krit.club logo

Life Processes - Transportation

Grade 10CBSE

Review the key concepts, formulae, and examples before starting your quiz.

🔑Concepts

Transportation in humans is carried out by the circulatory system, which consists of the heart, blood vessels (arteries, veins, and capillaries), and blood.

The human heart is a four-chambered muscular organ. The separation of the right and left sides prevents the mixing of oxygenated and deoxygenated blood, ensuring efficient O2O_2 supply.

Double circulation involves two cycles: Pulmonary circulation (Heart \rightarrow Lungs \rightarrow Heart) and Systemic circulation (Heart \rightarrow Body \rightarrow Heart).

Blood pressure is the force exerted by blood against vessel walls. It is measured using a sphygmomanometer; normal systolic pressure is 120 mmHg120\ mmHg and diastolic is 80 mmHg80\ mmHg.

Platelets are responsible for blood clotting at the site of injury to prevent excessive blood loss.

Lymph is an extracellular fluid that carries digested fats and drains excess fluid from intercellular spaces back into the blood. It contains less protein than plasma and no RBCsRBCs.

In plants, transportation occurs through vascular tissues: XylemXylem (water and minerals) and PhloemPhloem (food/sucrose).

Water moves upward in XylemXylem due to Root PressureRoot\ Pressure (at night) and Transpiration PullTranspiration\ Pull (during the day) through the stomata.

Translocation is the transport of soluble products of photosynthesis in PhloemPhloem. Unlike xylem transport, it requires energy in the form of ATPATP.

📐Formulae

BP=Systolic PressureDiastolic Pressure12080 mmHgBP = \frac{\text{Systolic Pressure}}{\text{Diastolic Pressure}} \approx \frac{120}{80}\ mmHg

Hb+4O2Hb(O2)4 (Oxyhaemoglobin formation)Hb + 4O_2 \rightleftharpoons Hb(O_2)_4 \text{ (Oxyhaemoglobin formation)}

Transpiration PullRate of Evaporation from Stomata\text{Transpiration Pull} \propto \text{Rate of Evaporation from Stomata}

Osmotic Pressure    Water movement into Phloem sieve tubes\text{Osmotic Pressure} \uparrow \implies \text{Water movement into Phloem sieve tubes}

💡Examples

Problem 1:

Calculate the heart rate if the cardiac cycle duration is 0.8 seconds0.8\ seconds.

Solution:

Heart Rate=60 seconds0.8 seconds/cycle=75 beats per minute\text{Heart Rate} = \frac{60\ \text{seconds}}{0.8\ \text{seconds/cycle}} = 75\ \text{beats per minute}

Explanation:

The heart rate is the number of cardiac cycles completed in one minute (6060 seconds).

Problem 2:

Explain how the transport of food in PhloemPhloem differs from the transport of water in XylemXylem.

Solution:

In XylemXylem, water moves upward due to physical forces like Transpiration PullTranspiration\ Pull. In PhloemPhloem, sucrose is loaded into sieve tubes using ATPATP. This increases the osmotic pressure, causing H2OH_2O to move into the phloem, creating a high-pressure gradient that moves the sap to tissues with lower pressure.

Explanation:

The movement in phloem is an active process requiring biological energy (ATPATP), whereas xylem transport is largely driven by physical gradients.

Problem 3:

What happens to the O2O_2 carrying capacity if there is a deficiency of HemoglobinHemoglobin (HbHb)?

Solution:

A deficiency in HbHb leads to AnemiaAnemia. Since HbHb has a high affinity for O2O_2, lower levels mean less O2O_2 is transported to tissues, leading to fatigue and breathlessness.

Explanation:

Each HbHb molecule binds to 44 molecules of O2O_2 to form Hb(O2)4Hb(O_2)_4. If HbHb concentration drops, the total O2O_2 concentration in the blood decreases.

Transportation - Revision Notes & Key Formulas | CBSE Class 10 Science