Category Archives: Induced Pluripotent Stem Cells


Researchers have managed to bio-print a functional mini-liver in 90 days – FLWL News

Brazilian researchers claim to have bio-printed hepatic organoids. These are miniature versions of livers obtained from human blood cells. However, these mini-organs would be able to perform all the functions of a liver. This innovation gives new hope in terms of organ transplant.

A functional mini-liverIn their publication in the journal Biofabrication of November 27, 2019, researchers from the Human Genome and Stem Cell Institute in Sao Paulo (Brazil) indicated that they obtained a mini-liver through bio-printing. However, the latter would fulfill all the functions hoped for! These include the production of vital proteins, the storage of vitamins and the secretion of bile.

The researchers explained that they combined several bioengineering techniques. Indeed, the culture of pluripotent stem cells and cell reprogramming have been combined with 3D bio-printing. However, there is a difference compared to previous research. In fact, the cells were placed entirely in the bio-ink before being extruded. Previously, it was simply a matter of individual cells.

Relieve waiting for transplantNo less than 90 days were required, from collecting the patients blood to producing the tissue. First, the researchers reprogrammed the patients blood cells into induced pluripotent stem cells. Then, the differentiation of the cells made it possible to change them into liver cells. Finally, their spheroids may have been associated with bio-ink.

You should know that the project directors have bio-printed not one, but three mini-livers. Logically, the stem cells came from three different donors. The objective? Test the method then analyze the functionalities of the organs and the maintenance of cellular contact. As expected, the method worked much better than in the case of previous research incorporating individualized cells. The researchers said the technique could be replicated on a large scale.

Thus, this innovation could open up new hopes in terms of organ transplants. Indeed, the wait for an organ can be very long, which can be problematic. In China, tensions around the field of organ transplants have given rise to questionable research. In 2017, researchers said they wanted to clone pigs to recover their organs. The objective? To successfully transplant humans with these same organs and end the terrible waiting lists.

Lamia spent a couple of years interning at an organization that offered medical consultation before joining the editorial team at FLWL News. An enthusiastic fitness freak in the room, she offers the best amounts of insights and craft-based writing style to keep us up to date about the medicine industry, health and science.

Email:lamia@flwl.orgPhone: +1 512-845-8162

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Researchers have managed to bio-print a functional mini-liver in 90 days - FLWL News

CYTOVIA Therapeutics and the New York Stem Cell Foundation Research Institute enter into a partnership to develop iPSC derived CAR NK Therapeutics -…

Press release content from Globe Newswire. The AP news staff was not involved in its creation.

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NEW YORK, Jan. 09, 2020 (GLOBE NEWSWIRE) -- The New York Stem Cell Foundation (NYSCF) Research Institute today announced a partnership with Cytovia Therapeutics Inc. (Cytovia) to develop new disease treatments that leverage human stem cell research and novel gene editing techniques. NYSCF will be a key partner to Cytovia in using stem cells to advance novel therapeutic targets for cancer.

Cytovia leverages NK cells to make these novel therapeutics more specific to cancer cells. NK or natural killer cells are immune cells that scan the body and attack infected or abnormal cells, often serving as a first line of defense against cancer. CAR (chimeric antigen receptor) NK cells are genetically engineered to better locate and attack tumors. CAR NK-based treatments are currently showing promise in clinical trials and could serve as a potent and cost-efficient alternative to current immunotherapies. Establishing high-quality, stem-cell-derived NKs and CAR NKs will help improve these treatments and accelerate their path to the clinic.

The NYSCF Research Institute is a pioneer and acknowledged leader in stem cell technology, having developed the NYSCF Global Stem Cell Array, the premier automated robotic platform for reprogramming adult cells into induced pluripotent stem cells (iPSCs). These iPSCs carry the genetic blueprint of the person from whom they are derived and can be turned into any cell type in the body, allowing scientists to study disease mechanisms in affected cells or modify them for use in therapeutics.

Our mission is to bring lifesaving treatments to patients around the world and we are excited to further this goal in partnership with Cytovia, says NYSCF CEO and founder Susan L. Solomon. It is critical that we collaborate with partners using our technology and expertise to bring innovative treatments to the market.

We are delighted to collaborate with the NYSCF Research Institute to develop iPSC-derived NK and CAR NK therapeutics, says Dr. Daniel Teper, CEO of Cytovia. By integrating NYSCFs world-class stem cell know-how and the precision gene-editing research conducted at the University of California San Francisco, Cytovia aims to become a leader in NK cell therapeutics for the treatment of cancer.

