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DUKAS_177858624_FER
Lab made foie gras for guilt free eating
Ferrari Press Agency
Foie Gras 1
Ref 16329
20/11/2024
See Ferrari text
Picture MUST credit: Vow
A High tech food company is hoping to make one of the worlds most controversial dishes a guilt-free meal.
The Australian firm, called Vow, has created a lab-made foie gras that not only takes the cruelty out of producing it, but also aims to make a distinctively tastier version of the delicacy.
It calls its creation “Forged Gras.”
Foie gras has its origins in Egypt circa 2500 BCE, and is still popular in French cuisine today.
It’s a high end delicacy food made from the enlarged liver of a duck or goose that has been force fed a high-fat diet.
This is said to yield a rich, buttery flavour typically served as a topping for bread, made into a pâté, or browned in a skillet and sliced.
Some countries have banned its production due to concerns over its production technique including Germany, Czech Republic, the UK, Italy, Poland and Switzerland.
India is the only country to have imposed an import ban as well which it did in 2014.
Vow is using cultured Japanese quail cells, combined with a plant-based fat mix, fava bean protein, and flavourings to make its version.
OPS: Forged Gras with poached pears
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_177858623_FER
Lab made foie gras for guilt free eating
Ferrari Press Agency
Foie Gras 1
Ref 16329
20/11/2024
See Ferrari text
Picture MUST credit: Vow
A High tech food company is hoping to make one of the worlds most controversial dishes a guilt-free meal.
The Australian firm, called Vow, has created a lab-made foie gras that not only takes the cruelty out of producing it, but also aims to make a distinctively tastier version of the delicacy.
It calls its creation “Forged Gras.”
Foie gras has its origins in Egypt circa 2500 BCE, and is still popular in French cuisine today.
It’s a high end delicacy food made from the enlarged liver of a duck or goose that has been force fed a high-fat diet.
This is said to yield a rich, buttery flavour typically served as a topping for bread, made into a pâté, or browned in a skillet and sliced.
Some countries have banned its production due to concerns over its production technique including Germany, Czech Republic, the UK, Italy, Poland and Switzerland.
India is the only country to have imposed an import ban as well which it did in 2014.
Vow is using cultured Japanese quail cells, combined with a plant-based fat mix, fava bean protein, and flavourings to make its version.
OPS: Forged Gras with blueberry waffles
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_177858618_FER
Lab made foie gras for guilt free eating
Ferrari Press Agency
Foie Gras 1
Ref 16329
20/11/2024
See Ferrari text
Picture MUST credit: Vow
A High tech food company is hoping to make one of the worlds most controversial dishes a guilt-free meal.
The Australian firm, called Vow, has created a lab-made foie gras that not only takes the cruelty out of producing it, but also aims to make a distinctively tastier version of the delicacy.
It calls its creation “Forged Gras.”
Foie gras has its origins in Egypt circa 2500 BCE, and is still popular in French cuisine today.
It’s a high end delicacy food made from the enlarged liver of a duck or goose that has been force fed a high-fat diet.
This is said to yield a rich, buttery flavour typically served as a topping for bread, made into a pâté, or browned in a skillet and sliced.
Some countries have banned its production due to concerns over its production technique including Germany, Czech Republic, the UK, Italy, Poland and Switzerland.
India is the only country to have imposed an import ban as well which it did in 2014.
Vow is using cultured Japanese quail cells, combined with a plant-based fat mix, fava bean protein, and flavourings to make its version.
OPS: Forged Gras with blueberry waffles
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_177858617_FER
Lab made foie gras for guilt free eating
Ferrari Press Agency
Foie Gras 1
Ref 16329
20/11/2024
See Ferrari text
Picture MUST credit: Vow
A High tech food company is hoping to make one of the worlds most controversial dishes a guilt-free meal.
The Australian firm, called Vow, has created a lab-made foie gras that not only takes the cruelty out of producing it, but also aims to make a distinctively tastier version of the delicacy.
It calls its creation “Forged Gras.”
Foie gras has its origins in Egypt circa 2500 BCE, and is still popular in French cuisine today.
It’s a high end delicacy food made from the enlarged liver of a duck or goose that has been force fed a high-fat diet.
This is said to yield a rich, buttery flavour typically served as a topping for bread, made into a pâté, or browned in a skillet and sliced.
Some countries have banned its production due to concerns over its production technique including Germany, Czech Republic, the UK, Italy, Poland and Switzerland.
India is the only country to have imposed an import ban as well which it did in 2014.
Vow is using cultured Japanese quail cells, combined with a plant-based fat mix, fava bean protein, and flavourings to make its version.
OPS: Forged Gras with poached pears
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_177858613_FER
Lab made foie gras for guilt free eating
Ferrari Press Agency
Foie Gras 1
Ref 16329
20/11/2024
See Ferrari text
Picture MUST credit: Vow
A High tech food company is hoping to make one of the worlds most controversial dishes a guilt-free meal.
The Australian firm, called Vow, has created a lab-made foie gras that not only takes the cruelty out of producing it, but also aims to make a distinctively tastier version of the delicacy.
