Neuroscience is undergoing a dynamic transformation that some call the neurotechnological revolution. Cures for Alzheimer's are expected by 2035 based on cutting-edge research in synaptic regeneration, gene-editing, neuropharmacology, and AI-driven neuroimaging. In the next decade, CRISPR-based therapies, stem cell infusion, and targeted brain stimulation will restore cognitive function and reverse neurodegenerative damage.
Even more exciting are direct thought-to-text communication, quantum simulations of the brain, and cognitive enhancement implants. The eradication of mental illness is also not far off, enhanced by the fusion of artificial intelligence, neuroscience, and quantum computing. Researchers are on the verge of unlocking an entirely new era of human understanding and capability, shaping the future in ways we can barely comprehend today. By 2035, our relationship with the brain and perhaps even what it means to be human will be transformed forever.
Imagine setting up an appointment for your personalized brain network analysis. Your neural circuitry will be mapped, synapses will be checked, and myelin sheaths will be analyzed. As you age, myelin sheaths, the fatty, insulating layers surrounding axons, decompose. Yet, they are essential for the electrical signaling between neurons. As the brain and spinal cord age, this covering progressively loses its protective ability, leading to cognitive decline, slower reflexes, and increased susceptibility to neurodegenerative disease.
Brain Anatomy
The brain's three-pound gelatinous mass is the size of a fist. This organ thinks, senses, controls, and initiates actions. Encased in a bony shell, the brain's mass contains 75-80% water, transporting nutrients, removing waste, regulating temperature, and assisting with electrical signaling. This amazing human body command center allows you to think, dream, feel, and move.
The brain, and frankly, your entire body, needs water. More than half of your body is composed of water. Drink enough every day to keep your brain ready to do its work. Without enough water, you can experience fatigue, mood changes, and cognitive difficulties. The remaining 20-25% of the brain is mostly lipids for energy storage.
Think of the brain as having three main components: forebrain, midbrain, and hindbrain. They work together but have unique functions. The largest part is the cerebrum, which sits at the top of the brain and is the most noticeable and responsible for thought, memories, imagination, and action. The midbrain is not visible from the outside but is essential for reflexes and voluntary movements like vision. The hindbrain, which controls movement and the body's vital functions like breathing, heartbeat, and balance, sits underneath and includes the wrinkled-looking cerebellum, the brain stem, and the upper part of the spinal cord.
The cerebrum consists of two parts with a gap between the two. You might have heard that left-brained people are logical and analytical, and right-brained individuals are creative and intuitive. This strict association is a myth since both sides work together, and complex tasks involve both hemispheres. Nevertheless, mathematics, analytical processes, and language are more left-dominant, while patterns, intuition, and spatial reasoning are more right-dominant.
Some individuals harness one hemisphere more than the other, though mathematics and language require require both for creativity. For example, a neuroscientist may use the left brain for analysis but the right brain for designing experiments. Meanwhile, the two hemispheres communicate with each other via the corpus callosum, nerve fibers containing an astounding 200 million axons. Neural signals cross the corpus callosum, meaning that the right hemisphere controls the left side of the body, and the left hemisphere controls the right. When one hemisphere is damaged, like in a stroke, the opposite side is affected.
You might have heard about "gray matter". This thick surface layer, called the cortex, covers the cerebrum and cerebellum. This coating is gray because it lacks the fatty myelin coating needed for long-range, fast transmission. "White matter" on the other hand, consists mainly of myelinated axons, which carry signals quickly between different brain regions.
Much of the brain's information processing occurs in the gray matter of the cerebral cortex. The brain's folds add to the surface area, increasing the amount of gray matter, allowing more information to be processed. Since this high-density information is integrated over short distances, myelination is not as necessary. The density of synapses (communication interfaces) in the cerebral cortex is nearly unfathomable. Neuroscientists seek to unravel its complex dimensions.