About The New York Stem Cell Foundation Research Institute The New York Stem Cell Foundation (NYSCF) Research Institute is an independent non-profit organization accelerating cures and better treatments for patients through stem cell research. The NYSCF global community includes over 190 researchers at leading institutions worldwide, including the NYSCF Druckenmiller Fellows, the NYSCF Robertson Investigators, the NYSCF Robertson Stem Cell Prize Recipients, and NYSCF Research Institute scientists and engineers. The NYSCF Research Institute is an acknowledged world leader in stem cell research and in the development of pioneering stem cell technologies, including the NYSCF Global Stem Cell Array, which is used to create cell lines for laboratories around the globe. In 2019, NYSCF launched its Womens Reproductive Cancers Initiative, which aims to shift paradigms in the way these cancers are studied and treated, in collaboration with leading cancer experts across the globe. NYSCF focuses on translational research in an accelerator model designed to overcome barriers that slow discovery and replace silos with collaboration. For more information, visit http://www.nyscf.org.

About Cytovia Therapeutics Inc. Cytovia is dedicated to the development of transformational cancer immunotherapies, addressing several of the most challenging unmet medical needs including the prevention of cancer relapse and metastasis. Cytovia focuses on Natural Killer (NK) cell biology and applies precision medicine tools to develop the right therapy for the right patient at the right stage of the disease. Cytovia has secured access to multiple advanced technologies, including allogeneic cell therapy, multispecific antibodies, and cytokines. Cytovia establishes development partnerships to accelerate time-to-market and commercialization alliances in order to optimize rapid adoption of its novel immunotherapies. Learn more at cytoviatx.com

Contact information:CYTOVIA Therapeutics:Anna Baran-DjokovicVP, Corporate Affairs anna@cytoviatx.com

Cytovia Media Contact: Charlotte Tomic charlotte@tomiccommmunications.com Cell: 9178825243

NYSCF Research InstituteDavid McKeonChief of Staff dmckeon@nyscf.org

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CYTOVIA Therapeutics and the New York Stem Cell Foundation Research Institute enter into a partnership to develop iPSC derived CAR NK Therapeutics -...

Stem Cells Market Segmentation and Analysis Report, 2025 – Food & Beverage Herald

In theglobalstem cells marketa sizeable proportion of companies are trying to garner investments from organizations based overseas. This is one of the strategies leveraged by them to grow their market share. Further, they are also forging partnerships with pharmaceutical organizations to up revenues.

In addition, companies in the global stem cells market are pouring money into expansion through multidisciplinary and multi-sector collaboration for large scale production of high quality pluripotent and differentiated cells. The market, at present, is characterized by a diverse product portfolio, which is expected to up competition, and eventually growth in the market.

Some of the key players operating in the global stem cells market are STEMCELL Technologies Inc., Astellas Pharma Inc., Cellular Engineering Technologies Inc., BioTime Inc., Takara Bio Inc., U.S. Stem Cell, Inc., BrainStorm Cell Therapeutics Inc., Cytori Therapeutics, Inc., Osiris Therapeutics, Inc., and Caladrius Biosciences, Inc.

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As per a report by Transparency Market Research, the global market for stem cells is expected to register a healthy CAGR of 13.8% during the period from 2017 to 2025 to become worth US$270.5 bn by 2025.

Depending upon the type of products, the global stem cell market can be divided into adult stem cells, human embryonic stem cells, induced pluripotent stem cells, etc. Of them, the segment of adult stem cells accounts for a leading share in the market. This is because of their ability to generate trillions of specialized cells which may lower the risks of rejection and repair tissue damage.

Depending upon geography, the key segments of the global stem cells market are North America, Latin America, Europe, Asia Pacific, and the Middle East and Africa. At present, North America dominates the market because of the substantial investments in the field, impressive economic growth, rising instances of target chronic diseases, and technological progress. As per the TMR report, the market in North America will likely retain its dominant share in the near future to become worth US$167.33 bn by 2025.

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Investments in Research Drives Market

Constant thrust on research to broaden the utility scope of associated products is at the forefront of driving growth in the global stem cells market. Such research projects have generated various possibilities of different clinical applications of these cells, to usher in new treatments for diseases.Since cellular therapies are considered the next major step in transforming healthcare, companies are expanding their cellular therapy portfolio to include a range of ailments such as Parkinsons disease, type 1 diabetes, spinal cord injury, Alzheimers disease, etc.

