaves through stomata. Creates tension (negative pressure) that pulls water up xylem. Affected by light, temperature, humidity, and wind. ~90% of water absorbed is lost through transpiration.

✓ Vascular Tissue Arrangement

Stems: Vascular bundles in ring pattern; xylem inside, phloem outside. Provides structural support. Roots: Central vascular cylinder; xylem forms star in center, phloem in pockets between xylem arms. Provides anchoring strength.

📚 About the Author

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Co-Founder @RevisionTown

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