Next, We Brew Warmer Robots

AI-Generated

Steve Walker Warsaw May 9, 2024

The Inevitable

In the vast landscape of human progress, the notion of creating beings akin to ourselves has persisted across civilizations and epochs. From ancient mythologies to modern advancements, the desire to replicate human qualities in machines reflects our innate pursuit of innovation and improvement.

Throughout the annals of history, humanity has continually pushed the boundaries of possibility, seeking to transcend limitations and expand the horizons of what is achievable. From the earliest tools to the latest technological marvels, each innovation has propelled us forward on our journey of discovery.

As we stand at the threshold of a new era, the emergence of warmer robots marks a significant milestone in our technological evolution. These robots, endowed with warmth, intelligence, and empathy, offer a glimpse into a future where machines seamlessly integrate into our lives, enriching our experiences and enhancing our capabilities.

But what if warmer robots represent more than just a feat of engineering? What if they hold the key to addressing some of humanity’s most pressing challenges, from healthcare to social cohesion to environmental sustainability?

A Harmony of Three

Amidst the dissolution of conventional boundaries and the fusion of industries, three distinct realms find themselves on the cusp of convergence, heralding a profound shift in our reality. Leading the charge is Artificial Intelligence (AI), an ever-present force seamlessly interwoven into our daily lives, revolutionising efficiency and spurring innovation across both professional and leisure domains.

Near behind is Gene Editing (GE), epitomised by the revolutionary CRISPR technology, lauded for its pivotal role in driving transformative medical breakthroughs amidst a global pandemic, ranging from RNA vaccines to pioneering genome research.

Finally, we encounter Targeted Microbial Fermentation (TMF), a quietly potent force propelled into uncharted territories of capability by the advancements in AI and CRISPR, including gene manipulation facilitated by tools like CRISPR, offering unparalleled avenues for scientific exploration and advancement.

This collision of industries marks the inception of a new epoch, where the lines between technology, biology, and medicine blur to reveal unprecedented opportunities. AI, with its computational prowess and adaptive learning capabilities, has redefined the landscape of innovation, unlocking realms once deemed unattainable. CRISPR, with its precision gene-editing mechanisms, has unravelled the complexities of the human genome, paving the way for personalized medicine and genetic therapies.

Hydrogen Producers Gas to PHA via Microbial Fermentation, the leather of the future?

Hydrogen is a dynamic building block but if we are to have enough of it to make a difference we are challenged to find alternative ways of getting hold of it, feeding hydrogen producer’s gas to microbes through microbial fermentation nurtures and grows microbes which once processed have the appearance, feel, durability and quality of leather and that’s because the end product is made from or grown out of microbes which replicate collagen. Producing the same biological material leather is made from, in scaled-up bio-manufacturing using hydrogen producer’s gas isn’t just the silver bullet the shoe and car industry was looking for, it also produces waterless green hydrogen as a byproduct  

Alternative Collagen can be produced after recycling waste carbon

Currently, Polyhydroxyalkanoates (PHA) are fermented to produce organic materials such as polymers, once produced these organic polymers are further processed to manufacture bio-compatible, bio-degradable plastics. The same bio-manufacturing process can also produce collagen at scale a replacement for animal skin, leather manufactured by the fermentation and processing of microbes

Though this bio-manufacturing process has been slow to catch on because traditionally it is relatively expensive, compared to low-cost oil-based plastics costs are being cut as producer’s gas demonstrates an ideal carbon-rich, abundant source of feedstock for microbial fermentation.

TITAN converts abundant low-value forest waste whilst ASMARA converts abundant and problematic, sorted municipal solid waste to produce a carbon-rich hydrogen producer’s gas enabling the ramping up of PHA fermentation and with much lower cost than in the previous production facilities. 

PHA products can replace many of the materials we use every day and not only those used to produce the items we only use once. PHA is recyclable, biodegradable, and biocompatible the opportunity to recycle PHA is unlimited and if for any reason PHA materials are landfilled or accidentally become sea fill PHA will happily break down in nature without harming the environment because PHA like natural other material is biocompatible it poses no chemical threat to our health or our environments well being. 

In the very near future, low-cost Hydrogen Producer Gas sourced PHA materials will go mainstream and replace oil-based plastics. As a result, much of the new PHA materials which will enter our supply chain in the next decade could be represented by a product which has been recycled from recovered oil-based thermoplastics as we clean up our environment.    

PHA Collagen the next step forward

Collagen roughly describes the main constructive protein of our bodies, it makes up approximately 30% of our body mass, as it does all mammals. Collagen is the fundament of our connective tissue, our bones, our skin, our tendons and our ligaments they are all made from collagen. 

PHA leather collagen can replace animal products like leather shoes and sneakers, jackets, belts and many other types of apparel that can be produced without the unnecessary environmental impact of fast fashion, most importantly they can be manufactured without the need to raise and slaughter animals for their skins.

Think of the benefits for the car industry to receive readily matching leather collagen hides all of regular size and shape. Mass-produced, PHA leather collagen is highly competitive in cost and ramping up PHA production means more affordability for items such as good quality apparel and footwear with far less production waste. The PHA value proposition for the fashion industry is top-quality materials, at competitive costs and with a zero landfill potential.       

PHA alt leather collagen is produced through Microbial Fermentation an industry enjoying dynamic growth and the potential for becoming a commonplace industrial practice that renders oil redundant in the production of fuels, chemicals and materials.