The growing prevalence of chronic diseases and increasing investments of pharmaceutical and biopharmaceutical companies in stem cell research are the key driving factors for the stem cells therapeutics market. The growing number of stem cell donors, improved stem cell banking facilities, and increasing research and development are other crucial factors serving to propel the market, explains the lead analyst of the report.

This post was originally published on Food and Beverage Herald

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Stem Cells Market Segmentation and Analysis Report, 2025 - Food & Beverage Herald

Stem Cell Therapy Market Robust Growth Counted to 2025 – Instanews247

Stem Cell Therapy Market research now available at Industry Stats Report encompasses an exhaustive Study of this business space with regards to pivotal industry drivers, market share analysis, and the latest trends characterizing the Stem Cell Therapy industry landscape. This report also covers details of market size, growth spectrum, and the competitive scenario of Stem Cell Therapy market in the forecast timeline.

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The well-established Key players in the market are:

Gilead Novartis Organogenesis Vericel Others

This report for Stem Cell Therapy Market discovers diverse topics such as regional market scope, product market various applications, market size according to specific product, sales and revenue by region, manufacturing cost analysis, Industrial Chain, Market Effect Factors Analysis, market size forecast, and more.

Reports include the following segmentation: By Product Type Adult Stem Cells Human Embryonic Stem Cells (hESC) Induced Pluripotent Stem Cells Very Small Embryonic Like Stem CellsBy Applications Type Regenerative Medicine Drug Discovery and DevelopmentBy Technology Cell Acquisition Cell Production Cryopreservation Expansion and Sub-CultureBy Cell Therapy Autologous AllogeneicBy Region North Americao U.S.o Canadao Mexico Europeo UKo Franceo Germanyo Russiao Rest of Europe Asia-Pacifico Chinao South Koreao Indiao Japano Rest of Asia-Pacific LAMEAo Latin Americao Middle Easto Africa

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The report outlines the regulatory framework surrounding and governing numerous aspects of the market. At the end, Stem Cell Therapy industry development rival view, the industry scenario, samples, research conclusions are described. The important examination incorporated from 2014 to 2019 and till 2024 makes the report helpful assets for industry officials, promoting, sales, directors, experts, trade consultants, and others looking for key industry information with clearly given tables and charts.

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The Top Biotech Trends We’ll Be Watching in 2020 – Singularity Hub

Last year left us with this piece of bombshell news: He Jiankui, the mastermind behind the CRISPR babies scandal, has been sentenced to three years in prison for violating Chinese laws on scientific research and medical management. Two of his colleagues also face prison for genetically engineering human embryos that eventually became the worlds first CRISPRd babies.

The story isnt over: at least one other scientist is eagerly following Hes footsteps in creating gene-edited humans, although he stresses that he wont implant any engineered embryos until receiving regulatory approval.

Biotech stories are rarely this dramatic. But as gene editing tools and assisted reproductive technologies increase in safety and precision, were bound to see ever more mind-bending headlines. Add in a dose of deep learning for drug discovery and synthetic biology, and its fair to say were getting closer to reshaping biology from the ground upboth ourselves and other living creatures around us.

Here are two stories in biotech were keeping our eyes on. Although successes likely wont come to fruition this year (sorry), these futuristic projects may be closer to reality than you think.

The idea of human-animal chimeras immediately triggers ethical aversion, but the dream of engineering replacement human organs in other animals is gaining momentum.

There are two main ways to do this. The slightly less ethically-fraught idea is to grow a fleet of pigs with heavily CRISPRd organs to make them more human-like. It sounds crazy, but scientists have already successfully transplanted pig hearts into baboonsa stand-in for people with heart failurewith some recipients living up to 180 days before they were euthanized. Despite having foreign hearts, the baboons were healthy and acted like their normal buoyant selves post-op.

But for cross-species transplantation, or xenotransplants to work in humans, we need to deal with PERVsa group of nasty pig genes scattered across the porcine genome, remnants of ancient viral infections that can tag along and potentially infect unsuspecting human recipients.

Theres plenty of progress here too: back in 2017 scientists at eGenesis, a startup spun off from Dr. George Churchs lab, used CRISPR to make PERV-free pig cells that eventually became PERV-free piglets after cloning. Then last month, eGenesis reported the birth of Pig3.0, the worlds most CRISPRd animal to further increase organ compatibility. These PERV-free genetic wonders had three pig genes that stimulate immunorejection removed, and nine brand new human genes to make themin theorymore compatible with human physiology. When raised to adulthood, pig3.0 could reproduce and pass on their genetic edits.

