Upside-Down Trains

If you’ve never seen an upside-down train before, you’ll love this.

Okay, its not entirely true that this train is upside down—unless you’re considering the upside of the train being attached to the downside of a structure (which sounds even crazier). But whatever you’d like to call it, these trains are all the hype, and it has us wondering:

Could we be seeing more of these trains in the future and what would be the benefits?

What Are Upside-Down Trains Called?

The “upside-down train”, or “upside-down railways”, are really called suspension trains or suspension railways. This make sense because the train is literally suspended from an overhead track.

There are six operable “upside-down trains” in the world: Three in Germany, two in Japan, and one in India.

Upside-down Trains in Germany

The first concept for a suspension railway was developed in England in the early 1800’s, but the first successful one was built in Wuppertal, a city in Germany in 1901.

What made it so successful? Well, its still standing today, and it’s called the Wuppertal Schwebebahn.

Schwebe means to “float” or “hover” and bahn means “railway” or “train”. So, Schwebebahn can mean either “floating railway” or “hovering train”; both of which are very cool sounding alternatives to suspensions railways.

Wuppertal Germany is known for this particular suspension railway; in fact, this “hovering train” is cited number one for the top attraction in Wuppertal on Tripadvisor.

Why Are There So Many Hanging Monorails In Germany?

When a country is known for something because of its great success, they tend to ride the wave and create more of that thing. Afterall, that’s it’s pride and glory.

The U.S, as an example, has arguably produced some of the best movies on the planet. So, its no surprise the America is known for Hollywood entertainment, and the result is that the U.S. produces the most number of movies by far.

For this reason, you’ll find that the majority of hanging Monorails trains are located in Germany, and it turns out that there could be some subtle benefits to these railways.

Advantages of Upside-down Trains

The obvious advantage of upside-down trains is they avoid traffic congestion, saving commuters valuable time. This is true of regular monorails, but upside-down monorails can offer a slight advantage because they are very space efficient. In densely populated areas, space efficiency could mean significantly less traffic congestion, which could make them even more ideal than regular monorails.

A more subtle advantage is that Views from high above are psychologically healthy. Infact, something as simple as a view from a window has shown to improve attention, reduce negative emotions, and even lower stress.

Passengers in the U.S. alone commute billions of kilometres a year on trains to and from work. Upside-down trains can make a positive difference for these commuters, especially if it provides a view of nature below.

Which brings us to the last advantage: Upside-down railways can be created with minimal environmental impact. It can navigate steep gradients, tight curves, and challenging terrain without disrupting natural landscapes. So, not only does it function like a regular monorail, but it provides the opportunity for some pretty amazing views of nature that boost the productivity of commuters as they head to work or school.

Where Are All the Up-side Down Railways Located?

• 1. Wuppertal Schwebebahn (Germany)

• Opened: 1901

Wuppertal Schwebebahn is the oldest and most famous hanging railway in the world. It runs over the Wupper River and streets of Wuppertal. It is a key part of the city’s public transport network. Imagine that!

• 2. Chiba Urban Monorail (Japan)
• Opened: 1988.

This is the world’s longest suspended monorail and it extends over 15 kilometers. It connects major areas in the city of Chiba and is used by both local commuters and tourists.

• 3. Shonan Monorail (Japan)
• Opened: 1970

The Shonan Monorail is arguably the most scenic suspended monorail, and it definitely has our pick. It runs from Kamakura to Fujisawa, which is about 6km, and offers commuters with some incredible views of the coastline.

• 4. Schwebebahn Dresden (Germany)
• Opened: 1901

This upside-down train is in Dresden Germany and is the second-oldest suspended railway in Germany.

• 5. Dortmund H-Bahn (Germany)
• Opened: 1984

This is the mode of transportation for the Dortmund University campus. It shuttles students and faculty between different areas. Talk about some lucky students.

• 6. Skybus Metro Test Track (India)
• In the Works: 2004 (Test Operations)

This is a test track in Goa and is currently part of an experimental elevated rail system. It was introduced to address urban transportation challenges like traffic congestion, which is a huge concern in India. Trails started in 2004 and stopped shortly after, but interest still remains, and its likely that India could be the first to start seeing upside-down rails in the near future.

A Great Advancement for 3D Printed Organs

3D printing in hospitals is nothing new, but for the first time in history, a woman received a 3D printed windpipe that became a fully functional without the need for immunosuppressants.

Immunosuppressants are used during organ transplants to keep the body from attacking the organ that it see’s as foreign. This means that the organ the woman received was organic and personalized for her, as if she had it her entire life.

This mind-blowing news shows that we are now closer than ever to being able to create full-scale, functional, and complicated 3D printed organs like a heart or lung.

But what about creating a brain?

3D Printing and Organoid Intelligence

Organoid Intelligence, or OI, is an emerging field of study that is focused on creating bio-computers by merging AI with real brain cells called organoids. Organoids are miniature and simplified versions of organs grown in a lab dish. They mimic some of the functions of fully grown organs, like brains. The idea behind OI is that by increase the cells organoids contain, they may begin to function like fully grown brains, and can then be used alongside computers to enhance Artificial Intelligence.

It turns out that the world’s first 3D printed windpipe was so successful that we are now closer than ever to creating the world first organoid intelligent bio-computer.

Here’s why.

