Science Daily | Brain tissue from a petri dish: Stem cell research -- ScienceDaily Science Daily The most complex organ in humans is the brain. Due to its complexity, it is extremely difficult to do scientific experiments on it -- ones that could help us to ... |
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Brain tissue from a petri dish: Stem cell research -- ScienceDaily - Science Daily
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'Cradle of life' stem cells taken from skin samples were developed into three-dimensional brain-like organisms capable of exchanging signals between each other in a network.
The petri dish cells behave in a similar way to the brain cells which produce messenger dopamine from neurons - and scientists hope they will be able to use them to come up with a cure for Parkinson's.
Dopamine maintains smooth body movements, but when the neurons die off, tremors, rigid muscles and other Parkinson's disease symptoms begin to take over.
The new developments mean scientists can now use the cells to test what environmental factors like pollutants have on the onset of the disease and potentially find a cure.
Lead author Professor Jens Schwamborn said: "Our cell cultures open new doors to brain research.
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"We can now use them to study the causes of Parkinson's disease and how it could possibly be effectively treated."
Our cell cultures open new doors to brain research
Professor Jens Schwamborn
The stem cells can be transformed into any cell type of the human body but cannot produce a complete organism.
PHD student Anna Monzel developed a procedure to convert the stem cells into brain cells as part of her doctoral thesis.
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Tremor - One of the most noticeable signs of Parkinson's is a tremor that often starts in the hands or fingers when they are relaxed
She said: "I had to develop a special, precisely defined cocktail of growth factors and a certain treatment method for the stem cells, so that they would differentiate in the desired direction."
Prof Schwamborn from the Luxembourg Centre for Systems Biomedicine at Luxembourg University said: "Our subsequent examination of these artificial tissue samples revealed that various cell types characteristic of the midbrain had developed."
"The cells can transmit and process signals.
"We were even able to detect dopaminergic cells - just like in the midbrain."
The scientists say their petri dish study can also reduce the amount of animal testing in brain research.
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Because cell cultures in the petri dishes are of human origin in some aspects they resemble human brains more than the brains of lab animals such as rats or mice.
Professor Schwamborn added: "There are also attractive economic opportunities in our approach.
"The production of tissue cultures is highly elaborate.
"In the scope of our spin-off Braingineering Technologies Sarl, we will be developing technologies by which we can provide the cultures for a fee to other labs or the pharmaceutical industry for their research."
The study was published in the Stem Cell Reports journal.
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Parkinson's breakthrough: Scientists one step closer to making a BRAIN out of stem cells - Express.co.uk
SUNRISE, FL / ACCESSWIRE / April 13, 2017 / U.S. Stem Cell, Inc. (USRM), a Florida corporation and leader in novel regenerative medicine solutions and physician-based stem cell therapies for human and animal patients, has received a commitment to invest up to $5,000,000 from private equity firm General American Capital Partners LLC (GACP) in exchange for up to 63,873,275 shares of common stock.
"We see exponential growth in the stem cell industry, estimated to grow to $170 billion by 2020," said Joseph DaGrosa, Jr., a Principal with General American Capital Partners. "We are very pleased to join forces with U.S. Stem Cell, Inc., a leader in regenerative medicine solutions, to help expand our role in this important market."
The 21st Century Cures Act, signed into effect in December of 2016, builds on the FDA's ongoing efforts to advance medical product innovation and ensure that patients get access to treatments as quickly as possible, with continued assurance from high quality evidence that they are safe and effective.
"Patient demand for regenerative medicine procedures as a viable alternative to surgery, as well as the transformative capacity of stem cell therapies, are leading the way to increased acceptance by both the medical and regulatory communities," said Mike Tomas, President and CEO of U.S. Stem Cell, Inc.
About U.S. Stem Cell, Inc.
US Stem Cell, Inc. (formerly Bioheart, Inc.) is an emerging enterprise in the regenerative medicine / cellular therapy industry. We are focused on the discovery, development, and commercialization of cell based therapeutics that prevent, treat, or cure disease by repairing and replacing damaged or aged tissue, cells and organs and restoring their normal function. We believe that regenerative medicine / cellular therapeutics will play a large role in positively changing the natural history of diseases, ultimately, we contend, lessening patient burdens, as well as reducing the associated economic impact disease imposes upon modern society.
Our business, which includes three operating divisions (US Stem Cell Training, Vetbiologics, and US Stem Cell Clinic) includes the development of proprietary cell therapy products, as well as revenue generating physician and patient based regenerative medicine / cell therapy training services, cell collection and cell storage services, the sale of cell collection and treatment kits for humans and animals, and the operation of a cell therapy clinic. Management maintains that revenues and their associated cash in-flows generated from our businesses will, over time, provide funds to support our clinical development activities, as they do today for our general business operations. We believe the combination of our own therapeutics pipeline combined with our revenue generating capabilities provides the Company with a unique opportunity for growth and a pathway to profitability.
Forward-Looking Statements:
Except for historical matters contained herein, statements made in this press release are forward-looking statements. Without limiting the generality of the foregoing, words such as "may," "will," "to," "plan," "expect," "believe," "anticipate," "intend," "could," "would," "estimate," or "continue," or the negative other variations thereof or comparable terminology are intended to identify forward-looking statements. Forward-looking statements involve known and unknown risks, uncertainties, and other factors which may cause our actual results, performance or achievements to be materially different from any future results, performance or achievements expressed or implied by the forward-looking statements. Also, forward-looking statements represent our management's beliefs and assumptions only as of the date hereof. Except as required by law, we assume no obligation to update these forward-looking statements publicly, or to update the reasons actual results could differ materially from those anticipated in these forward-looking statements, even if new information becomes available in the future.
