Meet the hybrid micro-robot: innovative technology only 10 microns across
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Research
Mar 27th, 2023
Tiny Robot Navigates in Physiological Environment and Captures Targeted Damaged
- Medicine
- Engineering
Researchers at Tel Aviv University have developed a hybrid micro-robot, the size of a single biological cell (about 10 microns across), that can be controlled and navigated using two different mechanisms - electric and magnetic. The micro-robot is able to navigate between different cells in a biological sample, distinguish between different types of cells, identify whether they are healthy or dying, and then transport the desired cell for further study, such as genetic analysis. The micro-robot can also transfect a drug and/or gene into the captured targeted single cell. According to the researchers, the development may help promote research in the important field of 'single cell analysis', as well as find use in medical diagnosis, drug transport and screening, surgery, and environmental protection.
Inspired by Biological Micro-swimmers
The innovative technology was developed by Prof. Gilad Yossifon from the School of Mechanical Engineering and Department of Biomedical Engineering at Tel Aviv University and his team: post-doctoral researcher Dr. Yue Wu and student Sivan Yakov, in collaboration with Dr. Afu Fu, Post-doctoral researcher, from the Technion, Israel Institute of Technology. The research was published in the journal Advanced Science.
“Developing the micro-robot’s ability to move autonomously was inspired by biological micro-swimmers, such as bacteria and sperm cells. This is an innovative area of research that is developing rapidly, with a wide variety of uses in fields such as medicine and the environment, as well as a research tool.” - Prof. Gilad Yossifon
Prof. Gilad Yossifon explains that micro-robots (sometimes called micro-motors or active particles) are tiny synthetic particles the size of a biological cell, which can move from place to place and perform various actions (for example: collection of synthetic or biological cargo) autonomously or through external control by an operator. According to Prof. Yossifon, “developing the micro-robot’s ability to move autonomously was inspired by biological micro-swimmers, such as bacteria and sperm cells. This is an innovative area of research that is developing rapidly, with a wide variety of uses in fields such as medicine and the environment, as well as a research tool”.
WATCH: The Hybrid Micro-Robot
As a demonstration of the capabilities of the micro-robot the researchers used it to capture single blood and cancer cells and a single bacterium, and showed that it is able to distinguish between cells with different levels of viability, such as a healthy cell, a cell damaged by a drug, or a cell that is dying or dying in a natural 'suicide' process (such a distinction may be significant, for example, when developing anti-cancer drugs).
After identifying the desired cell, the micro-robot captured it and moved the cell to where it could be further analyzed. Another important innovation is the ability of the micro-robot to identify target cells that are not labeled - the micro-robot identifies the type of cell and its condition (such as degree of health) using a built-in sensing mechanism based on the cell's unique electrical properties.
Effective in Physiological Environments
"Our new development significantly advances the technology in two main aspects: hybrid propulsion and navigation by two different mechanisms - electric and magnetic," explains Prof. Yossifon. "In addition, the micro-robot has an improved ability to identify and capture a single cell, without the need for tagging, for local testing or retrieval and transport to an external instrument. This research was carried out on biological samples in the laboratory for in-vitro assays, but the intention is to develop in the future micro-robots that will also work inside the body - for example, as effective drug carriers that can be precisely guided to the target”.
"... the technology will support the following areas: medical diagnosis at the single cell level, introducing drugs or genes into cells, genetic editing, carrying drugs to their destination inside the body, cleaning the environment from polluting particles, drug development, and creating a 'laboratory on a particle' - a microscopic laboratory designed to carry out diagnostics in places accessible only to micro-particles." - Prof. Gilad Yossifon
The researchers explain that the hybrid propulsion mechanism of the micro-robot is of particular importance in physiological environments, such as found in liquid biopsies: "The micro-robots that have operated until now based on an electrical guiding mechanism were not effective in certain environments characterized by relatively high electrical conductivity, such as a physiological environment, where the electric drive is less effective. This is where the complementary magnetic mechanism come into play, which is very effective regardless of the electrical conductivity of the environment”.
Prof. Yossifon concludes: "In our research we developed an innovative micro-robot with important capabilities that significantly contribute to the field: hybrid propulsion and navigation through a combination of electric and magnetic fields, as well as the ability to identify, capture, and transport a single cell from place to place in a physiological environment. These capabilities are relevant for a wide variety of applications as well as for research. Among other things, the technology will support the following areas: medical diagnosis at the single cell level, introducing drugs or genes into cells, genetic editing, carrying drugs to their destination inside the body, cleaning the environment from polluting particles, drug development, and creating a 'laboratory on a particle' - a microscopic laboratory designed to carry out diagnostics in places accessible only to micro-particles.”