Although only a first clinical propotype that needs further validation and refinement, eGenesis is hopeful. According to one (perhaps overzealous) estimate, the first pig-to-human xenotranplant clinical trial could come in just two years.

The more ethically-challenged idea is to grow human organs directly inside other animalsin other words, engineer human-animal hybrid embryos and bring them to term. This approach marries two ethically uncomfortable technologies, germline editing and hybrids, into one solution that has many wondering if these engineered animals may somehow receive a dose of humanness by accident during development. What if, for example, human donor cells end up migrating to the hybrid animals brain?

Nevertheless, this year scientists at the University of Tokyo are planning to grow human tissue in rodent and pig embryos and transplant those hybrids into surrogates for further development. For now, bringing the embryos to term is completely out of the question. But the line between humans and other animals will only be further blurred in 2020, and scientists have begun debating a new label, substantially human, for living organisms that are mainly human in characteristicsbut not completely so.

With over 800 gene therapy trials in the running and several in mature stages, well likely see a leap in new gene medicine approvals and growth in CAR-T spheres. For now, although transformative, the three approved gene therapies have had lackluster market results, spurring some to ponder whether companies may cut down on investment.

The research community, however, is going strong, with a curious bifurcating trend emerging. Let me explain.

Genetic medicine, a grab-bag term for treatments that directly change genes or their expression, is usually an off-the-shelf solution. Cell therapies, such as the blood cancer breakthrough CAR-T, are extremely personalized in that a patients own immune cells are genetically enhanced. But the true power of genetic medicine lies in its potential for hyper-personalization, especially when it comes to rare genetic disorders. In contrast, CAR-Ts broader success may eventually rely on its ability to become one-size-fits-all.

One example of hyper-tailored gene medicine success is the harrowing story of Mila, a six-year-old with Batten disease, a neurodegenerative genetic disorder that is always fatal and was previously untreatable. Thanks to remarkable efforts from multiple teams, however, in just over a year scientists developed a new experimental therapy tailored to her unique genetic mutation. Since receiving the drug, Milas condition improved significantly.

Milas case is a proof-of-concept of the power of N=1 genetic medicine. Its unclear whether other children also carry her particular mutationBatten has more than a dozen different variants, each stemming from different genetic miscodingor if anyone else would ever benefit from the treatment.

For now, monumental costs and other necessary resources make it impossible to pull off similar feats for a broader population. This is a shame, because inherited diseases rarely have a single genetic cause. But costs for genome mapping and DNA synthesis are rapidly declining. Were starting to better understand how mutations lead to varied disorders. And with multiple gene medicines, such as antisense oligonucleotides (ASOs) finally making a comeback after 40 years, its not hard to envision a new era of hyper-personalized genetic treatments, especially for rare diseases.

In contrast, the path forward for CAR-T is to strip its personalization. Both FDA-approved CAR-T therapies require doctors to collect a patients own immune T cells, preserved and shipped to a manufacturer, genetically engineered to boost their cancer-hunting abilities, and infused back into patients. Each cycle is a race against the cancer clock, requiring about three to four weeks to manufacture. Shipping and labor costs further drive up the treatments price tag to hundreds of thousands of dollars per treatment.

These considerable problems have pushed scientists to actively research off-the-shelf CAR-T therapies, which can be made from healthy donor cells in giant batches and cryopreserved. The main stumbling block is immunorejection: engineered cells from donors can cause life-threatening immune problems, or be completely eliminated by the cancer patients immune system and lose efficacy.

The good news? Promising results are coming soon. One idea is to use T cells from umbilical cord blood, which are less likely to generate an immune response. Another is to engineer T cells from induced pluripotent stem cells (iPSC)mature cells returned back to a young, stem-like state. A patients skin cells, for example, could be made into iPSCs that constantly renew themselves, and only pushed to develop into cancer-fighting T cells when needed.

Yet another idea is to use gene editing to delete proteins on T cells that can trigger an immune responsethe first clinical trials with this approach are already underway. With at least nine different off-the-shelf CAR-T in early human trials, well likely see movement in industrialized CAR-T this year.

Theres lots of other stories in biotech we here at Singularity Hub are watching. For example, the use of AI in drug discovery, after years of hype, may finally meet its reckoning. That is, can the technology actually speed up the arduous process of finding new drug targets or the design of new drugs?