The Company is subject to the risks and uncertainties described in its filings with the Securities and Exchange Commission, including the section entitled "Risk Factors" in its Annual Report on Form 10-K for the year ended December 31, 2016, and its Quarterly Reports on Form 10-Q.
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General American Capital Partners Invests up to $5 Million in U.S. Stem Cell, Inc. - Yahoo Finance
DUBLIN--(BUSINESS WIRE)--Research and Markets has announced the addition of the "Human Embryonic Stem Cells (hESC) Market, 2014 - 2025" report to their offering.
The global human embryonic stem cells (hESCs) market is anticipated to reach USD 1.06 billion by 2025. Application of hESCs as a promising donor source for cellular transplantation therapies is anticipated to bolster progress through to 2025. hESCs technology tends to be useful for tissue engineering in humans due to high histocompatibility between host and graft.
Maintenance of developmental potential for contribution of derivatives of all three germ layers is an important feature of these cells. This ability remains consistent even after clonal derivation or prolonged undifferentiated proliferation, thus pronouncing its accelerated uptake.
In addition, these are capable in expressing high level of alkaline phosphatase, key transcription factors, and telomerase. These factors are found to be of great importance in the maintenance of the inner cellular mass pluripotency.
Furthermore, hESCs can be easily differentiated into defined neurons, neural lineages, oligodendrocytes, and astrocytes. Aforementioned characteristic makes it useful in studying the sequence of events that take place during early neurodevelopment.
However, use of stem cells derived from viable embryos is fraught with ethical issues, prompting scientists to explore other methods to generate ESCs. The other methods include derivation of embryonic germ cells, stem cells from dead embryos, and other techniques.
Companies Mentioned
Key Topics Covered:
1 Research Methodology
2 Executive Summary
3 Human Embryonic Stem Cells Market Variables, Trends & Scope
4 Human Embryonic Stem Cells Market: Application Estimates & Trend Analysis
5 Human Embryonic Stem Cells Market: Regional Estimates & Trend Analysis, by Application
6 Competitive Landscape
For more information about this report visit http://www.researchandmarkets.com/research/w7n75n/human_embryonic
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Human Embryonic Stem Cells (hESC) Market to Reach $1 Billion by 2025 - Application of hESCs as a Promising Donor ... - Business Wire (press release)
The global human embryonic stem cells (hESCs) market is anticipated to reach USD 1.06 billion by 2025, according to a new report by Grand View Research, Inc. Application of hESCs as a promising donor source for cellular transplantation therapies is anticipated to bolster progress through to 2025. hESCs technology tends to be useful for tissue engineering in humans due to high histocompatibility between host and graft.
Maintenance of developmental potential for contribution of derivatives of all three germ layers is an important feature of these cells. This ability remains consistent even after clonal derivation or prolonged undifferentiated proliferation, thus pronouncing its accelerated uptake.
In addition, these are capable in expressing high level of alkaline phosphatase, key transcription factors, and telomerase. These factors are found to be of great importance in the maintenance of the inner cellular mass pluripotency.
Furthermore, hESCs can be easily differentiated into defined neurons, neural lineages, oligodendrocytes, and astrocytes. Aforementioned characteristic makes it useful in studying the sequence of events that take place during early neurodevelopment.
Request a sample of the report: http://www.orbisresearch.com/contacts/request-sample/240830
However, use of stem cells derived from viable embryos is fraught with ethical issues, prompting scientists to explore other methods to generate ESCs. The other methods include derivation of embryonic germ cells, stem cells from dead embryos, and other techniques.
Further Key Findings from the Study Suggest:
hESC derivation provides a unique opportunity for early human development studies.
It is believed to hold a substantial potential for regenerative medicine and biopharma.
Differentiated derivatives of these cells are applicable for screening assays in development of novel pharmaceutical moieties.
Screening for mutagenic as well as toxic compounds can also be carried out using such derivatives.
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Presence of lack of suitable donor organs and tissues for regenerative medicine is expected to increase the demand thus influencing growth.
Stem cell research is anticipated to exhibit fastest growth amongst the other applications.
However, presence of controversies pertaining to their use as a consequence of ethical considerations is responsible for steady growth.
Europe accounts for considerable share of the market, following North America.
As per a recent survey carried out by Swiss government, citizens there are more willing to accept embryonic stem cell research than politicians.
Asia Pacific is anticipated to drive market with fastest YoY growth.
Rising awareness amongst the population and physicians with respect to associated therapies is anticipated to propel progress.
Key players contributing in this market are CellGenix GmbH, International Stem Cell Corporation, Thermo Fisher Scientific, Inc.; Kite Pharma, PromoCell GmbH, and Lonza.
Presence of clinical trial pipeline for embryonic stem cell derived therapy for targeting different diseases is expected to fuel growth.
The diseases targeted include macular degeneration, Parkinsons disease, type I diabetes mellitus, and spinal cord injury.
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Global Human Embryonic Stem Cells Market Size, Growth, Share, Trends and Forecast by 2025- Market Research ... - MilTech
April 13, 2017 On Fig 1. you see two virtual slices. On the left side it is through the parasite. The digestive vacuole is light gray and the hemozoin crystals are black. In addition you see two nuclei. To the right you see a slice behind the vacuole with a third nucleus. The number of nuclei can be used to calculate when the cell was infected. Credit: Niels Bohr Institute
An international research team, led by Sergey Kapishnikov from the X-ray and Neutron Science section at the Niels Bohr Institute, has developed new techniques in analyzing malaria infected red blood cells, an important step towards finding more effective medicine. This amoeba is the biggest killer in the world earth's most dangerous animal.
The parasite has a complicated life cycle, and during most of the time, the parasite is inside a cell, making it very difficult for the immune system to respond. No patient has been found with permanent immunity, making the probability of developing a vaccine very low.