It calls its creation “Forged Gras.”
Foie gras has its origins in Egypt circa 2500 BCE, and is still popular in French cuisine today.
It’s a high end delicacy food made from the enlarged liver of a duck or goose that has been force fed a high-fat diet.
This is said to yield a rich, buttery flavour typically served as a topping for bread, made into a pâté, or browned in a skillet and sliced.
Some countries have banned its production due to concerns over its production technique including Germany, Czech Republic, the UK, Italy, Poland and Switzerland.
India is the only country to have imposed an import ban as well which it did in 2014.
Vow is using cultured Japanese quail cells, combined with a plant-based fat mix, fava bean protein, and flavourings to make its version.
OPS: Forged Gras with asparagus and frites
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_177858606_FER
Lab made foie gras for guilt free eating
Ferrari Press Agency
Foie Gras 1
Ref 16329
20/11/2024
See Ferrari text
Picture MUST credit: Vow
A High tech food company is hoping to make one of the worlds most controversial dishes a guilt-free meal.
The Australian firm, called Vow, has created a lab-made foie gras that not only takes the cruelty out of producing it, but also aims to make a distinctively tastier version of the delicacy.
It calls its creation “Forged Gras.”
Foie gras has its origins in Egypt circa 2500 BCE, and is still popular in French cuisine today.
It’s a high end delicacy food made from the enlarged liver of a duck or goose that has been force fed a high-fat diet.
This is said to yield a rich, buttery flavour typically served as a topping for bread, made into a pâté, or browned in a skillet and sliced.
Some countries have banned its production due to concerns over its production technique including Germany, Czech Republic, the UK, Italy, Poland and Switzerland.
India is the only country to have imposed an import ban as well which it did in 2014.
Vow is using cultured Japanese quail cells, combined with a plant-based fat mix, fava bean protein, and flavourings to make its version.
OPS: Forged Gras sushi
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_177015278_FER
Hybrid plant-animal cells could one day help grow organs
Ferrari Press Agency
Cells 1
Ref 16270
31/10/2024
See Ferrari text
Picture MUST credit: R. Aoki, Y. Inui, Y Okabe et al. 2024/ Proceedings of the Japan Academy, Series B
Scientists say they have created hybrid plant-animal cells.
The breakthrough could have major benefits for growing organs and tissues for transplant, or lab-grown meat.
The new hybrid means animal cells can gain energy from sunlight like plants.
Animal and plant cells have different energy-producing structures inside them.
Animals have mitochondria which convert chemical energy from food into a form that our cells can use.
Plants and algae use chloroplasts to perform photosynthesis to generate energy from sunlight for their cells.
In a new study led by the University of Tokyo in Japan, a team inserted chloroplasts from reg algae into animal cells harvested from hamsters
They discovered they continued to perform photosynthesis functions for at least two days.
OPS: Chloroplasts give plants and algae their green hue, and enable them to convert sunlight into food and oxygen, via photosynthesis. The chloroplasts (right) in this study were taken from a type of tiny red algae called Cyanidioschyzon merolae (left)
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_177015277_FER
Hybrid plant-animal cells could one day help grow organs
Ferrari Press Agency
Cells 1
Ref 16270
31/10/2024
See Ferrari text
Picture MUST credit: R. Aoki, Y. Inui, Y Okabe et al. 2024/ Proceedings of the Japan Academy, Series B
Scientists say they have created hybrid plant-animal cells.
The breakthrough could have major benefits for growing organs and tissues for transplant, or lab-grown meat.
The new hybrid means animal cells can gain energy from sunlight like plants.
Animal and plant cells have different energy-producing structures inside them.
Animals have mitochondria which convert chemical energy from food into a form that our cells can use.
Plants and algae use chloroplasts to perform photosynthesis to generate energy from sunlight for their cells.
In a new study led by the University of Tokyo in Japan, a team inserted chloroplasts from reg algae into animal cells harvested from hamsters
They discovered they continued to perform photosynthesis functions for at least two days.
OPS: This fluorescence image shows chloroplasts (magenta coloured) successfully incorporated into the hamster cells, with other features of the animal cell also highlighted (nuclei in light blue and organelles in yellow-green).
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_171650298_FER
Developing human-like skin for robots
Ferrari Press Agency
Faces 1
Ref 15959
26/06/2024
See Ferrari pictures
Pictures must credit: Takeuchi et al / University of Tokyo
Robots are about to get a realistic facelift — using laboratory grown human skin cells.
The team behind it believe it could lead to better human-robot interactions.
And there could also be a spin-off for plastic surgery.
A team at Japan’s University of The Tokyo grew a mix of human skin cells on a collagen base, before placing it on a 3D-printed mould.
The skin boasted tiny built-in anchors, inspired by human ligaments, that keep it anchored to the robot surface as well as making it flexible and preventing tears as a robot moves.
Tokyo professor Shoji Takeuchi said while the process has captured the basic look of human skin, there is more work to be done.
Future iterations might include wrinkles, a thicker layer of skin, and even sweat glands and nerves.
The skin may even be able to heal itself like a real human epidermis.
