Today, the world in which we live is much different from the past and will further transform in the future. Change is a constant aspect of life that the world is continuously witnessing, especially owing to fast technological development and advancements. Seemingly, certain technology trends around us are either becoming obsolete while others are becoming more advanced. It is evident that due to these shifts and developments, our way of acting, reacting, or doing business, is going to transform. Indeed, it will have a significant effect on the way we live our lives.

Where in the embryo does the person reside? Morphogenesis – the formation of the body from an embryo – once seemed so mystifying that scholars presumed the body must somehow already exist in tiny form at conception. In the 17th century, the Dutch microscopist Nicolaas Hartsoeker illustrated this'preformationist' theory by drawing a foetal homunculus tucked into the head of a sperm. This idea finds modern expression in the notion that the body plan is encoded in our DNA. But the more we come to understand how cells produce shape and form, the more inadequate the idea of a genomic blueprint looks, too. What cells follow is not a blueprint; if they can be considered programmed at all, it's not with a plan of what to make, but with a set of rules to guide construction. One implication is that humans and other complex organisms are not the unique result of cells' behaviour, but only one of many possible outcomes.

The concept of automation in business and non-business functions has undergone more than a few evolutions along the way. The earliest types of automation-related applications could only carry out repetitive tasks such as printing and basic calculations. In a bid to save time and minimize human error, such applications were used by businesses and individuals to automate the tasks that, according to organizations, employees didn't need to waste their energy on. The eventually widespread adoption of IoT, AI and robotics resulted in the growth of cognitive automation to execute more challenging, diverse and multifaceted functions such as supply chain operations, robotic surgery, architecture and construction. The sheer accuracy and consistency of cognitive automation tools powered by AI and robotics allow organizations to evaluate data at lightning-quick speed, predict future trends in consumer demand patterns and formulate robust strategies and frameworks for improved operational efficiency and regulatory compliance.

The world's first-ever living robots- Xenobots, were developed by a group of researchers from the University of Vermont and Tufts University, USA. These bots are named after the African clawed frog, Xenopus laevis from which their stem cells were harvested. Under one millimeter in size, these bots are self-healing and small enough to travel inside a human body. They can move forward, backward, and also spin in circles. While these Xenobots could create an evolutionary epoch, researchers believe that they also have potential risks, and experimenting with such living cells can create unforeseen consequences. The researchers from the University of Vermont and Tufts University wanted to figure out if they could take real-life cells and make them behave in a specific way, much like a traditional robot made of other materials.

A groundbreaking feat recently occurred for artificial intelligence and robots alike when the first-ever reproduction was witnessed in robots called "Xenobots. Well, the term "Xenobot" isn't brand new but was reported in 2020 as the tiny "programmable" living things made of several thousand frog stem cells. Since then, Xenobots have been in the global headlines because of the evolutions shown by them. In 2020, scientists created the first-ever living, programmable robot by assembling frog cells. These pioneer Xenobots could move around in fluids, and scientists claimed they could be useful for monitoring radioactivity, pollutants, drugs, or diseases.

As if it were a graphic novel by Science fiction, the first birth of robots called xenobots in the United States, which were made with frog cells. The xenobots are bio robots millimeter that could be replicated from themselves. Researchers from the universities of Vermont, Tufts and Harvard noted that in 2020 the first of their kind were assembled from frog cells. These organisms were designed on a computer and assembled by hand; they can swim in a petri dish, find individual cells, and collect hundreds of them, the University of Vermont reported late last November. These robots that can have "children" they are shaped like Pac-man and it keeps these cells inside its "mouth", they are also capable of assembling "babies" that look and move in the same way as they do.

A lot of freaky stuff is happening in the world of artificial intelligence. Imagine a human brain, multiply its deduction capabilities by billions, and eliminate the human predisposition for self-doubt - that's a derivative definition of artificial intelligence. In the last decade, great strides have been made in machine learning and artificial intelligence, which scientists believe could quicken the pace of breakthroughs in almost all arenas - from medicine, economy, and even climate change. AI programmes are fed data through which they improve their results. The wider and accurate the database, the better results AI will produce.

AI-designed (C-shaped) organisms push loose stem cells (white) into piles as they move through their environment. To persist, life must reproduce. Over billions of years, organisms have evolved many ways of replicating, from budding plants to sexual animals to invading viruses. Now scientists at the University of Vermont, Tufts University, and the Wyss Institute for Biologically Inspired Engineering at Harvard University have discovered an entirely new form of biological reproduction--and applied their discovery to create the first-ever, self-replicating living robots. The same team that built the first living robots ("Xenobots," assembled from frog cells--reported in 2020) has discovered that these computer-designed and hand-assembled organisms can swim out into their tiny dish, find single cells, gather hundreds of them together, and assemble "baby" Xenobots inside their Pac-Man-shaped "mouth"--that, a few days later, become new Xenobots that look and move just like themselves.

A dozen organisms designed by artificial intelligence known as xenobots (C-shaped; beige) beside loose frog stem cells (white). A dozen organisms designed by artificial intelligence known as xenobots (C-shaped; beige) beside loose frog stem cells (white). Scientists say they've witnessed a never-before-seen type of replication in organic robots created in the lab using frog cells. Among other things, the findings could have implications for regenerative medicine. The discovery involves a xenobot – a simple, "programmable" organism that is created by assembling stem cells in a Petri dish -- and is described by a team of researchers from Tufts University, Harvard University and the University of Vermont in a paper published this week in the Proceedings of the National Academy of Sciences.

Life finds a way, and the same goes for even robots, according to a group of scientists who say the first living robotic life forms can reproduce. In January 2020, a team of scientists from the University of Vermont, Tufts University and Harvard University took stem cells from African clawed frog embryos and formed them into tiny living creatures called xenobots. The xenobots, which are less than 0.04 inches wide, were able to move on their own, communicate amongst each other and heal themselves from an injury, making them the first-ever living robots. But over one year later, the computer-designed creatures have begun to do "something that's never been observed before." What the team of scientists discovered was the xenobots would move around their environment and find single cells.