Another potentially game-changing story is that of Biogens Alzheimers drug candidate, which reported contradicting results last year but was still submitted to the FDA. If approved, itll be the first drug to slow cognitive decline in a decade. And of course, theres always the potential for another mind-breaking technological leap (or stumble?) thats hard to predict.

In other words: we cant wait to bring you new stories from biotechs cutting edge in 2020.

Image Credit: Image by Konstantin Kolosov from Pixabay

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The Top Biotech Trends We'll Be Watching in 2020 - Singularity Hub

Induced Pluripotent Stem Cells Market Structure, Industry Inspection, and Forecast 2025 – Filmi Baba

The market study on the global Induced Pluripotent Stem Cells Market will include the entire ecosystem of the industry, covering five major regions namely North America, Europe, Asia Pacific, Latin America and Middle East & Africa, and the major countries falling under those regions. The study will feature estimates in terms of sales revenue and consumption from 2019 to 2025, at the global level and across the major regions mentioned above. The study has been created using a unique research methodology specifically designed for this market.

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Quantitative information includes Induced Pluripotent Stem Cells Market estimates & forecast for an upcoming years, at the global level, split across the key segments covered under the scope of the study, and the major regions and countries. Sales revenue and consumption estimates, year-on-year growth analysis, price estimation and trend analysis, etc. will be a part of quantitative information for the mentioned segments and regions/countries. Qualitative information will discuss the key factors driving the restraining the growth of the market, and the possible growth opportunities of the market, regulatory scenario, value chain & supply chain analysis, export & import analysis, attractive investment proposition, and Porters 5 Forces analysis among others will be a part of qualitative information. Further, justification for the estimates for each segments, and regions will also be provided in qualitative form.

Major Players included in this report are as follows Fujifilm Holding CorporationAstellas PharmaFate TherapeuticsBristol-Myers Squibb CompanyViaCyteCelgene CorporationAastrom BiosciencesAcelity HoldingsStemCellsJapan Tissue EngineeringOrganogenesis

Induced Pluripotent Stem Cells Market can be segmented into Product Types as HepatocytesFibroblastsKeratinocytesAmniotic CellsOthers

Induced Pluripotent Stem Cells Market can be segmented into Applications as Academic ResearchDrug Development And DiscoveryToxicity ScreeningRegenerative Medicine

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Induced Pluripotent Stem Cells Market: Regional analysis includes:Asia-Pacific (Vietnam, China, Malaysia, Japan, Philippines, Korea, Thailand, India, Indonesia, and Australia)Europe (Turkey, Germany, Russia UK, Italy, France, etc.)North America (United States, Mexico, and Canada.)South America (Brazil etc.)The Middle East and Africa (GCC Countries and Egypt.)

The study will also feature the key companies operating in the industry, their product/business portfolio, market share, financial status, regional share, segment revenue, SWOT analysis, key strategies including mergers & acquisitions, product developments, joint ventures & partnerships an expansions among others, and their latest news as well. The study will also provide a list of emerging players in the Induced Pluripotent Stem Cells Market.

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Induced Pluripotent Stem Cells Market Structure, Industry Inspection, and Forecast 2025 - Filmi Baba

Top Technical Advances of 2019 – The Scientist

Artificial intelligence tackles life science

Look under the hood of many of this years headline-making discoveries in biology and youll find machine learning, a tool thats gaining ground in the life sciences thanks to growing computational power and the availability of big datasets needed for training. Among other advances in 2019, researchers reported successfully using machine learning to screen images for signs of cancer or infection by pathogens, and to identify epigenetic markers in blood samples that are associated with vascular complications in people with diabetes. Check out our special issue on AI for more examples of how the tool is transforming biology.

Even as computers take on more of the tasks once done by hand, engineers are exploring DNAs capacity to adopt a function usually associated with machines: information storage. This summer, researchers in Boston reported a way of harnessing DNA, together with CRISPR-like base editing machinery, to make a record of events inside living cells that can then be decoded via sequencing. Study coauthor Timothy Lu of MIT told The Scientist that its potential applications include detecting environmental toxins and recording developmental processes.

Another creative spin on CRISPR-Cas9 editing to come out this year is a detection device for particular DNA sequences. Here, the Cas9 enzyme is bound to an RNA and to a graphene chip and engineered not to make cuts in DNA. If the RNA-Cas9 complex connects to its target DNA sequence, it causes a change in the chips electric field and thus a positive readout. The chips developers suggest it could one day be used for quick DNA tests in clinical settings.

