Temperature has a significant effect on active transport, as it influences both the kinetic energy of molecules and the activity of the protein carriers involved in the process. Generally, as temperature increases, the rate of active transport also increases, up to an optimal point. This is because higher temperatures provide more kinetic energy to molecules, potentially increasing the rate at which they interact with carrier proteins. However, if the temperature rises too high, it can denature the protein carriers, rendering them dysfunctional. This leads to a decrease or cessation of active transport. On the other hand, at lower temperatures, the kinetic energy of molecules is reduced, and the activity of enzymes and carrier proteins involved in active transport is diminished, leading to a slower transport rate. Thus, active transport is most efficient within a specific temperature range that supports optimal protein function without causing denaturation.

Active transport is critically important in nerve cells (neurons) for maintaining the proper balance of ions across their membranes, which is essential for nerve impulse transmission. Neurons rely on the maintenance of specific concentration gradients of ions like sodium (Na⁺) and potassium (K⁺) across their membranes. Active transport, particularly through the sodium-potassium pump, continuously moves Na⁺ out of the cell and K⁺ into the cell against their concentration gradients. This action helps restore and maintain the resting membrane potential, a crucial state for the conduction of nerve impulses. Without active transport, the ionic balance necessary for the generation and propagation of nerve impulses would be disrupted, impairing the functioning of the nervous system.

ATP hydrolysis is a crucial aspect of active transport, providing the necessary energy to drive the movement of substances against their concentration gradient. ATP (adenosine triphosphate) is the primary energy currency of the cell, and its hydrolysis (the chemical breakdown of ATP into ADP and an inorganic phosphate) releases energy. This energy is used to change the shape of carrier proteins embedded in the cell membrane. These conformational changes allow the proteins to bind to specific molecules or ions, transport them across the membrane, and release them on the other side. Without the energy provided by ATP hydrolysis, these carrier proteins would not be able to function, and active transport would not occur. This process is essential for various cellular functions, including maintaining ion balance, nutrient uptake, and waste removal.

Active transport can occur without oxygen, although the process is typically less efficient. Oxygen is crucial for aerobic respiration, which is a primary source of ATP, the energy currency needed for active transport. However, in the absence of oxygen, cells can still produce ATP through anaerobic respiration, although the amount of ATP generated is significantly less compared to aerobic respiration. For instance, in human muscle cells, during intense exercise when oxygen supply is limited, anaerobic respiration produces ATP, allowing active transport processes to continue, albeit at a reduced rate. Similarly, certain microorganisms that thrive in oxygen-deprived environments rely on anaerobic respiration to fuel active transport. Thus, while oxygen is essential for optimal ATP production, active transport can still occur in its absence, using the ATP generated from anaerobic pathways.

The concentration gradient plays a pivotal role in active transport. Unlike passive transport, where substances move down their concentration gradient (from high to low concentration), active transport moves substances against their concentration gradient (from low to high concentration). This process requires significant energy, typically in the form of ATP, because moving substances in opposition to their natural gradient is energetically unfavourable. The steeper the concentration gradient (i.e., the greater the difference in concentration between two sides of the membrane), the more energy is required to transport substances. This is because a steeper gradient represents a larger 'uphill' task for the transport proteins, demanding more ATP to achieve the necessary movement of molecules or ions. In essence, the concentration gradient in active transport is a barrier that must be overcome by the input of energy, highlighting the fundamental difference between active and passive transport mechanisms.