Osmosis is a process that is primarily associated with liquids, specifically the movement of water across a partially permeable membrane. It does not occur in gases. The fundamental principle of osmosis is the diffusion of water from an area of higher water potential (or lower solute concentration) to an area of lower water potential (or higher solute concentration) across a membrane. In gases, molecules are in a constant state of random motion and are far apart, lacking the cohesive properties of liquids that facilitate the movement of water molecules through osmosis. Additionally, osmosis requires a semi-permeable membrane to allow the selective passage of water molecules, a condition not applicable to gases. Therefore, osmosis is a process unique to liquid systems and is particularly crucial in biological contexts where it plays a vital role in maintaining the internal environment of cells.

Osmosis and diffusion are both passive transport processes, but they differ in key aspects. Osmosis specifically refers to the movement of water across a partially permeable membrane from an area of higher water potential to one of lower water potential. It is a selective process concerning only water molecules. In contrast, diffusion is the movement of any molecules (not just water) from an area of high concentration to an area of low concentration, until equilibrium is reached. Diffusion does not necessarily require a membrane and can occur in any medium – gas, liquid, or solid. While osmosis is a type of diffusion specific to water, the general principle of moving from a higher to a lower concentration gradient applies to both. However, the selective nature of the membrane in osmosis makes it a unique process critical for cellular functions, particularly in maintaining the balance of fluids and solutes within and outside of cells.

Plant cells have a unique feature that prevents them from bursting in hypotonic solutions: the cell wall. This rigid structure provides mechanical strength and support. When a plant cell is placed in a hypotonic solution, water enters the cell due to the higher water potential outside. As water fills the vacuole, the cell's internal pressure, or turgor pressure, increases, pushing the cell membrane against the cell wall. However, the cell wall's rigidity prevents the cell from expanding beyond a certain point, thus preventing it from bursting. This turgidity is essential for maintaining the structural integrity of plants, aiding in their upright stance and growth. Conversely, animal cells lack such a protective barrier, making them susceptible to bursting under similar conditions. Turgidity in plant cells is not just a response to osmotic stress but also a structural feature integral to plant physiology.

Aquaporins are integral membrane proteins that specifically facilitate the transport of water molecules across cell membranes. They play a crucial role in osmosis by increasing the permeability of cell membranes to water, thereby allowing rapid and efficient osmotic flow of water into and out of cells. Without aquaporins, the movement of water across cell membranes would be much slower, as the lipid bilayer of cell membranes is relatively impermeable to water. These proteins are highly selective, only allowing water molecules to pass through while preventing the passage of ions and other solutes. This selectivity is crucial in maintaining the cell's internal environment and osmotic balance. Aquaporins are found in a wide range of organisms, from bacteria to humans, and are particularly abundant in plant roots and animal kidneys, where rapid water transport is essential. Their discovery has significantly enhanced our understanding of cellular water management and has implications in medical research, particularly in the study of kidney functions and water balance disorders.

Osmosis is crucial for cell survival as it regulates the movement of water in and out of cells, maintaining the balance of fluids and electrolytes. This balance is vital for several reasons:

• Cell Structure and Function: The influx and efflux of water through osmosis help maintain the cell's shape and volume. For plant cells, turgidity provided by osmosis is essential for structural support and upright growth. For animal cells, osmotic balance prevents them from shrinking or bursting, which could disrupt cellular functions.
• Nutrient and Waste Transport: Osmosis assists in the transportation of nutrients into cells and waste products out of cells. Solutes dissolved in water are carried along as water moves across cell membranes.
• Biochemical Reactions: Many cellular processes depend on the aqueous environment provided by osmotic balance. Enzymatic reactions, for example, often occur in aqueous solutions.
• Osmoregulation: This is the process by which living organisms maintain the homeostatic balance of water and electrolytes. It is particularly important in organisms living in varying external environments, where the osmotic pressures can fluctuate dramatically.
• Protective Mechanisms: In adverse conditions, such as high salinity or drought, cells can alter their internal solute concentration, affecting the osmotic gradient to protect themselves.

In summary, osmosis is not just a physical phenomenon but a vital biological process integral to the health and functionality of cells. It is key to understanding how organisms interact with their environment and maintain internal stability.