Research
Mar 23rd, 2023
Hyperbaric Treatment More Effective than Medicines for Fibromyalgia Caused by
Researchers say "results were dramatic" for patients who underwent hyperbaric oxygen therapy
- Medicine
Researchers from Tel Aviv University compared treatment with a dedicated protocol of hyperbaric oxygen therapy (HBOT) to the pharmacology (drugs) treatment available today for patients suffering from fibromyalgia, a chronic pain syndrome, caused by traumatic brain injury (TBI). Their findings showed that dedicated hyperbaric oxygen therapy is much more effective in reducing pain than the drug treatment and ended up healing two out of five of the participants in the study.
Chronic Pain Syndrome
The study was conducted by researchers from Tel Aviv University’s Sackler Faculty of Medicine, led by Prof. Shai Efrati, MD, from the Sagol Center for Hyperbaric Medicine and Research at the Shamir Medical Center, and Prof. Jacob Ablin, MD, from the Tel Aviv Sourasky Medical Center. The results of the study were published in the journal PLOS One.
"At the end of the treatment, two out of five patients in the hyperbaric treatment group showed such a significant improvement that they no longer met the criteria for fibromyalgia. In the drug treatment group, this did not happen to any patient." Prof. Shai Efrati
"Fibromyalgia is a chronic pain syndrome, from which between 2% - 8% of the population suffers," explains Prof. Shai Efrati. "Until 15-20 years ago, there were doctors who believed that it was a psychosomatic illness and recommended that patients with chronic pain seek mental health care. Today we know that it is a biological illness, which damages the brain's processing of the signals received from the body. When this processing is malfunctioning, you feel pain without any real damage in related locations."
"Fibromyalgia can be induced by variable triggers - from certain infections, as we have recently seen in post-COVID patients, through post-traumatic stress syndrome to head injuries. We wanted to test whether the new protocols of hyperbaric medicine can provide better results than pharmacological medicine, for patients in whom the fibromyalgia was induced by traumatic brain injury."
Prof. Shai Efrati
Dramatic Results
Hyperbaric medicine is a form of treatment in which the patients stay in special chambers where the pressure is higher than the atmospheric pressure at sea level, and where the patients breathe 100% oxygen. Hyperbaric medicine is considered safe, used in many places including Israel, and is already used to treat a long list of medical conditions.
In recent years, scientific evidence has been accumulating that certain, newly developed, dedicated hyperbaric treatment protocols can lead to the growth of new blood vessels and neurons in the brain.
"Overall, existing treatments are not good enough. [Fibromyalgia] is a chronic disease that significantly affects the quality of life, including young people, and hyperbaric medicine meets an acute need of these patients." Prof. Jacob Ablin
In their current study, the researchers from Tel Aviv University recruited 64 Israelis aged 18 and older who suffered from fibromyalgia as a result of a head injury, and randomly divided them into two groups: one group was exposed to 100% pure oxygen at a pressure of two atmospheres for 90 minutes (with fluctuations in oxygen during the treatment every 20 minutes), five days a week, for three months. The second group received the conventional pharmacological treatment (i.e., the drugs pregabalin, which is known under the trade name "Lyrica", and duloxetine, which is better known as "Cymbalta").
"The results were dramatic," says Prof. Efrati. "At the end of the treatment, two out of five patients in the hyperbaric treatment group showed such a significant improvement that they no longer met the criteria for fibromyalgia. In the drug treatment group, this did not happen to any patient. Furthermore, the average improvement in the pain threshold tests was 12 times better in the hyperbaric group compared to the medication group. And in terms of quality-of-life indicators, as reported by the patients, we saw significant improvements in all the indicators among the patients who received hyperbaric treatment."
Meets Acute Need
"Today's accepted treatment for fibromyalgia includes pharmacologic and non-pharmacologic components," says Prof. Ablin. "with respect to the pharmacologic approach, these drugs are not very effective and therefore the emphasis is on the non-pharmacological side, that is, on external correction of pain processing within the nervous system. Currently used recommendations includes aerobic activity, hydrotherapy, cognitive-behavioral therapy and movement-based therapies such as Tai Chi. In addition, quite a few patients request treatment with medical cannabis, and for some it helps."