Dr Kapishnikov's group used advanced technologies to produce virtual cell slices, and examined them with soft and hard x-rays. In particular, they focused on the concentrations of iron, sulfur and potassium, in order to find the concentrations of iron in hemoglobin and in the hemozoin crystals found inside the parasites. They also found that the potassium concentration in infected cells was seven times lower than in pristine cells, but that the overall concentration was the same, suggesting that the potassium was absorbed by the parasite.
The parasite digests hemoglobin, using the protein as a nutrient. Heme molecules are formed during the degradation of hemoglobin. Heme is poisonous to the parasite, so it is immediately stored in pairs inside the digestive vacuole as hemozoin crystals. Now they are harmless, so an obvious goal to develop new cures against malaria could be to prevent this hemozoin formation, so that the heme's negative effects would remain.
Explore further: Malarial parasites dodge the kill
Scientists have uncovered a potential mode of parasite drug resistance in malaria infection, according to a report published in The Journal of Experimental Medicine.
The iron-containing molecule heme is necessary for life. Cells require heme to perform the chemical reactions that produce energy, among other critical tasks.
Two new studies from the Francis Crick Institute shed light on how the malaria parasite grows inside a host's red blood cells and breaks out when it's ready to spread to new host cells.
The compound that detectives spray at crime scenes to find trace amounts of blood may be used one day to kill the malaria parasite.
Despite decades of malaria research, the disease still afflicts hundreds of millions and kills around half a million people each year - most of them children in tropical regions. Part of the problem is that the malaria parasite ...
Malaria parasites cause red blood cells to become bendier, helping the parasites to enter and cause infection, says a new study.
A team of scientists from the Broad Institute of MIT and Harvard, the McGovern Institute for Brain Research at MIT, the Institute for Medical Engineering & Science at MIT, and the Wyss Institute for Biologically Inspired ...
People's ability to make random choices or mimic a random process, such as coming up with hypothetical results for a series of coin flips, peaks around age 25, according to a study published in PLOS Computational Biology.
The bacterial flagellum is one of nature's smallest motors, rotating at up to 60,000 revolutions per minute. To function properly and propel the bacterium, the flagellum requires all of its components to fit together to exacting ...
There are many processes that take place in cells that are essential for life. Two of these, transcription and translation, allow the genetic information stored in DNA to be deciphered into the proteins that form all living ...
A research group led by Hitoshi Kurumizaka, a professor of structural biology at Waseda University, unveiled the crystal structure of an overlapping dinucleosome, a newly discovered chromatin structural unit. This may explain ...
Hunting is a major threat to wildlife particularly in tropical regions, but a systematic, large-scale estimate of hunting-induced declines of animal numbers has been lacking. A study published in Science on April 14 fills ...
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An important step towards new malaria medicine - Phys.Org
For the past five decades pharmaceutical drugs like levodopa have been the gold standard for treating Parkinsons disease. These medications alleviate motor symptoms of the disease, but none of them can cure it.
Now a study from the Karolinska Institute in Stockholm shows it is possible to coax the brains own astrocytescells that typically support and nurture neuronsinto producing a new generation of dopamine neurons.
The reprogrammed cellscould alter the course of Parkinsons, according to the researchers. You can directly reprogram a cell that is already inside the brain and change the function in such a way that you can improve neurological symptoms, says senior author Ernest Arenas, a professor of medical biochemistry at Karolinska.
Directly converting astrocytes already present in patients brains could eliminate the need to search for donor cells[and the treatment may] be less likely to cause side effects compared with current drugs. This is like stem cell 2.0. Its the next-generation approach to stem cell treatments and regenerative medicine, says James Beck, vice president and chief scientific officer, for the nonprofit Parkinsons Disease Foundation.
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The GLP aggregated and excerpted this blog/article to reflect the diversity of news, opinion, and analysis. Read full, original post:Cell Therapy 2.0: Reprogramming the Brains Own Cells for Parkinsons Treatment
For more background on the Genetic Literacy Project, read GLP on Wikipedia
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Parkinson's stem cell therapy 2.0: New treatment coaxes the brain to repair itself - Genetic Literacy Project
by Kathleen Raven April 13, 2017
Jason Thomson, a core lab manager at the Yale Stem Cell Center, rebounded after large pharmaceutical companies retrenched in Connecticut. Photo credit: Robert Lisak
Six years ago, Jason Thomson learned that his 13-year position in research at Pfizer would come to an end. He was among 1,100 employees laid off at the companys drug development laboratory in Groton. He feared that his career was in jeopardy. He didnt want to move his family and worried he wouldnt be able to land a comparable job in Connecticut.
But things worked out much better than he expected. I was fortunate, says Thomson, a resident of Colchester. I was out of work for just over six months. Today, hes a lab manager at the Yale Stem Cell Center in New Haven. He plays a key role at the center, overseeing the preparation of stem cells that other researchers use to pursue their studies.
Thomsons personal journey illustrates an economic shift in Connecticut. Over the past decade, several large pharmaceutical companies have either closed their doors here or cut hundreds of jobs from their local payrolls. These moves pose a threat to the state economy. For Connecticut to thrive in the future, say state political, academic and business leaders, more jobs are needed in groundbreaking biomedical research and a home-grown biotech industry.
The 10-year-old Yale Stem Cell Center, which is within Yale School of Medicine, is an example of how this can be done. It has already created more than 200 jobs; involves more than 450 Yale faculty, post-docs and students; has produced more than 350 patent applications; and has three therapies currently being tested in clinical trials. And, because this type of research typically takes many years to have maximum impact, its likely that the best is yet to come.