The World’s First 3D Printed Windpipe

Transplant patients usually have to take a long course of immunosuppressants that help the body accept the organ. The body see’s the organ as foreign, and so the immune system begins to attack the new organ, which can lead to more complicated health problems.

The woman in her 50’s who received the 3D printed windpipe did so without any immunosuppressants. In just 6 months after the operation, the windpipe healed and began to form blood vessels, and of course, more cells.

The current goal of scientists in the field of Organoid Intelligence is to increase organoids from 100,000 cells to 10 million, and this begs the question:

Can 3D printing help build bio-computers by creating better organoids?

Can 3D Printing Help Build Bio-Computers?

The worlds first 3D printed windpipe shows that advances in 3D printing can create better functioning organs, and this implies that we can also create more intricate organoids to help in the field of Organoid Intelligence and eventually create bio-computers.

Its important to understand the distinction between 3D printing an organ and printing something like a tool or musical instrument.

The difference between printing an organ and printing a non-biological structure depends on the ink being used in the 3D printer.

3D printing non-organic structures will require ink that can be made from plastic, plastic alternatives like PLA, metal, and ceramics. On the other hand, 3D printed organs are made from ink called “bio-inks” that are a mixture of living cells and biocompatible substances like the ones mentioned above.

In the case of the 3D printed windpipe, the ink used was partly formed from the stem and cartilage cells collected from the woman’s own nose and ear. It was because of this bio-ink that the woman’s body did not reject the organ.

The Problem With 3D Printed Organs

Organs created with bioprinting need to function like real organs for the body to safely use them, and this does not happen right away.

The 3D printed organs need to go beyond just a printed structure and become living. They need to form tissues and cells that help create biological functionality, and forming these cells take time.

The problem with 3D bioprinting is that the ink used for the printer needs to be effective at doing this, and if it is not, the organ may not stay functional.

The ink used for the 3D-printed windpipe was made from part bio-ink and part polycaprolactone (PCL), a synthetic polyester material.

PCL is a used in the 3D ink for the purposes of maintain the structure of the windpipe, while the bio-ink is used to help the 3D printed organ to become fully biological in time so that the body can use it.

The PCL maintains the structure while the bio-ink does it’s thing.

The problem with PCL is that it is biodegradable and won’t last forever. In fact, doctors don’t expect the 3D-printed windpipe to last more than five years.

The Solution is Better Bio-ink

The 3D printed windpipe was not just made using PCL, but it contained bio-ink made from living cells too. The hope is that the living cells in the 3D printed organ—which came from the bio-ink—will assist the patient’s body in creating a fully functional windpipe to replace the PCL’s function.

If the organ begins to form cells and tissue by itself, then the function of PCL will be replaced by the biological function of the organ that is growing.

The organ becomes real!

Bio-Ink helps the 3D printed organ mimic it’s natural environment of cells and eventually become a real organ.

3D Printing Organs Will Save Lives

Every year, thousands of people need a lifesaving organ transplant. These transplants cost hundreds of thousand of dollars, and many people who need them don’t make it passed the waiting list.

3D Printing organs could give people the incredible opportunity to receive the help they need when they need it, saving thousands of lives annually, and millions of lives in the long run.

As advances are made in 3D Bioprinting, they will also be made in areas of Organoid and Artificial Intelligence, which shows that the progress being made in one place will once again shine its way to another.

Flow Hive

Flow Hive is the most revolutionary invention in beekeeping in history.

The innovation allows beekeepers to tap into honey directly from the hive without the mess and expensive processing equipment inherent in traditional beekeeping.

However, the invention goes beyond simply streamlining the harvesting process. The idea of Flow Hive started when founder Cedar Anderson was just a boy. He wanted to save the bees from being crushed when harvesting honey, and he and his father eventually created a very successful business from it.

How Does Flow Hive Work?

Before Flow Hive, the extraction process of honey involved breaking the hive to get to the honeycomb cells, manually removing the beeswax to get to the honey, and then using an extractor to collect the honey.

By comparison, Flow Hive uses Flow Frames, which the honey bees fill with wax and form honey on. When honey is formed, a Flow Key is inserted and rotated, which allows honey to flow right out of the Flow Frame and into a cup or jar, similar to turning on a faucet.

No breaking, no mess, no expensive processing equipment, and for those who would like to save the bees, no disturbed bees.

A Father and Son Bond is an Incredible Thing

Flow Hive’s are like a mini house that even the most spirited bees would be happy to call their home. Founders Stuart Anderson and his son Cedar come from three generations of beekeepers. This culture formed a father-son bond, creating the most innovative invention in beekeeping history.

How Did Flow Hive Start?

Flow Hive started in the mind of Cedar when he was just a child who felt bad that so many bees were being crushed while harvesting honey.

Imagine, a young boy raised to admire the social creatures that have sustained his family’s livelihood for three generations, and some of those very creatures are being harmed in the process.

A child’s innocence is a remarkable thing, but who would have known that it would become such a lucrative business?

“The first idea was simply that there must be a better way, and I’d been thinking about that from a very young age.”

That idea—brought about by a feeling in a young boy’s heart—eventually created the prototype which broke crowdfunding records.

Within 10 minutes on Indiegogo, they had surpassed their goal of raising $70,000, and within 15 minutes, they had already raised $250,000.

The campaign raised a total of $14,959,087, making it one of the most successful crowdfunding campaigns in history.