This MCQ module is based on: Nutrition and Respiration
Nutrition and Respiration
Study Notes and Summary
Life Processes Defined: Fundamental processes necessary for an organism’s survival and maintenance (e.g., nutrition, respiration, transport, excretion).
Nutrition:
Autotrophic Nutrition: Organisms synthesize their own food (e.g., plants, cyanobacteria).
Photosynthesis: Process of converting light energy into chemical energy.
Equation: 6CO2+6H2OLight EnergyC6H12O6+6O2
Site: Chloroplasts (contain chlorophyll).
Events:
Light-dependent reactions: Absorption of light energy by chlorophyll, conversion of light energy to chemical energy (ATP, NADPH), water splitting (H2O→O2,H+,e−).
Light-independent reactions (Calvin cycle): Reduction of CO2 to carbohydrates using ATP and NADPH.
Stomata: Tiny pores on leaves facilitating CO2 intake and O2/water vapor release. Guard cells regulate opening/closing.
Heterotrophic Nutrition: Organisms obtain food from others.
Types: Saprophytic (dead/decaying matter), Parasitic (living host), Holozoic (ingestion).
Holozoic Nutrition in Amoeba: Phagocytosis (pseudopodia engulf food), food vacuole formation, digestion by enzymes, absorption, egestion.
Holozoic Nutrition in Humans:
Alimentary Canal: Mouth → Pharynx → Esophagus → Stomach → Small Intestine → Large Intestine → Anus.
Digestive Glands: Salivary glands, gastric glands, liver, pancreas, intestinal glands.
Key Enzymes/Processes:
Mouth: Salivary amylase (starch digestion).
Stomach: Gastric glands secrete HCl (acidic medium, kills germs, activates pepsin), Pepsin (protein digestion).
Small Intestine: Site of complete digestion and absorption.
Liver: Bile (emulsifies fats).
Pancreas: Pancreatic amylase (starch), Trypsin (protein), Lipase (fats).
Intestinal Juice: Peptidases (peptides to amino acids), Sucrase/Lactase/Maltase (disaccharides to monosaccharides), Intestinal lipase.
Absorption: Villi and microvilli increase surface area in small intestine.
Large Intestine: Water absorption, waste formation.
Respiration: Process of releasing energy from food.
Types:
Aerobic Respiration: In presence of oxygen.
Glucose → Pyruvate (cytoplasm) → CO2+H2O+Energy (mitochondria). High ATP yield.
Equation: C6H12O6+6O2→6CO2+6H2O+Energy (38 ATP)
Anaerobic Respiration: In absence of oxygen.
Fermentation (Yeast): Glucose → Pyruvate → Ethanol + CO2 + Energy.
Lactic Acid Formation (Muscle Cells): Glucose → Pyruvate → Lactic Acid + Energy. (Occurs during vigorous exercise, leads to cramps).
Respiration in Plants: Gaseous exchange via stomata (leaves), lenticels (stems), general root surface. Occurs 24/7, but photosynthesis dominates during day.
Respiration in Animals:
Aquatic Organisms (e.g., Fish): Gills absorb dissolved oxygen from water. Faster breathing rate due to lower dissolved O2.
Terrestrial Organisms (e.g., Humans): Lungs for gaseous exchange.
Human Respiratory System: Nostrils → Pharynx → Larynx → Trachea → Bronchi → Bronchioles → Alveoli.
Alveoli: Thin-walled, richly vascularized sacs for efficient gaseous exchange (diffusion of O2 into blood, CO2 out).
Mechanism: Inhalation (diaphragm contracts, ribs lift, volume increases, pressure decreases, air rushes in); Exhalation (diaphragm relaxes, ribs lower, volume decreases, pressure increases, air rushes out).
Transportation of Gases: O2 transported by hemoglobin in RBCs. CO2 transported
largely as bicarbonate ions in plasma.
\(ΔK = -\frac{m_1m_2}{2(m_1+m_2)}(v_{1i}-v_{2i})^2\).