So far, three clinical trials are testing drugs based on scientific advances produced by Stem Cell Center researchers. They include using cell-based tissue engineering to cure congenital heart defects, and using skeletal stem cells to treat stroke and spinal cord injuries.
Here's an infographic explaining how the Yale Stem Cell Center contributes to society.
This is about faculty members and researchers making breakthrough discoveries and passing them along to business experts to take to the market.
Yale School of Medicine plays a critical role in fostering a fast-growing bioscience industry in the New Haven area. Already, upwards of 40 biotech and medical device companies employ more than 5,000 people in greater New Haven. This is about faculty members and researchers making breakthrough discoveries and passing them along to business experts to take to the market, says Susan Froshauer, president of Connecticut United for Research Excellence (CURE), the bioscience industrys advocacy group.
At Pfizer, Thomsons job was to determine the safety profile of drugs using embryonic stem cells from mice. The New York native, who studied animal science at Cornell University, loved the company and his job, but he wasnt surprised when the bad news came. He had seen evidence that a retrenchment in the pharmaceutical industry was underway. For instance, just a few years earlier, Bayer Healthcare began shutting down its West Haven facility, which displaced about 1,000 workers. (The sprawling facility is now Yale Universitys West Campus.)
When Thomson received the layoff notice, leaving Connecticut and moving to another state wasnt an attractive option. He didnt want to disrupt his wifes career as a tenured high school teacher, nor the lives of his two young daughters.
He recalled hearing about efforts in the state to foster its strengths in biosciencein part by funding university research. Thomson began monitoring university websites. After a few nervous months, he got his big break. The Yale Stem Cell Center posted what he considered a dream job. Thomson appliedand got it.
Hes now a respected leader and colleague at the center. Caihong Qiu, Ph.D., who is the technical director of the Centers two core science labs, says researchers there admire Thomson for his deep scientific knowledge and helpful manner. Jason is the face of the core. He is very thorough and dedicated, Qiu says.
At the center, Thomson grows stem cells so scientists can conduct experiments to better understand the underlying cause of diseases, or to learn how to build new human organs. He provides feedback on study designs, orders lab supplies, and oversees the nitrogen tanks and other machinery that keep 10 years worth of cells frozen. He calls the core labs the special forces unit within the center. No matter how difficult the task is, they get it done.
Thomson loves working with stem cells because they contain clues to many unanswered questions surrounding how humans grow and develop. The long lab hours and a two-hour round-trip daily commute from his home in Colchester dont dampen his enthusiasm. Says Thompson: You have to love what you do for a living, and I do.
This article was submitted by Stephen Hamm on April 12, 2017.
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How Medical Research Is Boosting Connecticut's Economy - Yale News
Hairy cell leukemia is an uncommon hematological malignancy characterized by an accumulation of abnormal B lymphocytes. It is usually classified as a sub-type of chronic lymphoid leukemia. Hairy cell leukemia makes up approximately 2% of all leukemias, with fewer than 2,000 new cases diagnosed annually in North America and Western Europe combined.
Hairy cell leukemia was originally described as histiocytic leukemia, malignant reticulosis, or lymphoid myelofibrosis in publications dating back to the 1920s. The disease was formally named leukemic reticuloendotheliosis and its characterization significantly advanced by Bertha Bouroncle and colleagues at The Ohio State University College of Medicine in 1958. Its common name, which was coined in 1966,[1] is derived from the "hairy" appearance of the malignant B cells under a microscope.
In hairy cell leukemia, the "hairy cells" (malignant B lymphocytes) accumulate in the bone marrow, interfering with the production of normal white blood cells, red blood cells, and platelets. Consequently, patients may develop infections related to low white blood cell count, anemia and fatigue due to a lack of red blood cells, or easy bleeding due to a low platelet count.[2] Leukemic cells may gather in the spleen and cause it to swell; this can have the side effect of making the person feel full even when he or she has not eaten much.
Hairy cell leukemia is commonly diagnosed after a routine blood count shows unexpectedly low numbers of one or more kinds of normal blood cells, or after unexplained bruises or recurrent infections in an otherwise apparently healthy patient.
Platelet function may be somewhat impaired in HCL patients, although this does not appear to have any significant practical effect.[3] It may result in somewhat more mild bruises than would otherwise be expected for a given platelet count or a mildly increased bleeding time for a minor cut. It is likely the result of producing slightly abnormal platelets in the overstressed bone marrow tissue.
Patients with a high tumor burden may also have somewhat reduced levels of cholesterol,[4] especially in patients with an enlarged spleen.[5] Cholesterol levels return to more normal values with successful treatment of HCL.
As with many cancers, the cause of hairy cell leukemia is unknown. Exposure to tobacco smoke, ionizing radiation, or industrial chemicals (with the possible exception of diesel) does not appear to increase the risk of developing HCL.[6] Farming and gardening appear to increase the risk of HCL in some studies.[7]
Recent studies have identified somatic BRAF V600E mutations in all patients with the classic form of hairy cell leukemia thus sequenced, but in no patients with the variant form.[8]
The U.S. Institute of Medicine (IOM) announced "sufficient evidence" of an association between exposure to herbicides and later development of chronic B-cell leukemias and lymphomas in general. The IOM report emphasized that neither animal nor human studies indicate an association of herbicides with HCL specifically. However, the IOM extrapolated data from chronic lymphocytic leukemia and non-Hodgkin lymphoma to conclude that HCL and other rare B-cell neoplasms may share this risk factor.[9] As a result of the IOM report, the U.S. Department of Veterans Affairs considers HCL an illness presumed to be a service-related disability (see Agent Orange).