"In the group that received hyperbaric treatment, you could see the repair of the brain tissue, while in the control group there was only an attempt to relieve the pain - without treating the damaged tissue - and of course the medication group experienced the side effects associated with drug treatment." Prof. Shai Efrati
"Overall, existing treatments are not good enough. [Fibromyalgia] is a chronic disease that significantly affects the quality of life, including young people, and hyperbaric medicine meets an acute need of these patients. Of course, these are preliminary studies, and we must follow and see what effect the medical protocol has on the patients after one, two and three years - and if it is necessary to maintain the positive results with further exposure to hyperbaric sessions."
Looking to Cure
According to Prof. Efrati, the importance of the research is in healing the damaged brain tissue - and not in treating its superficial symptoms: "In the group that received hyperbaric treatment, you could see the repair of the brain tissue, while in the control group there was only an attempt to relieve the pain - without treating the damaged tissue - and of course the medication group experienced the side effects associated with drug treatment. This is a difference in approach: to cure instead of just treating the symptoms."
"We assessed the improvement of the participants in the hyperbaric group more than a week after the last hyperbaric session. More follow-up studies are needed to see the duration of the beneficial effect of the treatment and if and for whom additional treatment will be needed. Our goal as doctors is not only to treat the symptoms but, to the extent possible, also to treat the source of the problem, thus improving the quality of life of fibromyalgia patients."
"It is important to emphasize that the dedicated hyperbaric oxygen treatment protocol found to be effective is only available in medical centers that have licensed hyperbaric chambers. Be careful of so-called 'private chambers', since these cannot provide the therapeutic protocol found to be effective, and they are not regulated or approved for medical use," cautions Prof. Efrati.
Research
Mar 20th, 2023
“Super Seaweed” Produces Natural Health Compounds and Medicine from the Sea
New Israeli technology could lead to anti-cancer, anti-diabetic, anti-inflammatory, anti-viral and antibiotic treatments
- Life Sciences
After developing an innovative technology that enables the growth of seaweed enriched with proteins and minerals such as zinc, iron, iodine, magnesium, and calcium for humans and animals, researchers from Tel Aviv University's School of Zoology at The George S. Wise Faculty of Life Sciences and the Israel Oceanographic and Limnological Research Institute (IOLR) have made a new advancement: They succeeded in significantly increasing the ability of seaweed to produce healthy natural substances, focusing on enhancing the production of bio-active compounds that offer medical benefits to humans, such as antioxidants - the concentration of which was doubled in the seaweed; natural sunscreens - its concentration tripled; and unique protective pigments of great medical value, the concentration of which increased by ten-fold.
The study was carried out with the innovative and sustainable approach of integrated aquaculture, which combines seaweed with fish cultivation, upgrading the seaweed while at the same time helping to purify the seawater and minimizing negative environmental impacts. According to the researchers, these findings may serve the pharmaceutical, cosmetics, food, and nutritional supplement industries.
Manufacturers of Valuable Compounds
The new development was led by Ph.D. student Doron Ashkenazi of Tel Aviv University and the Israel Oceanographic and Limnological Research Institute, under the guidance of Prof. Avigdor Abelson of Tel Aviv University’s School of Zoology and Prof. Alvaro Israel of the IOLR in Haifa, in collaboration with other leading researchers from Israel and around the world, including Guy Paz from IOLR; organic chemistry expert Dr. Shoshana Ben-Valid; Dr. Eitan Salomon from the National Center for Mariculture in Eilat; and Prof. Félix López Figueroa, Julia Vega, Nathalie Korbee, and Marta García-Sánchez from Malaga University in Spain. The article was published in the scientific journal Marine Drugs.
Ph.D. student Doron Ashkenazi (left) and Prof. Avigdor Abelson (right)
Doron Ashkenazi explains that “seaweed, also known as macroalgae, are marine plants that form the basis of the coastal marine ecosystem. The seaweed absorb carbon dioxide and release oxygen into the environment. They purify the water, provide food, habitat, and shelter for numerous species of fish and invertebrates. Not many know that seaweed also produce a wide variety of distinct bio-active compounds that are beneficial to humans. The seaweed living in the intertidal zone face extreme stress conditions, which include changes in salinity, temperature, desiccation [loss of moisture] conditions, changes in the availability of nutrients and high exposure to solar radiation, especially in the ultraviolet (UV) range."