\(\theta_1+\theta_2=90^\circ\)).
Practice MCQs
Assessment Worksheets
This assessment will be based on: Nutrition and Respiration
Experiment-Based Theories for Olympiad Preparation
Hypothetical Experiment: Investigating the Efficiency of Gaseous Exchange in Different Respiratory Surfaces
Objective: To quantitatively compare the rates of oxygen uptake and carbon dioxide release across different simulated respiratory surfaces, emphasizing adaptations for efficiency.
Materials:
Setup 1 (Simulating Alveolus): Thin, moist, semi-permeable membrane (e.g., dialysis tubing or egg membrane) stretched over a petri dish, connected to a small oxygen sensor and a CO2 sensor. A circulatory fluid (simulated blood plasma with a pH indicator) on the other side.
Setup 2 (Simulating Fish Gill Lamellae): Multiple thin, highly folded semi-permeable membranes submerged in oxygenated water, with a similar sensor setup.
Setup 3 (Simulating Plant Stomata): A potted plant leaf coated with a substance to vary stomatal opening (e.g., ABA solution to close, light to open), connected to gas sensors in a sealed chamber.
Oxygen and CO2 gas cylinders, peristaltic pumps, data logger.
Procedure:
Alveolus Simulation: Introduce a fixed volume of “atmospheric air” (high O2, low CO2) to one side of the membrane. Circulate simulated blood (low O2, high CO2, slightly acidic) on the other side. Monitor gas levels over time and pH changes in the “blood.”
Gill Simulation: Submerge the gill model in a continuously flowing stream of oxygenated water. Circulate “blood” through the gill lamellae. Monitor gas levels.
Stomata Simulation: Place the leaf in the sealed chamber. Vary light intensity and measure O2 and CO2 changes in the chamber, correlating with stomatal opening (observed under microscope).
Expected Observations:
Alveolus: Rapid decrease in O2 on air side, rapid increase in CO2 on air side, and concurrent changes in blood side, indicating efficient bidirectional diffusion. pH of “blood” would slightly increase as CO2 diffuses out.
Gill: Continuous and efficient O2 uptake from water and CO2 release, demonstrating counter-current exchange principles if flow rates are optimized.
Stomata: Net O2 release and CO2 uptake in light; net O2 uptake and CO2 release in dark (respiration). Stomatal opening/closing directly affects gas exchange rates.
Theoretical Outcomes & Advanced Concepts:
Fick’s Law of Diffusion: Quantitatively analyze how surface area, thickness of membrane, and concentration gradient affect diffusion rates in each setup.
Rate of Diffusion ∝Thickness of MembraneSurface Area×Concentration Gradient
Partial Pressures: Relate the observed gas exchange to differences in partial pressures of O2 and CO2 across the membranes.
Counter-Current Exchange (Gills): Explain how the opposite flow of water and blood maximizes the concentration gradient along the entire length of the gill lamella, leading to highly efficient oxygen extraction.
Buffering Capacity of Blood: Explain how the change in pH in the “blood” (due to CO2 levels) relates to the carbonic acid-bicarbonate buffer system.
Regulation of Stomatal Opening: Discuss how environmental factors (light, CO2 concentration, water availability) influence guard cell turgidity and thus stomatal pore size, linking to water conservation.
Real-Life Connections:
Respiratory Diseases: How conditions like emphysema (reduced alveolar surface area) or asthma (bronchial constriction) impair gas exchange.
Altitude Sickness: The physiological adaptations and challenges associated with lower partial pressures of O2 at high altitudes.
Aquaculture: Designing efficient aeration systems for fish farms based on gill efficiency.
Agricultural Productivity: How optimizing stomatal function (e.g., drought-resistant crops) can improve crop yield by balancing photosynthesis and transpiration.
Eutrophication: Impact of reduced dissolved oxygen in aquatic environments on aquatic life due to impaired gill function.