The human cortex contains approximately 16 billion neurons. Each neuron in the cortex consists of thousands of synapses, each communicating via chemicals called neurotransmitters. If each cortical neuron has between 1,000 to 10,000 synapses, then there are somewhere between 100 trillion and 1 quadrillion synapses. To be clearer, that is 1,000,000,000,000,000 synapses enabling complex information processing, learning, memory, reasoning, perception, and decision-making. If you want to study neuroscience, there is a lot of processing to do. Computational neuroscience is a hot field combining AI, mathematical modeling, computer simulations, and the circuit analysis of neural networks.
The white matter area beneath the cortex is heavily myelinated because it transmits signals between the cortex and other areas of the brain. The brain's gray matter and white matter work closely together. The dense gray matter interprets, processes, and integrates, while the white matter specializes in long-distance transmission between brain regions.
Cerebral Lobes: Frontal, Parietal, Occipital, Temporal
The motor cortex sits at the back of the frontal lobe. This area helps you plan, control, and execute movements like stretching, running, or typing. The parietal lobe exists just behind the frontal lobe. This region is responsible for interpreting the body's sensory information, like touch, pain, and temperature. The parietal lobe, in conjunction with the prefrontal cortex, also processes spatial relationships and abstract thinking for geometry, graphs, and numerical calculations. The occipital lobe links images from the eyes to those stored in your memory. Thus, if the occipital lobe is damaged, you cannot connect images, which may lead to blindness. The temporal lobes lie underneath the frontal and parietal lobes. This area receives information from the ears, like music, and integrates the sensations of taste, sound, sight, and touch while forming and retrieving memories.
Inner Brain and Midbrain
Deep inside the brain, hidden underneath the cerebrum, lies the midbrain and inner brain, two of the most powerful parts of your nervous system. The midbrain acts like a high-speed messenger, connecting different areas of your brain and helping you react quickly to the world around you. The midbrain controls eye movement, hearing, and body coordination, ensuring you can catch a ball, listen to music, or turn your head when someone calls your name. The midbrain is also a key part of the dopamine system, which influences motivation and pleasure, shaping how you feel about rewards and challenges.
Even deeper, the inner brain, which includes the thalamus, hypothalamus, and limbic system, controls your emotions, memory, and survival instincts. The thalamus acts as a "relay station," directing sensory information to the right part of your brain so you can recognize a familiar face or feel warmth from the sun. The hypothalamus is your body's command center, regulating hunger, thirst, sleep, and body temperature. Meanwhile, the limbic system is where emotions and memories come to life, allowing you to remember a happy moment with friends or feel fear in a dangerous situation. Together, the midbrain and inner brain shape how you move, think, feel, and survive.
A group of nerve cells in the limbic system leads from the hypothalamus and the thalamus to the hippocampus. This region sends memories out to the cerebral hemisphere for long-term storage, retrieving information when necessary. The basal ganglia, nerve cells surrounding the thalamus, are responsible for initiating and integrating movements. When the nerve cells are damaged, an individual experiences tremors, rigidity, and difficulty walking, all signs of Parkinson's Disease.
The hindbrain and brainstem sit underneath, connecting to the spinal cord and signaling centers to the rest of the body, keeping you alive every second of the day. The hindbrain, which includes the cerebellum, pons, and medulla oblongata, is like the silent guardian of your body's most important functions. The cerebellum controls balance and movement, making sure you do not trip when walking or fall off your bike. The pons acts like a highway, helping signals travel smoothly between different parts of the brain. And the medulla oblongata? This is the reason your heart keeps beating, and your lungs keep breathing, even when you are asleep. Without the hindbrain, even the simplest actions, blinking, swallowing, or standing upright, would be impossible.
The brainstem, often called the "bridge to life", is even more impressive. This powerful structure connects your brain to the rest of your body, ensuring that every breath, heartbeat, and reflex happens without you even thinking about it. The brainstem helps you wake up in the morning, stay alert in class, and react instantly...