"Not many know that seaweed also produce a wide variety of distinct bio-active compounds that are beneficial to humans." Doron Ashkenazi
To survive, the seaweed has developed a unique set of chemical defense mechanisms – natural chemicals that help them cope with these harsh environments. They are highly efficient natural factories that produce valuable substances that may offer significant benefits to humans.
In the current study, they sought to examine whether and how it is possible to increase and maximize the seaweed’ production of bio-active compounds, and secondary metabolites, that offer significant health benefits. These substances include antioxidants, protective pigments, and natural UV radiation filters.
A dedicated aquaculture system where the researchers grew three local species of algae
Future Looking Greener Than Ever?
To this end, the researchers developed an original and practical cultivation approach, whereby three local seaweed - Ulva, Gracilaria and Hypnea - were initially grown alongside fish effluents, and subsequently exposed to stressors including high irradiance, nutrient starvation, and high salt content.
They investigated how these changes affected the concentration of specific valuable biomaterials in the seaweed, to enhance their production. The results were impressive: antioxidant levels had doubled, seaweed natural sunscreen molecules tripled, and protective pigments were increased by ten-fold. “We developed optimal cultivation conditions and invented a new and clean way to increase the levels of healthy natural bio-active compounds in seaweed to an unprecedented level,” says Ashkenazi. “We in fact produced ‘super seaweed’ tailor designed to be utilized by the emerging health industries for food and health applications.”
“In the future, humanity will focus on creating science-based environmental solutions (...) technologies that promote recycling and the sound use of natural resources without overexploiting them.” Doron Ashkenazi
The researchers believe that in the future it will be possible to use their cultivation approach to elevate in seaweed additional natural materials with important medical properties, such as anti-cancer, anti-diabetic, anti-inflammatory, anti-viral, and ant-biotic substances.
They also emphasize that seaweed aquaculture is environmentally friendly, preserving the ecological balance, and reducing environmental risks by minimizing excessive amounts of pollutants caused by humans, reducing the emission of greenhouse gases, and lowering the carbon footprint. In this way, seaweed aquaculture can help cope with global environmental challenges such as pollution, habitat loss, and the climate crisis.
“In the future, humanity will focus on creating science-based environmental solutions, like the one we offer in this study - technologies that promote recycling and the sound use of natural resources without overexploiting them. Our study demonstrates how we can enjoy nature without harming it,” concludes Ashkenazi.
Research
Mar 14th, 2023
Do We Need 'Junk DNA'?
Researchers offer possible reason why neutral sequences in the genome of living creatures continue to exist millions of years later
- Life Sciences
A new model developed at Tel Aviv University offers a possible solution to the scientific question of why neutral sequences, sometimes referred to as "junk DNA", are not eliminated from the genome of living creatures in nature and continue to exist within it even millions of years later.
According to the researchers, the explanation is that junk DNA is often located in the vicinity of functional DNA. Deletion events around the borders between junk and functional DNA are likely to damage the functional regions and so evolution rejects them. The model contributes to the understanding of the huge variety of genome sizes observed in nature.
Border Induced Selection
The model describes a phenomenon which the team of researchers refer to as "border induced selection," and was developed under the leadership of PhD student Gil Loewenthal in the laboratory of Prof. Tal Pupko from the Shmunis School of Biomedicine and Cancer Research at the The George S. Wise Faculty of Life Sciences and in collaboration with Prof. Itay Mayrose, also from TAU's Faculty of Life Sciences. The study was published in the journal Open Biology.
Throughout evolution, the size of the genome in living creatures in nature changes. For example, some salamander species have a genome ten times larger than the human genome. "The rate of deletions and short insertions, dubbed 'indels', is usually measured by examining pseudogenes," explains Prof. Pupko. "Pseudogenes are genes that have lost their function, and in which there are frequent mutations, including deletions and insertions of DNA segments."
In previous studies that characterized the indels, it was found that the rate of deletions is greater than the rate of additions in a variety of creatures including bacteria, insects, and even mammals such as humans.
Prof. Tal Pupko
Reverse Bias for Short Segments
The question the researchers sought to answer is how the genomes are not deleted when the probability of DNA deletion events is significantly greater than DNA addition events: "We have provided a different view to the dynamics of evolution at the DNA level," says Loewenthal. "When measuring the rate of indels there will be more deletions, but the measurements are carried out in pseudogenes which are quite long sequences. We assert that in shorter neutral segments, deletions would likely remove adjacent functional segments which are essential for the functioning of the organism, and they will therefore be rejected [through 'border-induced selection']. Accordingly, we assert that when the segment is short, there will be a reverse bias – there will be more insertions than deletions - and therefore short neutral segments are usually retained."