The scientists are also working on sophisticated artificial muscles known as actuators, allowing for more lifelike expressions.
OPS:The new method can work on complex, curved, and even moving surfaces.
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_171650291_FER
Developing human-like skin for robots
Ferrari Press Agency
Faces 1
Ref 15959
26/06/2024
See Ferrari pictures
Pictures must credit: Takeuchi et al / University of Tokyo
Robots are about to get a realistic facelift — using laboratory grown human skin cells.
The team behind it believe it could lead to better human-robot interactions.
And there could also be a spin-off for plastic surgery.
A team at Japan’s University of The Tokyo grew a mix of human skin cells on a collagen base, before placing it on a 3D-printed mould.
The skin boasted tiny built-in anchors, inspired by human ligaments, that keep it anchored to the robot surface as well as making it flexible and preventing tears as a robot moves.
Tokyo professor Shoji Takeuchi said while the process has captured the basic look of human skin, there is more work to be done.
Future iterations might include wrinkles, a thicker layer of skin, and even sweat glands and nerves.
The skin may even be able to heal itself like a real human epidermis.
The scientists are also working on sophisticated artificial muscles known as actuators, allowing for more lifelike expressions.
OPS:The new anchoring method allows flexible skin tissue to conform to any shape it’s attached to. In this case, a relatively flat robotic face (left) is made to smile (right) . The skin deforms without constraining the robot, returning to its original shape afterwards.
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_171650288_FER
Developing human-like skin for robots
Ferrari Press Agency
Faces 1
Ref 15959
26/06/2024
See Ferrari pictures
Pictures must credit: Takeuchi et al / University of Tokyo
Robots are about to get a realistic facelift — using laboratory grown human skin cells.
The team behind it believe it could lead to better human-robot interactions.
And there could also be a spin-off for plastic surgery.
A team at Japan’s University of The Tokyo grew a mix of human skin cells on a collagen base, before placing it on a 3D-printed mould.
The skin boasted tiny built-in anchors, inspired by human ligaments, that keep it anchored to the robot surface as well as making it flexible and preventing tears as a robot moves.
Tokyo professor Shoji Takeuchi said while the process has captured the basic look of human skin, there is more work to be done.
Future iterations might include wrinkles, a thicker layer of skin, and even sweat glands and nerves.
The skin may even be able to heal itself like a real human epidermis.
The scientists are also working on sophisticated artificial muscles known as actuators, allowing for more lifelike expressions.
OPS:The new method can work on complex, curved, and even moving surfaces.
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_161485626_FER
New material for fixing severed nerve cells
Ferrari Press Agency
Nerve 1
Ref 15174
11/10/2023
See Ferrari text
Pictures MUST credit: Joshua Chen/ Rice University
A tiny device that can mend broken nerves could help return feeling back to paralysed limbs.
It is made of a magneto-electric material, that turns magnetic fields into electric fields .
It has long been thought these electric fields can stimulate neural tissue in a minimally invasive way and help treat neurological disorders or nerve damage.
However neurons, the nerve cells that send messages all around the body, have a hard time responding to the shape and frequency of the electric signal resulting from this conversion.
But now a team at the USA’s Rice University in Houston. Texas, has designed the first magneto-electric material that solves and does the magnetic-to-electric conversion 120 times faster than similar materials.
The team was led by neuro-engineer Prof Jacob Robinson and sowed the material can be used to precisely stimulate neurons remotely, bridging the gap in a broken sciatic nerve in a rat.
The material’s qualities and performance could have a profound impact on neuro stimulation treatments, making for significantly less invasive procedures.
Instead of implanting a neuro stimulation device, tiny amounts of the material could simply be injected at the desired site.
OPS: Schematic of neural response for linear magnetic-to-electric conversion (top and middle) versus nonlinear (bottom third).
Picture supplied by Ferrari
(FOTO: DUKAS/FERRARI PRESS) -
DUKAS_161485625_FER
New material for fixing severed nerve cells
Ferrari Press Agency
Nerve 1
Ref 15174
11/10/2023
See Ferrari text
Pictures MUST credit: The Robinson Lab/ Rice University
A tiny device that can mend broken nerves could help return feeling back to paralysed limbs.
It is made of a magneto-electric material, that turns magnetic fields into electric fields .
It has long been thought these electric fields can stimulate neural tissue in a minimally invasive way and help treat neurological disorders or nerve damage.
However neurons, the nerve cells that send messages all around the body, have a hard time responding to the shape and frequency of the electric signal resulting from this conversion.
But now a team at the USA’s Rice University in Houston. Texas, has designed the first magneto-electric material that solves and does the magnetic-to-electric conversion 120 times faster than similar materials.
The team was led by neuro-engineer Prof Jacob Robinson and sowed the material can be used to precisely stimulate neurons remotely, bridging the gap in a broken sciatic nerve in a rat.
The material’s qualities and performance could have a profound impact on neuro stimulation treatments, making for significantly less invasive procedures.
Instead of implanting a neuro stimulation device, tiny amounts of the material could simply be injected at the desired site.