Human T-lymphotropic virus 2 (HTLV-2) has been isolated in a small number of patients with the variant form of HCL.[10] In the 1980s, HTLV-2 was identified in a patient with a T-cell lymphoproliferative disease; this patient later developed hairy cell leukemia (a B cell disease), but HTLV-2 was not found in the hairy cell clones.[11] There is no evidence that HTLV-II causes any sort of hematological malignancy, including HCL.[12]
The diagnosis of HCL may be suggested by abnormal results on a complete blood count (CBC), but additional testing is necessary to confirm the diagnosis. A CBC normally shows low counts for white blood cells, red blood cells, and platelets in HCL patients. However, if large numbers of hairy cells are in the blood stream, then normal or even high lymphocyte counts may be found.
On physical exam, 8090% of patients have an enlarged spleen, which can be massive.[13] This is less likely among patients who are diagnosed at an early stage. Peripheral lymphadenopathy (enlarged lymph nodes) is uncommon (less than 5% of patients), but abdominal lymphadenopathy is a relatively common finding on computed tomography (CT) scans.[13]
The most important lab finding is the presence of hairy cells in the bloodstream.[13] Hairy cells are abnormal white blood cells with hair-like projections of cytoplasm; they can be seen by examining a blood smear or bone marrow biopsy specimen. The blood film examination is done by staining the blood cells with Wright's stain and looking at them under a microscope. Hairy cells are visible in this test in about 85% of cases.[13]
Most patients require a bone marrow biopsy for final diagnosis. The bone marrow biopsy is used both to confirm the presence of HCL and also the absence of any additional diseases, such as Splenic marginal zone lymphoma or B-cell prolymphocytic leukemia. The diagnosis can be confirmed by viewing the cells with a special stain known as TRAP (tartrate resistant acid phosphatase).
It is also possible to definitively diagnose hairy cell leukemia through flow cytometry on blood or bone marrow. The hairy cells are larger than normal and positive for CD19, CD20, CD22, CD11c, CD25, CD103, and FMC7.[14] (CD103, CD22, and CD11c are strongly expressed.)[15]
Hairy cell leukemia-variant (HCL-V), which shares some characteristics with B cell prolymphocytic leukemia (B-PLL), does not show CD25 (also called the Interleukin-2 receptor, alpha). As this is relatively new and expensive technology, its adoption by physicians is not uniform, despite the advantages of comfort, simplicity, and safety for the patient when compared to a bone marrow biopsy. The presence of additional lymphoproliferative diseases is easily checked during a flow cytometry test, where they characteristically show different results.[16]
The differential diagnoses include: several kinds of anemia, including myelophthisis and aplastic anemia,[17] and most kinds of blood neoplasms, including hypoplastic myelodysplastic syndrome, atypical chronic lymphocytic leukemia, B-cell prolymphocytic leukemia, or idiopathic myelofibrosis.[16]
When not further specified, the "classic" form is often implied. However, two variants have been described: Hairy cell leukemia-variant[18] and a Japanese variant. The non-Japanese variant is more difficult to treat than either 'classic' HCL or the Japanese variant HCL.
Hairy cell leukemia-variant, or HCL-V, is usually described as a prolymphocytic variant of hairy cell leukemia.[19] It was first formally described in 1980 by a paper from the University of Cambridge's Hayhoe lab.[20] About 10% of people with HCL have this variant form of the disease, representing about 60-75 new cases of HCL-V each year in the U.S. While classic HCL primarily affects men, HCL-V is more evenly divided between males and females.[21] While the disease can appear at any age, the median age at diagnosis is over 70.[22]
Similar to B-cell prolymphocytic leukemia ("B-PLL") in Chronic lymphocytic leukemia, HCL-V is a more aggressive disease. Historically, it has been considered less likely to be treated successfully than is classic HCL, and remissions have tended to be shorter.
However, the introduction of combination therapy with concurrent rituximab and cladribine therapy has shown excellent results in early follow-up.[23] As of 2016, this therapy is considered the first-line treatment of choice for many people with HCL-V.[24]
Many older treatment approaches, such as Interferon-alpha, the combination chemotherapy regimen "CHOP", and common alkylating agents like cyclophosphamide showed very little benefit.[21] Pentostatin and cladribine administered as monotherapy (without concurrent rituximab) provide some benefit to many people with HCL-V, but typically induce shorter remission periods and lower response rates than when they are used in classic HCL. More than half of people respond partially to splenectomy.[21]
In terms of B-cell development, the prolymphocytes are less developed than are lymphocytes or plasma cells, but are still more mature than their lymphoblastic precursors.
HCL-V differs from classic HCL principally in the following respects:
Low levels of CD25, a part of the receptor for a key immunoregulating hormone, may explain why HCL-V cases are generally much more resistant to treatment by immune system hormones.[19]
HCL-V, which usually features a high proportion of hairy cells without a functional p53 tumor suppressor gene, is somewhat more likely to transform into a higher-grade malignancy. A typical transformation rate of 5%-6% has been postulated in the U.K., similar to the Richter's transformation rate for SLVL and CLL.[21][27] Among HCL-V patients, the most aggressive cases normally have the least amount of p53 gene activity.[28] Hairy cells without the p53 gene tend, over time, to displace the less aggressive p53(+) hairy cells.
There is some evidence suggesting that a rearrangement of the immunoglobulin gene VH4-34, which is found in about 40% of HCL-V patients and 10% of classic HCL patients, may be a more important poor prognostic factor than variant status, with HCL-V patients without the VH4-34 rearrangement responding about as well as classic HCL patients.[29]
Hairy cell leukemia-Japanese variant or HCL-J. There is also a Japanese variant, which is more easily treated.