Among the endless variations of CRISPR scientists are engineering, one developed this year purports to reduce its off-target effects by avoiding double-strand DNA breaks. The technique, known as prime editing, uses the same Cas9 nuclease as frequently deployed in the CRISPR system but combines the enzyme with a guide RNA called pegRNA and a reverse transcriptase that initiates the addition of a new sequence or base into the genome. Once the new genetic material is incorporated into a cut strand of DNA, the prime editor nicks the unedited strand, signaling to the cell to rebuild it to match the edited strand.

As some researchers worked on their own variations of genome editing, others made an important edit of a recipe for induced pluripotent stem cells. First published by Shinya Yamanaka (now of Kyoto University) in 2006, the method overexpresses genes for four transcription factors in differentiated cells to reset them to a pluripotent state, creating what are known as induced pluripotent stem cells (iPSCs). The most important of the four overproduced factors was thought to be Oct4. But last month, researchers at the Max Planck Institute for Molecular Biomedicine announced theyd not only managed to make mouse iPSCs without tweaking Oct4 levels, but that the process was more efficient that way. If this works in adult human cells, it will be a huge advantage for the clinical applications of iPS cells, Yamanaka wrote in an email to The Scientist.

Shawna Williams is a senior editor atThe Scientist. Email her at swilliams@the-scientist.com or follow her on Twitter @coloradan.

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Top Technical Advances of 2019 - The Scientist

The next 3D-printing craze? It could be functioning ‘mini-livers’ – Inverse

3D-printing human organs will save lives once perfected. Over 100,000 people are currently on a transplant waiting list, and 18 people die every day in the United States waiting to receive a transplant. If we could just print someone an organ using their own cells, they wouldnt have to wait for a donor and thered be pretty much no chance of the organ being rejected. Researchers in Brazil just successfully 3D-printed mini-livers in a lab, and they function just like a regular liver. Their research was published in late November 2019 in the journal Biofabrication.

The researchers took blood from three volunteers and reprogrammed the blood cells to turn them into pluripotent stem cells, which are able to develop into any type of cell found in the human body.

The pluripotent stem cells were then induced to become liver cells, mixed with bioink and put through the 3D printer as spheroids. Spheroids are clusters of cells, so unlike other organ tissue that has been printed by researchers in the past, they were printing with more than one cell at a time. The researchers then let the structure culture for 18 days.

When the scientists examined the culture after it growth period, they found hepatic organoids, which are essentially miniature livers. They are able to function exactly as a liver does on a smaller scale.

Ernesto Goulart, a postdoctoral fellow at the University of So Paulos Institute of Biosciences and an author of the study, claimed in a statement that their method was more successful than other methods.

Instead of printing individualized cells, we developed a method of grouping them before printing. These clumps of cells, or spheroids, are what constitute the tissue and maintain its functionality much longer, Goulart.

The tissue that was printed maintained hepatic functions longer than other liver tissue produced by 3D printing. Hepatic function is the term for how well the liver is working.

See also: How 3D-Printed Organs at the International Space Station May Cure Diseases

The researchers claim this whole process can be completed in 90 days. They claim their methods could definitely be used to print a fully functioning human liver.

We did it on a small scale, but with investment and interest, it can easily be scaled up, Goulart said.

Scientists have been getting much better at 3D-printing organ tissue and miniature versions of human organs in recent years. Scientists at Tel Aviv University were actually able to print a mini-human heart earlier this year. The bio-printing company Organovo is actually trying to have a patient receive a partial organ transplant with tissue made by a 3D printer by next year. A partial transplant would mean a portion of the organ tissue is replaced, which would in turn theoretically buy a patient a year or two before they need a transplant.

Were still years away from a scenario where people are regularly getting entirely new organs that were made using their own cells, but its not science fiction anymore. Once this technology proliferates and becomes affordable for the average person, well enter a time when people dont die waiting for transplants anymore.