OPS: Prototype magneto electric meta material shown for scale with a US cent
Picture supplied by Ferrari
(FOTO: DUKAS/FERRARI PRESS) -
DUKAS_161150042_FER
New clue to embryo IVF fialure
Ferrari Press Agency
IVF 1
Ref 15143
02/10/2023
See Ferrari text
Pictures MUST credit: Christian Ottolini / Johns Hopkins University
A clue to the cause of the high failure rate in IVF fertility treatment has been uncovered by scientists.
They genetically tested nearly 1,000 embryos and found nearly half suffered genetic mishaps in early development.
That suggests more IVF babies could come to term with changes in the fertility treatment process.
It also sheds new light on the still largely mysterious earliest stages of pregnancy through natural means.
The research compared IVF embryos that failed to develop within a few days of fertilisation to those that survived and looked for genetic differences.
Some embryos start growing properly while the genetic material is pre-loaded into the egg control cell division, only to falter and stall when the embryo's genes take over.
Human cells typically receive 46 chromosomes, 23 from each parent.
The team discovered non-viable embryos started with the 46-chromosome set, but then passed down incorrect numbers of chromosomes as cells divided.
A common type of abnormal cell division is where an embryo cleaves directly from a single cell into three rather than two cells.
The new research shows such abnormal division is strongly associated with chromosome abnormalities and embryo failure
OPS:A common type of abnormal cell division where an IVF embryo cleaves directly from a single cell into three rather than two cells. The new research shows such abnormal division is strongly associated with chromosome abnormalities and embryo arrest. Here the single cell splits into three instead of two.
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_161150041_FER
New clue to embryo IVF fialure
Ferrari Press Agency
IVF 1
Ref 15143
02/10/2023
See Ferrari text
Pictures MUST credit: Christian Ottolini / Johns Hopkins University
A clue to the cause of the high failure rate in IVF fertility treatment has been uncovered by scientists.
They genetically tested nearly 1,000 embryos and found nearly half suffered genetic mishaps in early development.
That suggests more IVF babies could come to term with changes in the fertility treatment process.
It also sheds new light on the still largely mysterious earliest stages of pregnancy through natural means.
The research compared IVF embryos that failed to develop within a few days of fertilisation to those that survived and looked for genetic differences.
Some embryos start growing properly while the genetic material is pre-loaded into the egg control cell division, only to falter and stall when the embryo's genes take over.
Human cells typically receive 46 chromosomes, 23 from each parent.
The team discovered non-viable embryos started with the 46-chromosome set, but then passed down incorrect numbers of chromosomes as cells divided.
A common type of abnormal cell division is where an embryo cleaves directly from a single cell into three rather than two cells.
The new research shows such abnormal division is strongly associated with chromosome abnormalities and embryo failure
OPS:A common type of abnormal cell division where an IVF embryo cleaves directly from a single cell into three rather than two cells. The new research shows such abnormal division is strongly associated with chromosome abnormalities and embryo arrest. Here the single cell splits into three instead of two.
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_161150039_FER
New clue to embryo IVF fialure
Ferrari Press Agency
IVF 1
Ref 15143
02/10/2023
See Ferrari text
Pictures MUST credit: Christian Ottolini / Johns Hopkins University
A clue to the cause of the high failure rate in IVF fertility treatment has been uncovered by scientists.
They genetically tested nearly 1,000 embryos and found nearly half suffered genetic mishaps in early development.
That suggests more IVF babies could come to term with changes in the fertility treatment process.
It also sheds new light on the still largely mysterious earliest stages of pregnancy through natural means.
The research compared IVF embryos that failed to develop within a few days of fertilisation to those that survived and looked for genetic differences.
Some embryos start growing properly while the genetic material is pre-loaded into the egg control cell division, only to falter and stall when the embryo's genes take over.
Human cells typically receive 46 chromosomes, 23 from each parent.
The team discovered non-viable embryos started with the 46-chromosome set, but then passed down incorrect numbers of chromosomes as cells divided.
A common type of abnormal cell division is where an embryo cleaves directly from a single cell into three rather than two cells.
The new research shows such abnormal division is strongly associated with chromosome abnormalities and embryo failure
OPS:A common type of abnormal cell division where an IVF embryo cleaves directly from a single cell into three rather than two cells. The new research shows such abnormal division is strongly associated with chromosome abnormalities and embryo arrest. Here the single cell splits into three instead of two.
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_161150037_FER
New clue to embryo IVF fialure
Ferrari Press Agency
IVF 1
Ref 15143
02/10/2023
See Ferrari text
Pictures MUST credit: Christian Ottolini / Johns Hopkins University
A clue to the cause of the high failure rate in IVF fertility treatment has been uncovered by scientists.
They genetically tested nearly 1,000 embryos and found nearly half suffered genetic mishaps in early development.
That suggests more IVF babies could come to term with changes in the fertility treatment process.
It also sheds new light on the still largely mysterious earliest stages of pregnancy through natural means.
The research compared IVF embryos that failed to develop within a few days of fertilisation to those that survived and looked for genetic differences.
Some embryos start growing properly while the genetic material is pre-loaded into the egg control cell division, only to falter and stall when the embryo's genes take over.
