Paralyzed By Polio, This British Tea Broker Changed the Course Of Medical History Forever
Robin Cavendish in his special wheelchair with his son Jonathan in the 1960s.
In December 1958, on a vacation with his wife in Kenya, a 28-year-old British tea broker named Robin Cavendish became suddenly ill. Neither he nor his wife Diana knew it at the time, but Robin's illness would change the course of medical history forever.
Robin was rushed to a nearby hospital in Kenya where the medical staff delivered the crushing news: Robin had contracted polio, and the paralysis creeping up his body was almost certainly permanent. The doctors placed Robin on a ventilator through a tracheotomy in his neck, as the paralysis from his polio infection had rendered him unable to breathe on his own – and going off the average life expectancy at the time, they gave him only three months to live. Robin and Diana (who was pregnant at the time with their first child, Jonathan) flew back to England so he could be admitted to a hospital. They mentally prepared to wait out Robin's final days.
But Robin did something unexpected when he returned to the UK – just one of many things that would astonish doctors over the next several years: He survived. Diana gave birth to Jonathan in February 1959 and continued to visit Robin regularly in the hospital with the baby. Despite doctors warning that he would soon succumb to his illness, Robin kept living.
After a year in the hospital, Diana suggested something radical: She wanted Robin to leave the hospital and live at home in South Oxfordshire for as long as he possibly could, with her as his nurse. At the time, this suggestion was unheard of. People like Robin who depended on machinery to keep them breathing had only ever lived inside hospital walls, as the prevailing belief was that the machinery needed to keep them alive was too complicated for laypeople to operate. But Diana and Robin were up for the challenges – and the risks. Because his ventilator ran on electricity, if the house were to unexpectedly lose power, Diana would either need to restore power quickly or hand-pump air into his lungs to keep him alive.
Robin's wheelchair was not only the first of its kind; it became the model for the respiratory wheelchairs that people still use today.
In an interview as an adult, Jonathan Cavendish reflected on his parents' decision to live outside the hospital on a ventilator: "My father's mantra was quality of life," he explained. "He could have stayed in the hospital, but he didn't think that was as good of a life as he could manage. He would rather be two minutes away from death and living a full life."
After a few years of living at home, however, Robin became tired of being confined to his bed. He longed to sit outside, to visit friends, to travel – but had no way of doing so without his ventilator. So together with his friend Teddy Hall, a professor and engineer at Oxford University, the two collaborated in 1962 to create an entirely new invention: a battery-operated wheelchair prototype with a ventilator built in. With this, Robin could now venture outside the house – and soon the Cavendish family became famous for taking vacations. It was something that, by all accounts, had never been done before by someone who was ventilator-dependent. Robin and Hall also designed a van so that the wheelchair could be plugged in and powered during travel. Jonathan Cavendish later recalled a particular family vacation that nearly ended in disaster when the van broke down outside of Barcelona, Spain:
"My poor old uncle [plugged] my father's chair into the wrong socket," Cavendish later recalled, causing the electricity to short. "There was fire and smoke, and both the van and the chair ground to a halt." Johnathan, who was eight or nine at the time, his mother, and his uncle took turns hand-pumping Robin's ventilator by the roadside for the next thirty-six hours, waiting for Professor Hall to arrive in town and repair the van. Rather than being panicked, the Cavendishes managed to turn the vigil into a party. Townspeople came to greet them, bringing food and music, and a local priest even stopped by to give his blessing.
Robin had become a pioneer, showing the world that a person with severe disabilities could still have mobility, access, and a fuller quality of life than anyone had imagined. His mission, along with Hall's, then became gifting this independence to others like himself. Robin and Hall raised money – first from the Ernest Kleinwort Charitable Trust, and then from the British Department of Health – to fund more ventilator chairs, which were then manufactured by Hall's company, Littlemore Scientific Engineering, and given to fellow patients who wanted to live full lives at home. Robin and Hall used themselves as guinea pigs, testing out different models of the chairs and collaborating with scientists to create other devices for those with disabilities. One invention, called the Possum, allowed paraplegics to control things like the telephone and television set with just a nod of the head. Robin's wheelchair was not only the first of its kind; it became the model for the respiratory wheelchairs that people still use today.
Robin went on to enjoy a long and happy life with his family at their house in South Oxfordshire, surrounded by friends who would later attest to his "down-to-earth" personality, his sense of humor, and his "irresistible" charm. When he died peacefully at his home in 1994 at age 64, he was considered the world's oldest-living person who used a ventilator outside the hospital – breaking yet another barrier for what medical science thought was possible.
Lab-grown insect meat could be the protein source of the future.
Agriculture in the 21st century is not as simple as it once was. With a population seven billion strong, a climate in crisis, and sustainability in farming practices on everyone's radar, figuring out how to feed the masses without destroying the Earth is a pressing concern.
Tufts scientists argue that insect cells may be better suited to lab-created meat protein than traditional farm animal cells.
In addition to low-emission cows and drone pollinators, there's a promising new solution on the table. How does "lab-grown insect meat" grab you?
Writing in Frontiers in Sustainable Food Systems, researchers at Tufts University say insects that are fed plants and genetically modified for maximum growth, nutrition, and flavor could be the best, greenest alternative to our current livestock farming practices. This lab-grown protein source could produce high volume, nutritious food without the massive resources required for traditional animal agriculture.
"Due to the environmental, public health, and animal welfare concerns associated with our current livestock system, it is vital to develop more sustainable food production methods," says lead author Natalie Rubio. Could insect meat be the key?
Next Up
New sustainable food production includes what's called "cellular agriculture," an emerging industry and field of study in which meat and dairy are produced via cells in a lab instead of whole animals. So far, scientists have primarily focused on bovine, porcine, and avian cells to create this "cultured meat."
