The neural probe explores how to integrate electrochemistry, material science, and electrical engineering into biotechnology to make a healthy, happy future by revealing the true self of neural activities and its delicate algorithms. As such humanity can translate electrochemical signals between the neuronal groups to algorithms, allowing us for a deep understanding of the foundation of the brain, causing and medical treatment of neurological disorders. The company has successful partnerships with the biggest tertiary hospitals in South Korea. The bioengineering, neuroscience, and brain engineering projects are undergoing wildly with excellent knowledge and on-site data from the lab. With this expertise and experience, the next step is going into the global market and seeking R&D-based companies and universities doing scientific research in this field in order to do international R&D projects to acquire extra knowledge and insight into bioengineering, neuroscience, and brain engineering to support humanity. Their product, a neural probe, is in the core. A neural probe is a scientific tool that captures what is happening in the neuron scale, such as neural spikes and cell activities. These marks are significant for describing how to translate undergoing process inside an animal brain to mathematical algorithms or medical 2D images. The fact indicates that scientists and engineers must consider high functionality and biocompatibility for designing a neural probe. Attention to the Human-computer interface (HCI) field has increased since the 20th century when humans dreamed of communicating with other high-intelligence life forms. From science fiction about extraterrestrial civilizations to machine interfaces, humanity tried to establish mathematical and scientific descriptions behind the intellectual process. The company designed and developed the neural probe with much pride and professionality for this generation and the upcoming Fourth industrial biotechnological revolution society. The neural probe is full of technological evolution. It has 8 to 32 nano-scale electrodes coated in biocompatible high-polymer materials. Its customizable channels can capture neural activities precisely and effectively in the electrochemical pool where neurons combine and communicate. Because of its nano-scale size, it can access the inner brain, such as the laboratory mouse’s hippocampus and motor cortex. Furthermore, the company has expertise in making durable biomaterial circuit boards. The neural probe is built upon a flexible printed circuit board (fPCB), so the user does not have to care whether the neural probe is broken inside the brain.