Human cells typically receive 46 chromosomes, 23 from each parent.
The team discovered non-viable embryos started with the 46-chromosome set, but then passed down incorrect numbers of chromosomes as cells divided.
A common type of abnormal cell division is where an embryo cleaves directly from a single cell into three rather than two cells.
The new research shows such abnormal division is strongly associated with chromosome abnormalities and embryo failure
OPS:A common type of abnormal cell division where an IVF embryo cleaves directly from a single cell into three rather than two cells. The new research shows such abnormal division is strongly associated with chromosome abnormalities and embryo arrest. Here is the single cell before changing.
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_156576526_FER
Scientists engineer a human like tissue in war against disease carrying mosquitoes.
Ferrari Press Agency
Skin 1
Ref 14860
12/06/2023
See Ferrari pictures
Pictures must credit: University of Central Florida
Scientists have engineered tissue with human cells that mosquitoes love to bite and feed upon—with the goal of helping fight deadly diseases they transit.
Testing showed the insects readily bit and fed on the material.
Scientists hope to use this new platform to study how pathogens carried by mosquitoes impact and infect human cells and tissues.
Currently researchers rely largely upon animal models and cells cultured on flat dishes for such investigations.
The team behind the new system say it holds great promise for breeding mosquito species as colonies in the laboratory which has proven difficult in the past.
To make the tissue, they lined 3D capillary gel biomaterials with human cells to create engineered tissue and then infused it with blood.
A biomaterial is a substance that has been engineered to interact with human biological systems.
Mosquitoes have often been called the world's deadliest animal causing more than 700,000 deaths worldwide each year from illnesses passing on things such as malaria, dengue fever and Zika virus.
Even for those who survive these illnesses, many are left suffering from organ failure, seizures and serious neurological impacts.
The tissue was engineered at the USA’s University of Central Florida.
OPS: Graphic showing the make-up of the tissue which has been dubbed BITE -- Biological Interfacial Tissue-Engineered System
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_156576525_FER
Scientists engineer a human like tissue in war against disease carrying mosquitoes.
Ferrari Press Agency
Skin 1
Ref 14860
12/06/2023
See Ferrari pictures
Pictures must credit: University of Central Florida
Scientists have engineered tissue with human cells that mosquitoes love to bite and feed upon—with the goal of helping fight deadly diseases they transit.
Testing showed the insects readily bit and feed on the material.
Scientists hope to use this new platform to study how pathogens carried by mosquitoes impact and infect human cells and tissues.
Currently researchers rely largely upon animal models and cells cultured on flat dishes for such investigations.
The team behind the new system say it holds great promise for breeding mosquito species as colonies in the laboratory which has proven difficult in the past.
To make the tissue, they lined 3D capillary gel biomaterials with human cells to create engineered tissue and then infused it with blood.
A biomaterial is a substance that has been engineered to interact with human biological systems.
Mosquitoes have often been called the world's deadliest animal causing more than 700,000 deaths worldwide each year from illnesses passing on things such as malaria, dengue fever and Zika virus.
Even for those who survive these illnesses, many are left suffering from organ failure, seizures and serious neurological impacts.
The tissue was engineered at the USA’s University of Central Florida.
OPS: Mosquitoes feed on blood from the the lab created tissue
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_156576519_FER
Scientists engineer a human like tissue in war against disease carrying mosquitoes.
Ferrari Press Agency
Skin 1
Ref 14860
12/06/2023
See Ferrari pictures
Pictures must credit: University of Central Florida
Scientists have engineered tissue with human cells that mosquitoes love to bite and feed upon—with the goal of helping fight deadly diseases they transit.
Testing showed the insects readily bit and feed on the material.
Scientists hope to use this new platform to study how pathogens carried by mosquitoes impact and infect human cells and tissues.
Currently researchers rely largely upon animal models and cells cultured on flat dishes for such investigations.
The team behind the new system say it holds great promise for breeding mosquito species as colonies in the laboratory which has proven difficult in the past.
To make the tissue, they lined 3D capillary gel biomaterials with human cells to create engineered tissue and then infused it with blood.
A biomaterial is a substance that has been engineered to interact with human biological systems.
Mosquitoes have often been called the world's deadliest animal causing more than 700,000 deaths worldwide each year from illnesses passing on things such as malaria, dengue fever and Zika virus.
Even for those who survive these illnesses, many are left suffering from organ failure, seizures and serious neurological impacts.
The tissue was engineered at the USA’s University of Central Florida.
OPS: Mosquitoes feed on blood from the the lab created tissue
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_156576518_FER
Scientists engineer a human like tissue in war against disease carrying mosquitoes.
Ferrari Press Agency
Skin 1
Ref 14860
12/06/2023
See Ferrari pictures
Pictures must credit: University of Central Florida
Scientists have engineered tissue with human cells that mosquitoes love to bite and feed upon—with the goal of helping fight deadly diseases they transit.
Testing showed the insects readily bit and feed on the material.
Scientists hope to use this new platform to study how pathogens carried by mosquitoes impact and infect human cells and tissues.
Currently researchers rely largely upon animal models and cells cultured on flat dishes for such investigations.