Treatment with cladribine has been reported.[30]
Pancytopenia in HCL is caused primarily by marrow failure and splenomegaly. Bone marrow failure is caused by the accumulation of hairy cells and reticulin fibrosis in the bone marrow, as well as by the detrimental effects of dysregulated cytokine production.[13] Splenomegaly reduces blood counts through sequestration, marginalization, and destruction of healthy blood cells inside the spleen.[13]
Hairy cells are nearly mature B cells, which are activated clonal cells with signs of VH gene differentiation.[16] They may be related to pre-plasma marginal zone B cells[13] or memory cells.
Cytokine production is disturbed in HCL. Hairy cells produce and thrive on TNF-alpha.[13] This cytokine also suppresses normal production of healthy blood cells in the bone marrow.[13]
Unlike healthy B cells, hairy cells express and secrete an immune system protein called Interleukin-2 receptor (IL-2R).[13] In HCL-V, only part of this receptor is expressed.[13] As a result, disease status can be monitored by measuring changes in the amount of IL-2R in the blood serum.[13] The level increases as hairy cells proliferate, and decreases when they are killed. Although uncommonly used in North America and northern Europe, this test correlates better with disease status and predicts relapse more accurately than any other test.
Hairy cells respond to normal production of some cytokines by T cells with increased growth. Treatment with Interferon-alpha suppresses the production of this pro-growth cytokine from T cells.[13] A low level of T cells, which is commonly seen after treatment with cladribine or pentostatin, and the consequent reduction of these cytokines, is also associated with reduced levels of hairy cells.
In June 2011, E Tiacci et al[31][32] discovered that 100% of hairy-cell leukaemia samples analysed had the oncogenic BRAF mutation V600E, and proposed that this is the disease's driver mutation. Until this point, only a few genomic imbalances had been found in the hairy cells, such as trisomy 5 had been found.[13] The expression of genes is also dysregulated in a complex and specific pattern. The cells underexpress 3p24, 3p21, 3q13.3-q22, 4p16, 11q23, 14q22-q24, 15q21-q22, 15q24-q25, and 17q22-q24 and overexpress 13q31 and Xq13.3-q21.[33] It has not yet been demonstrated that any of these changes have any practical significance to the patient.
Several treatments are available, and successful control of the disease is common.
Not everyone needs treatment. Treatment is usually given when the symptoms of the disease interfere with the patient's everyday life, or when white blood cell or platelet counts decline to dangerously low levels, such as an absolute neutrophil count below one thousand cells per microliter (1.0 K/uL). Not all patients need treatment immediately upon diagnosis, and about 10% of patients will never need treatment.
Treatment delays are less important than in solid tumors. Unlike most cancers, treatment success does not depend on treating the disease at an early stage. Because delays do not affect treatment success, there are no standards for how quickly a patient should receive treatment. However, waiting too long can cause its own problems, such as an infection that might have been avoided by proper treatment to restore immune system function. Also, having a higher number of hairy cells at the time of treatment can make certain side effects somewhat worse, as some side effects are primarily caused by the body's natural response to the dying hairy cells. This can result in the hospitalization of a patient whose treatment would otherwise be carried out entirely at the hematologist's office.
Single-drug treatment is typical. Unlike most cancers, only one drug is normally given to a patient at a time. While monotherapy is normal, combination therapytypically using one first-line therapy and one second-line therapyis being studied in current clinical trials and is used more frequently for refractory cases. Combining rituximab with cladribine or pentostatin may or may not produce any practical benefit to the patient.[34] Combination therapy is almost never used with a new patient. Because the success rates with purine analog monotherapy are already so high, the additional benefit from immediate treatment with a second drug in a treatment-nave patient is assumed to be very low. For example, one round of either cladribine or pentostatin gives the median first-time patient a decade-long remission; the addition of rituximab, which gives the median patient only three or four years, might provide no additional value for this easily treated patient. In a more difficult case, however, the benefit from the first drug may be substantially reduced and therefore a combination may provide some benefit.
Cladribine (2CDA) and pentostatin (DCF) are the two most common first-line therapies. They both belong to a class of medications called purine analogs, which have mild side effects compared to traditional chemotherapy regimens.
Cladribine can be administered by injection under the skin, by infusion over a couple of hours into a vein, or by a pump worn by the patient that provides a slow drip into a vein, 24 hours a day for 7 days. Most patients receive cladribine by IV infusion once a day for five to seven days, but more patients are being given the option of taking this drug once a week for six weeks. The different dosing schedules used with cladribine are approximately equally effective and equally safe.[35] Relatively few patients have significant side effects other than fatigue and a high fever caused by the cancer cells dying, although complications like infection and acute kidney failure have been seen.
Pentostatin is chemically similar to cladribine, and has a similar success rate and side effect profile, but it is always given over a much longer period of time, usually one dose by IV infusion every two weeks for three to six months.
During the weeks following treatment the patient's immune system is severely weakened, but their bone marrow will begin to produce normal blood cells again. Treatment often results in long-term remission. About 85% of patients achieve a complete response from treatment with either cladribine or pentostatin, and another 10% receive some benefit from these drugs, although there is no permanent cure for this disease. If the cancer cells return, the treatment may be repeated and should again result in remission, although the odds of success decline with repeated treatment.[36] Remission lengths vary significantly, from one year to more than twenty years. The median patient can expect a treatment-free interval of about ten years.
It does not seem to matter which drug a patient receives. A patient who is not successfully treated with one of these two drugs has a reduced chance of being successfully treated with the other. However, there are other options.
If a patient is resistant to either cladribine or pentostatin, then second-line therapy is pursued.