Abstract:

The liver is responsible for many metabolic, endocrine and exocrine functions. Approximately 2 million deaths per year are associated with liver failure. Modern 3D bioprinting technologies allied with autologous induced pluripotent stem cells (iPS)-derived grafts could represent a relevant tissue engineering approach to treat end stage liver disease patients. However, protocols that accurately recapitulates livers epithelial parenchyma through bioprinting are still underdeveloped. Here we evaluated the impacts of using single cell dispersion (i.e. obtained from conventional bidimensional differentiation) of iPS-derived parenchymal (i.e. hepatocyte-like cells) versus using iPS-derived hepatocyte-like cells spheroids (i.e. three-dimensional cell culture), both in combination with non-parenchymal cells (e.g. mesenchymal and endothelial cells), into final liver tissue functionality. Single cell constructs showed reduced cell survival and hepatic function and unbalanced protein/amino acid metabolism when compared to spheroid printed constructs after 18 days in culture. In addition, single cell printed constructs revealed epithelial-mesenchymal transition, resulting in rapid loss of hepatocyte phenotype. These results indicates the advantage of using spheroid-based bioprinting, contributing to improve current liver bioprinting technology towards future regenerative medicine applications and liver physiology and disease modeling.

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The next 3D-printing craze? It could be functioning 'mini-livers' - Inverse

Induced Pluripotent Stem Cells Market: Latest Innovations, Drivers and Industry Key Events 2016 2021 – Market Reports Observer

The global market forinduced pluripotent stem cells (iPSCs)reached $2.1 billion in 2016. The market should reach $3.6 billion in 2021, increasing at a compound annual growth rate (CAGR) of 11.6% from 2016 through 2021.

Report Scope:

This study is focused on the market side of iPSCs rather than its technical side. Different market segments for this emerging market are covered. For example, application-based market segments include academic research, drug development and toxicity testing, and regenerative medicine; product function-based market segments include molecular and cellular engineering, cellular reprogramming, cell culture, cell differentiation and cell analysis; iPSC-derived cell-type-based market segments include cardiomyocytes, hepatocytes, neurons, endothelia cells and other cell types; geography-based market segments include the U.S., Europe, Asia-Pacific and Rest of World. Research and market trends are also analyzed by studying the funding, patent publications and research publications in the field.

Report Includes:

An overview of the global market for induced pluripotent stem cells. Analyses of global market trends with data from 2015 and 2016, and projections of compound annual growth rates (CAGRs) through 2021. Information on induced pluripotent stem cell research products, defined as all research tools including but not limited to: induced pluripotent stem cells and various differentiated cells derived from induced pluripotent stem cells; various related assays and kits, culture media and medium components, such as serum, growth factors and inhibitors, antibodies, enzymes, and many others that can be applied for the specific purpose of executing induced pluripotent stem cell research. Discussion of important manufacturers, technologies, and factors influencing market demand, such as the driving forces and limiting factors of induced pluripotent stem cell market growth. Profiles of major players in the industry.

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Report Summary

Its been over 10 years since the discovery of induced pluripotent stem cell (iPSC) technology. The market has gradually become an important part of the life sciences industry during recent years. Particularly for the past five years, the global market for iPSCs has experienced a rapid growth. The market was estimated at $1.7 billion in 2015 and over $2 billion in 2016, with an average 18% growth. The overall iPSC market is forecast to continue its relatively rapid growth and reach over $3.6 billion in 2021, with an estimated compound annual growth rate (CAGR) of 11.6% from 2016 through 2021.

Key Drivers for Market Growth

This report has identified several key drivers for the rapidly growing market: iPSC shold promising hope for therapeutic solutions for diseases without ethical issues. A series of technical breakthroughs were made in recent years for improving cellular reprogramming, differentiation and large-scale production of GMP- grade iPSCs derived cells toward clinical usability. The pharmaceutical industry needs better cell sources such as iPSC-derived functional cells for drug toxicity testing and drug screening. The U.S. government has been encouraging the marketing of stem cells, including iPSCs.

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The U.S. Food and Drug Administration (FDA) has been authorized to provide orphan drug designations for many of the therapies developed for rare diseases such as Parkinsons and Huntingtons using stem cells. The provisions of grants from organizations, such as the National Institutes of Health (NIH) and the California Institute for Regenerative Medicine (CIRM) have been encouraging for the research institutes to venture into iPSC research. Rapidly growing medical tourism and contract research outsourcing drives the Asia-Pacific stem cell market. Cellular reprogramming, including iPSC technology, was awarded the 2012 Nobel Prize. The first human iPSC clinical trial started in August 2014, and the recent report of the first macular degeneration patient treated with the sheets of retinal pigmented epithelial cells made from iPSCs was encouraging. iPSC technology is developing into a platform for precision and personalized medicine, which is experiencing rapid growth globally. New biotechnologies such as genome editing technology are advancing iPSCs into more and better uses.