But the Tufts scientists argue that insect cells may be better suited to lab-created meat protein than traditional farm animal cells.
"Compared to cultured mammalian, avian, and other vertebrate cells, insect cell cultures require fewer resources and less energy-intensive environmental control, as they have lower glucose requirements and can thrive in a wider range of temperature, pH, oxygen, and osmolarity conditions," reports Rubio.
"Alterations necessary for large-scale production are also simpler to achieve with insect cells, which are currently used for biomanufacturing of insecticides, drugs, and vaccines," she adds.
They still have some details to hash out, however, including how to make cultured insect meat more like the steak and chicken we're all familiar with.
"Despite this immense potential, cultured insect meat isn't ready for consumption," says Rubio. "Research is ongoing to master two key processes: controlling development of insect cells into muscle and fat, and combining these in 3D cultures with a meat-like texture." They are currently experimenting with mushroom-derived fiber to tackle the latter.
People would still be able to eat meat—it would just come from a different source.
Open Questions
As the report points out, one thing that makes cellular agriculture an attractive alternative to high-density animal farming is that it doesn't require consumers to change their behaviors. People would still be able to eat meat—it would just come from a different source.
But the big question remains: How will lab-grown insect meat taste? Will the buggers really taste as good as burgers?
And, of course, there's the "ew" factor. Meat alternatives have proven to work for some people—Tofurky is still in business, after all—but it may be a hard sell to get the masses to jump on board with eating bugs. Consuming creepy crawlies sounds simply unpalatable to many, and the term "lab-grown, cellular insect meat" doesn't help much. Perhaps an entirely new nomenclature is in order.
Another question is whether or not folks will trust such scientifically-created food. People already use the term "frankenfood" to refer to genetic modification -- even though the vast majority of the corn and soybeans planted in the U.S. today are genetically engineered, and other major crops with GM varieties include potatoes, apples, squash, and papayas. Still, combining GM technology with eating insects may be a hard sell.
However, we're all going to have to get used to trying new things if we want to leave a habitable home for our children. If a lab-grown bug burger can save the planet, maybe it's worth a shot.
Six Reasons Why Humans Should Return to the Moon
An astronaut does a spacewalk on the Moon.
"That's one small step for man; one giant leap for mankind."
This July 20th marks fifty years since Neil Armstrong, mission commander of NASA's Apollo 11, uttered those famous words. Much less discussed is how Project Apollo shifted lunar science into high gear, ultimately teaching scientists just how valuable the Moon could become.
A lunar-based solar power system would actually be cheaper than Earth-based solar power implemented on a global scale.
During the six missions that landed humans on the lunar surface from 1969 to 1972, Apollo astronauts collected some 842 pounds of lunar rocks and dirt. Analysis of these materials has provided us with major clues about the origin of Earth's celestial companion 4.51 billion years ago, but also has revealed the Moon is a treasure trove. Lunar rock contains a plethora of minerals with high industrial value. So let's take a look at some prime examples of how humanity's expected return to the lunar surface in the years to come could help life here on Earth.
24/7 solar energy for Earth
During the 1970s, scientists began examining the Apollo lunar samples to study how the lunar surface could be used as a resource. One such scientist was physicist David Criswell, who has since shown that a lunar-based solar power system would actually be cheaper than Earth-based solar power implemented on a global scale. Whoa! How is that possible, given the high cost of launching people and machines into space?
The key is that it would be enormously expensive to scale up enough Earth-based solar power to supply all of humanity's electrical needs, since solar power on such a scale would require a lot of metal, glass, and cement.
But the Moon's lack of atmosphere and weather means that photovoltaic cells built by robots from lunar materials can be paper thin, in contrast with the heavy structures needed in Earth-based solar arrays. Ringing the Moon, such a system would be in perpetual sunlight, making it cheaper to collect solar power there and beam it down to Earth in the form of microwaves.
A source of helium-3 for clean, safe nuclear fusion power and other uses
The gas helium-3 is extremely rare on Earth, but plentiful on the Moon, and could be used in advanced nuclear fusion reactors. Helium-3 also has anti-terrorism and medical uses, especially in the diagnosis of various pulmonary diseases.
A place to offload industrial pollution
Since there are minerals and oxygen in lunar rocks and dust, and frozen water in certain locations, the Moon is an ideal home for factories. Thus, billionaire Jeff Bezos has proposed relocating large segments of heavy industry there, reducing the amount of pollution that is produced on Earth.
The Moon could be a place for colonists to get their space legs before humans put down roots on more distant locations like Mars.
Radio Astronomy without interference from Earth
Constructed on the Moon's far side (the side of the Moon that always faces away from Earth), radio telescopes advancing human knowledge of the Cosmos, and searching for signals from extraterrestrial civilizations, could operate with increased sensitivity and efficiency.
Lunar Tourism
Using the Moon as a destination for tourists may not sound helpful initially, given that only the very wealthy would be able to afford such journeys in the foreseeable future. However, the economic payoff could be substantial in terms of jobs that lunar tourism could provide on Earth. Furthermore, short of actual tourism, companies are gearing up to provide lunar entertainment to fun-seekers here on Earth in the form of mini lunar rovers that people could control from their living rooms, just for fun.
Lunar Colonies
Similar to lunar tourism, lunar colonization sounds initially like a development that would help only those people who go. But, located just three-days' travel from Earth, the Moon would be an excellent place for humanity to become a multi-planet species. The Moon could be a place for colonists to get their space legs before humans put down roots on more distant locations like Mars. With hundreds or thousands of humans thriving on the Moon, Earthlings might find some level of peace of mind knowing that humanity is in a position to outlive a planetary catastrophe.