Monoclonal antibodies The most common treatment for cladribine-resistant disease is infusing monoclonal antibodies that destroy cancerous B cells. Rituximab is by far the most commonly used. Most patients receive one IV infusion over several hours each week for four to eight weeks. A 2003 publication found two partial and ten complete responses out of 15 patients with relapsed disease, for a total of 80% responding.[37] The median patient (including non-responders) did not require further treatment for more than three years. This eight-dose study had a higher response rate than a four-dose study at Scripps, which achieved only 25% response rate.[38] Rituximab has successfully induced a complete response in Hairy Cell-Variant.[39]
Rituximab's major side effect is serum sickness, commonly described as an "allergic reaction", which can be severe, especially on the first infusion. Serum sickness is primarily caused by the antibodies clumping during infusion and triggering the complement cascade. Although most patients find that side effects are adequately controlled by anti-allergy drugs, some severe, and even fatal, reactions have occurred. Consequently, the first dose is always given in a hospital setting, although subsequent infusions may be given in a physician's office. Remissions are usually shorter than with the preferred first-line drugs, but hematologic remissions of several years' duration are not uncommon.
Other B cell-destroying monoclonal antibodies such as Alemtuzumab, Ibritumomab tiuxetan and I-131 Tositumomab may be considered for refractory cases.
Interferon-alpha Interferon-alpha is an immune system hormone that is very helpful to a relatively small number of patients, and somewhat helpful to most patients. In about 65% of patients,[40] the drug helps stabilize the disease or produce a slow, minor improvement for a partial response.[41]
The typical dosing schedule injects at least 3 million units of Interferon-alpha (not pegylated versions) three times a week, although the original protocol began with six months of daily injections.
Some patients tolerate IFN-alpha very well after the first couple of weeks, while others find that its characteristic flu-like symptoms persist. About 10% of patients develop a level of depression. It is possible that, by maintaining a steadier level of the hormone in the body, that daily injections might cause fewer side effects in selected patients. Drinking at least two liters of water each day, while avoiding caffeine and alcohol, can reduce many of the side effects.
A drop in blood counts is usually seen during the first one to two months of treatment. Most patients find that their blood counts get worse for a few weeks immediately after starting treatment, although some patients find their blood counts begin to improve within just two weeks.[42]
It typically takes six months to figure out whether this therapy is useful. Common criteria for treatment success include:
If it is well tolerated, patients usually take the hormone for 12 to 18 months. An attempt may be made then to end the treatment, but most patients discover that they need to continue taking the drug for it to be successful. These patients often continue taking this drug indefinitely, until either the disease becomes resistant to this hormone, or the body produces an immune system response that limits the drug's ability to function. A few patients are able to achieve a sustained clinical remission after taking this drug for six months to one year. This may be more likely when IFN-alpha has been initiated shortly after another therapy. Interferon-alpha is considered the drug of choice for pregnant women with active HCL, although it carries some risks, such as the potential for decreased blood flow to the placenta.
Interferon-alpha works by sensitizing the hairy cells to the killing effect of the immune system hormone TNF-alpha, whose production it promotes.[43] IFN-alpha works best on classic hairy cells that are not protectively adhered to vitronectin or fibronectin, which suggests that patients who encounter less fibrous tissue in their bone marrow biopsies may be more likely to respond to Interferon-alpha therapy. It also explains why non-adhered hairy cells, such as those in the bloodstream, disappear during IFN-alpha treatment well before reductions are seen in adhered hairy cells, such as those in the bone marrow and spleen.[43]
Splenectomy can produce long-term remissions in patients whose spleens seem to be heavily involved, but its success rate is noticeably lower than cladribine or pentostatin. Splenectomies are also performed for patients whose persistently enlarged spleens cause significant discomfort or in patients whose persistently low platelet counts suggest Idiopathic thrombocytopenic purpura.
Bone marrow transplants are usually shunned in this highly treatable disease because of the inherent risks in the procedure. They may be considered for refractory cases in younger, otherwise healthy individuals. "Mini-transplants" are possible.
Patients with anemia or thrombocytopenia may also receive red blood cells and platelets through blood transfusions. Blood transfusions are always irradiated to remove white blood cells and thereby reduce the risk of graft-versus-host disease. Patients may also receive a hormone to stimulate production of red blood cells. These treatments may be medically necessary, but do not kill the hairy cells.
Patients with low neutrophil counts may be given filgrastim or a similar hormone to stimulate production of white blood cells. However, a 1999 study indicates that routine administration of this expensive injected drug has no practical value for HCL patients after cladribine administration.[44] In this study, patients who received filgrastim were just as likely to experience a high fever and to be admitted to the hospital as those who did not, even though the drug artificially inflated their white blood cell counts. This study leaves open the possibility that filgrastim may still be appropriate for patients who have symptoms of infection, or at times other than shortly after cladribine treatment.
Although hairy cells are technically long-lived, instead of rapidly dividing, some late-stage patients are treated with broad-spectrum chemotherapy agents such as methotrexate that are effective at killing rapidly dividing cells. This is not typically attempted unless all other options have been exhausted and it is typically unsuccessful.
More than 95% of new patients are treated well or at least adequately by cladribine or pentostatin.[45] A majority of new patients can expect a disease-free remission time span of about ten years, or sometimes much longer after taking one of these drugs just once. If re-treatment is necessary in the future, the drugs are normally effective again, although the average length of remission is somewhat shorter in subsequent treatments.
As with B-cell chronic lymphocytic leukemia, mutations in the IGHV on hairy cells are associated with better responses to initial treatments and with prolonged survival.[46]
How soon after treatment a patient feels "normal" again depends on several factors, including:
With appropriate treatment, the overall projected lifespan for patients is normal or near-normal. In all patients, the first two years after diagnosis have the highest risk for fatal outcome; generally, surviving five years predicts good control of the disease. After five years' clinical remission, patients in the United states with normal blood counts can often qualify for private life insurance with some US companies.[47]
Accurately measuring survival for patients with the variant form of the disease (HCL-V) is complicated by the relatively high median age (70 years old) at diagnosis. However, HCL-V patients routinely survive for more than 10 years, and younger patients can likely expect a long life.