The team behind the new system say it holds great promise for breeding mosquito species as colonies in the laboratory which has proven difficult in the past.
To make the tissue, they lined 3D capillary gel biomaterials with human cells to create engineered tissue and then infused it with blood.
A biomaterial is a substance that has been engineered to interact with human biological systems.
Mosquitoes have often been called the world's deadliest animal causing more than 700,000 deaths worldwide each year from illnesses passing on things such as malaria, dengue fever and Zika virus.
Even for those who survive these illnesses, many are left suffering from organ failure, seizures and serious neurological impacts.
The tissue was engineered at the USA’s University of Central Florida.
OPS: Mosquitoes feed on blood from the the lab created tissue
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189196_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189195_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189193_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189192_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189191_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189190_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189188_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189186_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189182_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189177_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189176_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189173_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUKAS_154189172_FER
3D Lego-built bioprinter that can print skin
Ferrari Press Agency
Lego printer 1
Ref 14737
28/04/2023
See Ferrari text
Pictures must credit: Cardiff University
A 3D printer constructed entirely from Lego bricks has been built by scientists to print human skin.
The team behind the device in the hope that their work can enable easy uptake, modification and improvement by other laboratories.
It was engineered by researchers from the UK’s Cardiff University to create affordable, scalable and reproducible tissue.
Human tissue samples are needed for biomedical research to help advance scientific understanding of thousands of medical conditions as well as to develop effective treatments.
While 3D bioprinting offers hope for the development of these samples, it can be prohibitively expensive and off-the shelf devices can often be limited in their usability in the lab.
The Cardiff team hope that their LEGO 3D bioprinter could offer a technically proficient, scientifically robust, low-cost solution.
Using skin tissue as a mechanism to demonstrate the capability of the bioprinter, they have successfully printed hydrogel droplets containing cells.
They are now in the process of recreating the three-dimensional architecture of skin.
OPS: The Lego bioprinter team, from left to right: Dr Oliver Castell, Dr Chris Thomas and Dr Sion Coulman
Picture supplied by Ferrari (FOTO: DUKAS/FERRARI PRESS) -
DUK10142398_009
SCHICKSALE - Ein Paar hat nach dem Verlust von frühgeborenen Zwillingen eine Tochter bekommen
MERCURY PRESS (PICTURED- Chloe and Amelia) - A couple have had a miracle baby thanks to a single cervical stitch after the devastating loss of premature twins. Chloe and Chris Turner lost their twins, Alice and Amelia, after they were born severely premature at 24 weeks in June 2018. The couple, from Burton Latimer, Kettering, had been unaware that the removal of some precancerous cells from Chloe's cervix two years earlier had made her susceptible to going into early labour. They spent a year devastated with grief before they decided to try again for a baby and on June 12 2020 their miracle baby Amber, now ten months old, was born. - SEE MERC COPY (FOTO: DUKAS/CATERSNEWS)
(c) Dukas -
DUK10142398_010
SCHICKSALE - Ein Paar hat nach dem Verlust von frühgeborenen Zwillingen eine Tochter bekommen
WILLIAM LAILEY / MERCURY PRESS (PICTURED- Chris and Chloe Turner with ten month old Amber beside a memorial plant box in the garden dedicated to the twins) - A couple have had a miracle baby thanks to a single cervical stitch after the devastating loss of premature twins. Chloe and Chris Turner lost their twins, Alice and Amelia, after they were born severely premature at 24 weeks in June 2018. The couple, from Burton Latimer, Kettering, had been unaware that the removal of some precancerous cells from Chloe's cervix two years earlier had made her susceptible to going into early labour. They spent a year devastated with grief before they decided to try again for a baby and on June 12 2020 their miracle baby Amber, now ten months old, was born. - SEE MERC COPY (FOTO: DUKAS/CATERSNEWS)
(c) Dukas -
DUK10142398_007
SCHICKSALE - Ein Paar hat nach dem Verlust von frühgeborenen Zwillingen eine Tochter bekommen