This report identifies key revenue segments for the iPSC market from various aspects. The applicationbased segments include the research, drug development and clinical markets; the product functionbased segments include molecular and cellular engineering, cellular reprogramming, cell culture, cell differentiation and cell analysis. The current major revenue segment is the drug development and toxicity testing sector, but the market for regenerative medicine is the fastest growing one. The marketfor clinical applications is not fully established, but the market for the translational medicine research of iPSC is also growing very quickly.

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Stem Cell-Derived Cells Market Expected to Expand at a Steady CAGR through 2019 2029 – Downey Magazine

An exhaustive study report on the Stem Cell-Derived Cells Market published by Persistence Market Research offers an in-depth understanding of the critical aspects that are expected to propel the growth of the Stem Cell-Derived Cells Market in the foreseeable future. Furthermore, by analyzing the data enclosed in the report, leading investors, stakeholders and upcoming market players can devise strategic methodologies to gather momentum and enhance their global footprint in the current Stem Cell-Derived Cells Market landscape.

As per the critical nuances of the study, the Stem Cell-Derived Cells market is poised to grow at a CAGR of ~XX% and attain a value of ~US$XX by the end of 2029. Prevailing and future prospects of the Stem Cell-Derived Cells Market gives readers a sinuous understanding and detailed market intelligence of the Stem Cell-Derived Cells Market landscape.

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Important Aspects Related to the Stem Cell-Derived Cells Market Included in the Report

The report answers the following questions related to the Stem Cell-Derived Cells Market:

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key players in stem cell-derived cells market are focused on generating high-end quality cardiomyocytes as well as hepatocytes that enables end use facilities to easily obtain ready-made iPSC-derived cells. As the stem cell-derived cells market registers a robust growth due to rapid adoption in stem cellderived cells therapy products, there is a relative need for regulatory guidelines that need to be maintained to assist designing of scientifically comprehensive preclinical studies. The stem cell-derived cells obtained from human induced pluripotent stem cells (iPS) are initially dissociated into a single-cell suspension and later frozen in vials. The commercially available stem cell-derived cell kits contain a vial of stem cell-derived cells, a bottle of thawing base and culture base.

The increasing approval for new stem cell-derived cells by the FDA across the globe is projected to propel stem cell-derived cells market revenue growth over the forecast years. With low entry barriers, a rise in number of companies has been registered that specializes in offering high end quality human tissue for research purpose to obtain human induced pluripotent stem cells (iPS) derived cells. The increase in product commercialization activities for stem cell-derived cells by leading manufacturers such as Takara Bio Inc. With the increasing rise in development of stem cell based therapies, the number of stem cell-derived cells under development or due for FDA approval is anticipated to increase, thereby estimating to be the most prominent factor driving the growth of stem cell-derived cells market. However, high costs associated with the development of stem cell-derived cells using complete culture systems is restraining the revenue growth in stem cell-derived cells market.

The global Stem cell-derived cells market is segmented on basis of product type, material type, application type, end user and geographic region:

Segmentation by Product Type

Segmentation by End User

The stem cell-derived cells market is categorized based on product type and end user. Based on product type, the stem cell-derived cells are classified into two major types stem cell-derived cell kits and accessories. Among these stem cell-derived cell kits, stem cell-derived hepatocytes kits are the most preferred stem cell-derived cells product type. On the basis of product type, stem cell-derived cardiomyocytes kits segment is projected to expand its growth at a significant CAGR over the forecast years on the account of more demand from the end use segments. However, the stem cell-derived definitive endoderm cell kits segment is projected to remain the second most lucrative revenue share segment in stem cell-derived cells market. Biotechnology and pharmaceutical companies followed by research and academic institutions is expected to register substantial revenue growth rate during the forecast period.

North America and Europe cumulatively are projected to remain most lucrative regions and register significant market revenue share in global stem cell-derived cells market due to the increased patient pool in the regions with increasing adoption for stem cell based therapies. The launch of new stem cell-derived cells kits and accessories on FDA approval for the U.S. market allows North America to capture significant revenue share in stem cell-derived cells market. Asian countries due to strong funding in research and development are entirely focused on production of stem cell-derived cells thereby aiding South Asian and East Asian countries to grow at a robust CAGR over the forecast period.

Some of the major key manufacturers involved in global stem cell-derived cells market are Takara Bio Inc., Viacyte, Inc. and others.

The report covers exhaustive analysis on:

Regional analysis includes

Report Highlights:

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