"In our study, we simulated the dynamics of indels, while taking into account the effect of 'border-induced selection,' and compared the simulation results to the distribution of human intron lengths (introns are DNA segments in the middle of a protein-coding gene, which themselves do not code for a protein). A good match was obtained between the results of the simulations and the distribution of lengths observed in nature, and we were able to explain peculiar phenomena in the length distribution of introns, such as the large variation in intron lengths, as well as the complex shape of the distribution which does not look like a standard bell curve."
Research
Mar 13th, 2023
World's First mRNA Vaccine Against Deadly Bacteria
Israeli researchers develop vaccine that is 100% effective against bacteria lethal to humans
- Life Sciences
For the first time worldwide, a team of researchers from Tel Aviv University and the Israel Institute for Biological Research have developed an mRNA-based vaccine that is 100% effective against a type of bacteria that is lethal to humans. The study, conducted in a lab model, demonstrated that all treated models were fully protected against the bacteria. The researchers believe their new technology can enable rapid development of effective vaccines for bacterial diseases, including diseases caused by antibiotic-resistant bacteria, for example in case of a new fast-spreading pandemic.
"In our study we proved that it is, in fact, possible to develop mRNA vaccines that are 100% effective against deadly bacteria." Dr. Edo Kon
Quickly Developed
The study was led by Tel Aviv University’s Dr. Edo Kon and Prof. Dan Peer, VP for R&D and Head of the Laboratory of Precision Nano-Medicine at The Shmunis School of Biomedicine and Cancer Research at The George S. Wise Faculty of Life Sciences, in collaboration with researchers from the Israel Institute for Biological Research: Dr. Yinon Levy, Uri Elia, Dr. Emanuelle Mamroud, and Dr. Ofer Cohen. The results of the study were published in the journal Science Advances.
"So far, mRNA vaccines, such as the COVID-19 vaccines which are familiar to all of us, were assumed to be effective against viruses but not against bacteria," explains Dr. Edo Kon. "The great advantage of these vaccines, in addition to their effectiveness, is the ability to develop them very quickly: once the genetic sequence of the virus SARS-CoV2 (COVID-19) was published, it took only 63 days to begin the first clinical trial. However, until now scientists believed that mRNA vaccines against bacteria were biologically unattainable. In our study we proved that it is, in fact, possible to develop mRNA vaccines that are 100% effective against deadly bacteria."
Running RNA gel
Combining Breakthrough Strategies
The researchers explain that viruses depend on external (host) cells for their reproduction. Inserting its own mRNA molecule into a human cell, a virus uses our cells as a factory for producing viral proteins based on its own genetic material, namely replicates of itself.
In mRNA vaccines this same molecule is synthesized in a lab, then wrapped in lipid nanoparticles resembling the membrane of human cells. When the vaccine is injected into our body, the lipids stick to our cells, and consequently the cells produce viral proteins. The immune system, becoming familiar with these proteins, learns how to protect our body in the event of exposure to the real virus.
Since viruses produce their proteins inside our cells, the proteins translated from the viral genetic sequence resemble those translated from the lab-synthesized mRNA.
"If tomorrow we face some kind of bacterial pandemic, our study will provide a pathway for quickly developing safe and effective mRNA vaccines." Prof. Dan Peer
Bacteria, however, are a whole different story: They don't need our cells to produce their own proteins. And since the evolutions of humans and bacteria are quite different from one another, proteins produced in bacteria can be different from those produced in human cells, even when based on the same genetic sequence.
"Researchers have tried to synthesize bacterial proteins in human cells, but exposure to these proteins resulted in low antibodies and a general lack of protective immune effect, in our bodies," explains Dr. Kon. "This is because, even though the proteins produced in the bacteria are essentially identical to those synthesized in the lab, being based on the same 'manufacturing instructions', those produced in human cells undergo significant changes, like the addition of sugars, when secreted from the human cell."
"To address this problem, we developed methods to secrete the bacterial proteins while bypassing the classical secretion pathways, which are problematic for this application. The result was a significant immune response, with the immune system identifying the proteins in the vaccine as immunogenic bacterial proteins. To enhance the bacterial protein's stability and make sure that it does not disintegrate too quickly inside the body, we buttressed it with a section of human protein. By combining the two breakthrough strategies we obtained a full immune response."