WILLIAM LAILEY / MERCURY PRESS (PICTURED- Chris Turner with ten month old Amber holding a photo of the twins) - A couple have had a miracle baby thanks to a single cervical stitch after the devastating loss of premature twins. Chloe and Chris Turner lost their twins, Alice and Amelia, after they were born severely premature at 24 weeks in June 2018. The couple, from Burton Latimer, Kettering, had been unaware that the removal of some precancerous cells from Chloe's cervix two years earlier had made her susceptible to going into early labour. They spent a year devastated with grief before they decided to try again for a baby and on June 12 2020 their miracle baby Amber, now ten months old, was born. - SEE MERC COPY (FOTO: DUKAS/CATERSNEWS)
(c) Dukas -
DUK10142398_006
SCHICKSALE - Ein Paar hat nach dem Verlust von frühgeborenen Zwillingen eine Tochter bekommen
WILLIAM LAILEY / MERCURY PRESS (PICTURED- Chloe Turner holding a pictrue of the twins) - A couple have had a miracle baby thanks to a single cervical stitch after the devastating loss of premature twins. Chloe and Chris Turner lost their twins, Alice and Amelia, after they were born severely premature at 24 weeks in June 2018. The couple, from Burton Latimer, Kettering, had been unaware that the removal of some precancerous cells from Chloe's cervix two years earlier had made her susceptible to going into early labour. They spent a year devastated with grief before they decided to try again for a baby and on June 12 2020 their miracle baby Amber, now ten months old, was born. - SEE MERC COPY (FOTO: DUKAS/CATERSNEWS)
(c) Dukas -
DUK10142398_005
SCHICKSALE - Ein Paar hat nach dem Verlust von frühgeborenen Zwillingen eine Tochter bekommen
WILLIAM LAILEY / MERCURY PRESS (PICTURED- Chloe Turner with ten month old Amber) - A couple have had a miracle baby thanks to a single cervical stitch after the devastating loss of premature twins. Chloe and Chris Turner lost their twins, Alice and Amelia, after they were born severely premature at 24 weeks in June 2018. The couple, from Burton Latimer, Kettering, had been unaware that the removal of some precancerous cells from Chloe's cervix two years earlier had made her susceptible to going into early labour. They spent a year devastated with grief before they decided to try again for a baby and on June 12 2020 their miracle baby Amber, now ten months old, was born. - SEE MERC COPY (FOTO: DUKAS/CATERSNEWS)
(c) Dukas -
DUK10142398_004
SCHICKSALE - Ein Paar hat nach dem Verlust von frühgeborenen Zwillingen eine Tochter bekommen
WILLIAM LAILEY / MERCURY PRESS (PICTURED- Chris Turner with ten month old Amber) - A couple have had a miracle baby thanks to a single cervical stitch after the devastating loss of premature twins. Chloe and Chris Turner lost their twins, Alice and Amelia, after they were born severely premature at 24 weeks in June 2018. The couple, from Burton Latimer, Kettering, had been unaware that the removal of some precancerous cells from Chloe's cervix two years earlier had made her susceptible to going into early labour. They spent a year devastated with grief before they decided to try again for a baby and on June 12 2020 their miracle baby Amber, now ten months old, was born. - SEE MERC COPY (FOTO: DUKAS/CATERSNEWS)
(c) Dukas -
DUK10142398_003
SCHICKSALE - Ein Paar hat nach dem Verlust von frühgeborenen Zwillingen eine Tochter bekommen
WILLIAM LAILEY / MERCURY PRESS (PICTURED- Chris and Chloe Turner with ten month old Amber) - A couple have had a miracle baby thanks to a single cervical stitch after the devastating loss of premature twins. Chloe and Chris Turner lost their twins, Alice and Amelia, after they were born severely premature at 24 weeks in June 2018. The couple, from Burton Latimer, Kettering, had been unaware that the removal of some precancerous cells from Chloe's cervix two years earlier had made her susceptible to going into early labour. They spent a year devastated with grief before they decided to try again for a baby and on June 12 2020 their miracle baby Amber, now ten months old, was born. - SEE MERC COPY (FOTO: DUKAS/CATERSNEWS)
(c) Dukas -
DUK10142398_002
SCHICKSALE - Ein Paar hat nach dem Verlust von frühgeborenen Zwillingen eine Tochter bekommen
WILLIAM LAILEY / MERCURY PRESS (PICTURED- Ten month old Amber) - A couple have had a miracle baby thanks to a single cervical stitch after the devastating loss of premature twins. Chloe and Chris Turner lost their twins, Alice and Amelia, after they were born severely premature at 24 weeks in June 2018. The couple, from Burton Latimer, Kettering, had been unaware that the removal of some precancerous cells from Chloe's cervix two years earlier had made her susceptible to going into early labour. They spent a year devastated with grief before they decided to try again for a baby and on June 12 2020 their miracle baby Amber, now ten months old, was born. - SEE MERC COPY (FOTO: DUKAS/CATERSNEWS)
(c) Dukas -
DUK10142398_001
SCHICKSALE - Ein Paar hat nach dem Verlust von frühgeborenen Zwillingen eine Tochter bekommen
