Two examples of prokaryotes are Bacteria (like E. coli) and Archaea, while two examples of eukaryotes are Animals

nucleus (control center), mitochondria (energy production), ribosomes (protein synthesis), endoplasmic reticulum (transport), Golgi apparatus (packaging), and lysosomes (waste breakdown).

 because its phospholipid bilayer structure and embedded transport proteins carefully control which substances (like nutrients, ions, waste) can pass through, letting essential small molecules and specific ions in while blocking others, crucial for maintaining the cell's internal balance (homeostasis).

it regulates water balance in our cells and bodies, essential for nutrient absorption, waste removal (kidney function, sweating), maintaining cell shape, and overall homeostasis (stable internal environment) in humans and plants, preventing dehydration or swelling, and allowing plants to stay upright.

FALSE THERE COMPLETELY OPPOSITE !!!

The biggest difference is that eukaryotic cells have a true nucleus and other membrane-bound organelles (like mitochondria, ER) to compartmentalize functions, while prokaryotic cells (bacteria, archaea) lack these internal membranes,

• Nucleus: The cell's control center, holding DNA, the blueprints for all cell activities, growth, and reproduction.
• Mitochondria: The powerhouses, generating ATP (energy) for all cellular processes.
• Ribosomes: Protein factories, essential for building structures, enzymes, and hormones.
• Endoplasmic Reticulum (ER): Creates and transports proteins (rough ER) and lipids (smooth ER), plus detoxification.
• Golgi Apparatus: The "shipping department," modifying, sorting, and packaging molecules for export or delivery.
• Lysosomes: The recycling center, breaking down waste, old cell parts, and foreign invaders.
• Cell Membrane: Protects the cell and controls what enters and leaves.
• Cytoplasm/Cytosol: The jelly-like substance where metabolic reactions occur and organelles reside. 

its hydrophilic (water-loving) heads face outward, while the hydrophobic (water-fearing) tails form a water-repellent core, creating a selectively permeable barrier that blocks water-soluble substances but allows small, nonpolar molecules (like oxygen, lipids) to pass freely, while larger or charged molecules need help from transport proteins to cross.

to maintain water balance (homeostasis) in cells and organisms by moving water across semipermeable membranes

the vital metabolic process where living cells convert nutrients (like glucose) and oxygen into usable energy (ATP), releasing carbon dioxide and water as byproducts, essentially "burning" food for fuel to power all life functions.

The prokaryotic DNA is a  Single, circular DNA in the cytoplasm (nucleoid region). While the Eukaryote DNA is  Multiple, linear chromosomes inside the nucleus.

• Foundation of Life: Cells are the basic units of life, and organelles ensure cells can perform essential functions like energy production, growth, and reproduction.
• Coordination & Specialization: Just as organs work together, organelles perform specialized tasks, allowing complex functions needed for tissues, organs, and systems.
• Health & Disease: Proper organelle function maintains cellular balance (homeostasis); errors in organelle communication or function can lead to serious conditions like metabolic, cardiovascular diseases, and cancer. 

 substances flow naturally from high to low concentration (like a ball rolling downhill), requiring no energy (passive transport), while moving against it means going from low to high concentration (uphill), which demands energy (ATP) and is called active transport.

low solute concentration (high water concentration) to an area of high solute concentration (low water concentration)

sunlight (energy), carbon dioxide (from the air), and water (from the soil), plus the green pigment chlorophyll to capture light, all working to create glucose (food) and oxygen.