WATCH: Prof. Dan Peer and Dr. Edo Kon on the world's first mRNA vaccine for deadly bacteria
Solution to Antibiotic-resistant Bacteria?
"There are many pathogenic bacteria for which we have no vaccines," adds Prof. Peer. "Moreover, due to excessive use of antibiotics over the last few decades, many bacteria have developed resistance to antibiotics, reducing the effectiveness of these important drugs. Consequently, antibiotic-resistant bacteria already pose a real threat to human health worldwide. Developing a new type of vaccine may provide an answer to this global problem."
"In our study, we tested our novel mRNA vaccine in animals infected with a deadly bacterium. Within a week, all unvaccinated animals died, while those vaccinated with our vaccine remained alive and well. Moreover, in one of our vaccination methods, one dose provided full protection just two weeks after it was administered. The ability to provide full protection with just one dose is crucial for protection against future outbreaks of fast-spreading bacterial pandemics. It is important to note that the COVID-19 vaccine was developed so quickly because it relied on years of research on mRNA vaccines for similar viruses. If tomorrow we face some kind of bacterial pandemic, our study will provide a pathway for quickly developing safe and effective mRNA vaccines."
The study was funded by research grants from the European Union (ERC; EXPERT) and the Shmunis Family (for Prof. Peer).
Research
Mar 2nd, 2023
New Snake Family Identified
As far as researchers are aware the Micrelapidae family includes only three species, one in Israel and neighboring countries, and two in East Africa.
- Life Sciences
An extensive international study identified a new family of snakes: Micrelapidae. According to the researchers, Micrelaps, small snakes usually with black and yellow rings, diverged from the rest of the evolutionary tree of snakes about 50 million years ago. As far as they know, the new family includes only three species, one in Israel and neighboring countries, and two in East Africa.
"Today we tend to assume that most large groups of animals, such as families, are already known to science, but sometimes we still encounter surprises, and this is what happened with Micrelapid snakes." Prof. Shai Meiri
Exploring the Micrelaps' Family Tree
The study was conducted by Prof. Shai Meiri of TAU's School of Zoology, The George S. Wise Faculty of Life Sciences, and of The Steinhardt Museum of Natural History Museum, as well as researchers from Finland, the USA, Belgium, Madagascar, Hong Kong, and Israel. The paper was published in Molecular Phylogenetics and Evolution.
"Today we tend to assume that most large groups of animals, such as families, are already known to science, but sometimes we still encounter surprises, and this is what happened with Micrelapid snakes," explains Prof Meiri.
"For years, they were considered members of the largest snake family, the Colubridae, but multiple DNA tests conducted over the last decade contradicted this classification. Since then, snake researchers around the world have tried to discover which family these snakes belong to – to no avail. In this study we joined the scientific effort."
The researchers used micro-CT technology – high-resolution magnetic imaging, to examine the snake's morphology, focusing specifically on the skull. In addition, they applied methods of deep genomic sequencing – examining about 4,500 ultra-conserved elements, namely regions in the genome that take millions of years to exhibit any change.
Prof. Meiri explains that "in addition to the DNA of Micrelaps, we sampled DNA from various snake groups to which they might have belonged. This way, we discovered some unique genomic elements in Micrelaps, which were not found in any of the other groups."
Prof. Shai Meiri
"Even through these snakes have been known for decades, they were mistakenly included in other families for many years." Prof. Shai Meiri
Family Relocation
According to the researchers their findings indicate that Micrelaps diverged from the rest of the evolutionary tree of snakes about 50 million years ago. Since then, these snakes have evolved independently, as a distinct and separate family.
Apparently, this is a very small family, including only three species: two in Kenya and Tanzania in East Africa, and one in Israel and nearby regions (northern Jordan and the Palestinian Authority, southern Syria, and southern Lebanon). The geographic dispersion suggests that these snakes probably originated in Africa, and then, at some point in their history, some of them made their way north through the Great Rift Valley.
"In this study we were able to associate a new snake family – the Micrelapidae. Even through these snakes have been known for decades, they were mistakenly included in other families for many years. Since most animals have already been classified into well-defined families, such a discovery of a new family is quite a rare occurrence in modern science," concludes Prof. Meiri.