WILLIAM LAILEY / MERCURY PRESS (PICTURED- Chloe Turner with ten month old Amber and a photo of the twins Alice and Amelia) - A couple have had a miracle baby thanks to a single cervical stitch after the devastating loss of premature twins. Chloe and Chris Turner lost their twins, Alice and Amelia, after they were born severely premature at 24 weeks in June 2018. The couple, from Burton Latimer, Kettering, had been unaware that the removal of some precancerous cells from Chloe's cervix two years earlier had made her susceptible to going into early labour. They spent a year devastated with grief before they decided to try again for a baby and on June 12 2020 their miracle baby Amber, now ten months old, was born. - SEE MERC COPY (FOTO: DUKAS/CATERSNEWS)
(c) Dukas -
DUK10084931_072
FEATURE - Best of: Bilder des Tages
February 7, 2018 - Tirat Carmel, Israel - Israel based biotechnology Bonus Biogroup Ltd. goes public with its worldly unique breaking technology allowing growth of live and active human tissue outside of the body. The process includes liposuction harvesting of a patient's fat cells, two week regeneration of bone tissue in the lab and finally injecting live bone graft by syringe or surgery for total healing of bone loss due to trauma, aging or tumors. Establishes in 2008, now in Phase II of clinical study with 6 clusters of pending patents, the Bonus Biogroup process has been used to treat some 30 human patients with unprecedented results (FOTO: DUKAS/ZUMA)
(c) Dukas -
DUK10084028_002
NEWS - Die ersten Klonaffen: Zhong Zhong und Hua Hua
(180125) -- BEIJING, Jan. 25, 2018 (Xinhua) -- Two cloned macaques named Zhong Zhong and Hua Hua are held by a nurse at the non-human-primate research facility under the Chinese Academy of Sciences (CAS) on Jan. 22, 2018. China on Thursday announced it successfully cloned world's first macaques from somatic cells by method that made Dolly. (Xinhua/Jin Liwang) (dhf)
Xinhua News Agency / eyevine
Contact eyevine for more information about using this image:
T: +44 (0) 20 8709 8709
E: info@eyevine.com
http://www.eyevine.com
(FOTO: DUKAS/EYEVINE) *** Local Caption *** 02046614
(c) Dukas -
DUK10084028_003
NEWS - Die ersten Klonaffen: Zhong Zhong und Hua Hua
(180125) -- BEIJING, Jan. 25, 2018 (Xinhua) -- Two cloned macaques named Zhong Zhong and Hua Hua are held by a nurse at the non-human-primate research facility under the Chinese Academy of Sciences (CAS) on Jan. 22, 2018. China on Thursday announced it successfully cloned world's first macaques from somatic cells by method that made Dolly. (Xinhua/Jin Liwang) (dhf)
Xinhua News Agency / eyevine
Contact eyevine for more information about using this image:
T: +44 (0) 20 8709 8709
E: info@eyevine.com
http://www.eyevine.com
(FOTO: DUKAS/EYEVINE) *** Local Caption *** 02046606
(c) Dukas -
DUK10084028_001
NEWS - Die ersten Klonaffen: Zhong Zhong und Hua Hua
(180125) -- BEIJING, Jan. 25, 2018 (Xinhua) -- File photo provided by the Chinese Academy of Sciences shows two cloned macaques named Zhong Zhong and Hua Hua at the non-human-primate research facility under the Chinese Academy of Sciences. China on Thursday announced it successfully cloned world's first macaques from somatic cells by method that made Dolly. (Xinhua) (dhf)
Xinhua News Agency / eyevine
Contact eyevine for more information about using this image:
T: +44 (0) 20 8709 8709
E: info@eyevine.com
http://www.eyevine.com
(FOTO: DUKAS/EYEVINE) *** Local Caption *** 02046613
(c) Dukas -
DUK10084028_004
NEWS - Die ersten Klonaffen: Zhong Zhong und Hua Hua
(180125) -- BEIJING, Jan. 25, 2018 (Xinhua) -- Two cloned macaques named Zhong Zhong and Hua Hua are held by a nurse at the non-human-primate research facility under the Chinese Academy of Sciences (CAS) on Jan. 22, 2018. China on Thursday announced it successfully cloned world's first macaques from somatic cells by method that made Dolly. (Xinhua/Jin Liwang) (dhf)
Xinhua News Agency / eyevine
Contact eyevine for more information about using this image:
T: +44 (0) 20 8709 8709
E: info@eyevine.com
http://www.eyevine.com
(FOTO: DUKAS/EYEVINE) *** Local Caption *** 02046605
(c) Dukas -
DUK10084028_006
NEWS - Die ersten Klonaffen: Zhong Zhong und Hua Hua
(180125) -- BEIJING, Jan. 25, 2018 (Xinhua) -- Two cloned macaques named Zhong Zhong and Hua Hua are held by a nurse at the non-human-primate research facility under the Chinese Academy of Sciences (CAS) on Jan. 22, 2018. China on Thursday announced it successfully cloned world's first macaques from somatic cells by method that made Dolly. (Xinhua/Jin Liwang) (dhf)
Xinhua News Agency / eyevine
Contact eyevine for more information about using this image:
T: +44 (0) 20 8709 8709
E: info@eyevine.com
http://www.eyevine.com
(FOTO: DUKAS/EYEVINE) *** Local Caption *** 02046608
(c) Dukas -
DUK10084028_005
NEWS - Die ersten Klonaffen: Zhong Zhong und Hua Hua
(180125) -- BEIJING, Jan. 25, 2018 (Xinhua) -- Two cloned macaques named Zhong Zhong and Hua Hua are fed at the non-human-primate research facility under the Chinese Academy of Sciences, Jan. 22, 2018. China on Thursday announced it successfully cloned world's first macaques from somatic cells by method that made Dolly. (Xinhua/Jin Liwang) (dhf)
Xinhua News Agency / eyevine
Contact eyevine for more information about using this image:
T: +44 (0) 20 8709 8709
E: info@eyevine.com
http://www.eyevine.com
(FOTO: DUKAS/EYEVINE) *** Local Caption *** 02046607
(c) Dukas -