Worldwide, approximately 300 HCL patients per year are expected to die.[48] Some of these patients were diagnosed with HCL due to a serious illness that prevented them from receiving initial treatment in time; many others died after living a normal lifespan and experiencing years of good control of the disease. Perhaps as many as five out of six HCL patients die from some other cause.[original research?]
Despite decade-long remissions and years of living very normal lives after treatment, hairy cell leukemia is officially considered an incurable disease. While survivors of solid tumors are commonly declared to be permanently cured after two, three, or five years, people who have hairy cell leukemia are never considered 'cured'. Relapses of HCL have happened even after more than twenty years of continuous remission. Patients will require lifelong monitoring and should be aware that the disease can recur even after decades of good health.
People in remission need regular follow-up examinations after their treatment is over. Most physicians insist on seeing patients at least once a year for the rest of the patient's life, and getting blood counts about twice a year. Regular follow-up care ensures that patients are carefully monitored, any changes in health are discussed, and new or recurrent cancer can be detected and treated as soon as possible. Between regularly scheduled appointments, people who have hairy cell leukemia should report any health problems, especially viral or bacterial infections, as soon as they appear.
HCL patients are also at a slightly higher than average risk for developing a second kind of cancer, such as colon cancer or lung cancer, at some point during their lives (including before their HCL diagnosis). This appears to relate best to the number of hairy cells, and not to different forms of treatment.[49] On average, patients might reasonably expect to have as much as double the risk of developing another cancer, with a peak about two years after HCL diagnosis and falling steadily after that, assuming that the HCL was successfully treated. Aggressive surveillance and prevention efforts are generally warranted, although the lifetime odds of developing a second cancer after HCL diagnosis are still less than 50%.
There is also a higher risk of developing an autoimmune disease.[13] Autoimmune diseases may also go into remission after treatment of HCL.[13]
Because the cause is unknown, no effective preventive measures can be taken.
Because the disease is rare, routine screening is not cost-effective.
This disease is rare, with fewer than 1 in 10,000 people being diagnosed with HCL during their lives. Men are four to five times more likely to develop hairy cell leukemia than women.[50] In the United States, the annual incidence is approximately 3 cases per 1,000,000 men each year, and 0.6 cases per 1,000,000 women each year.[13]
Most patients are white males over the age of 50,[13] although it has been diagnosed in at least one teenager.[51] It is less common in people of African and Asian descent compared to people of European descent.
It does not appear to be hereditary, although occasional familial cases that suggest a predisposition have been reported,[52] usually showing a common Human Leukocyte Antigen (HLA) type.[13]
The Hairy Cell Leukemia Consortium was founded in 2008 to address researchers' concerns about the long-term future of research on the disease.[53] Partly because existing treatments are so successful, the field has attracted very few new researchers.
In 2013 the Hairy Cell Leukemia Foundation was created when the Hairy Cell Leukemia Consortium and the Hairy Cell Leukemia Research Foundation joined together. The HCLF is dedicated to improving outcomes for patients by advancing research into the causes and treatment of hairy cell leukemia, as well as by providing educational resources and comfort to all those affected by hairy cell leukemia.[54]
Three immunotoxin drugs have been studied in patients at the NIHNational Cancer Institute in the U.S.: BL22,[55]HA22[56] and LMB-2.[57] All of these protein-based drugs combine part of an anti-B cell antibody with a bacterial toxin to kill the cells on internalization. BL22 and HA22 attack a common protein called CD22, which is present on hairy cells and healthy B cells. LMB-2 attacks a protein called CD25, which is not present in HCL-variant, so LMB-2 is only useful for patients with HCL-classic or the Japanese variant. HA-22, now renamed moxetumab pasudotox, is being studied in patients with relapsed hairy cell leukemia at the National Cancer Institute in Bethesda, Maryland, MD Anderson Cancer Center in Houston, Texas, and Ohio State University in Columbus, Ohio. Other sites for the study are expected to start accepting patients in late 2014, including The Royal Marsden Hospital in London, England.[58]
Other clinical trials[59] are studying the effectiveness of cladribine followed by rituximab in eliminating residual hairy cells that remain after treatment by cladribine or pentostatin. It is not currently known if the elimination of such residual cells will result in more durable remissions.
BRAF mutation has been frequently detected in HCL (Tiacci et al. NEJM 2011) and some patients may respond to Vemurafenib
The major remaining research questions are identifying the cause of HCL and determining what prevents hairy cells from maturing normally.[60]
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Hairy cell leukemia - Wikipedia
Until the myth of the fountain of youth proves true, regenerative medicine is the best hope weve got for fixing failed body parts and, as a result, living longer. Scientists wont be able to bottle forever. They are, however, working on engineering human cells, tissues, and organs that can repair themselves.
Basically, theyre trying to heal body parts using cells or tissue grown from stem cells, and by prompting regeneration with biologically active drugs that would essentially restart parts by forcing new growth, among other approaches. But its still a speculative venture, say Goldman Sachs analysts in an April 4 report on venture capital going into this novel frontier.
Perfecting processes for regenerating body parts is no mean feat, technically speaking. Plus, there are ethical questions to resolve and regulatory hurdles to overcome. In other words, itll take a while before new parts are available.
Nonetheless, investors are interested in the field, and especially in companies working with stem cells. Goldman analysts believe regenerative medicine is attractive because of its vast potential to eventually cure common and rare diseases in almost any tissue or organ, including the heart, liver, and lungs.
So, moneys going to regenerative medicine, at a rate of hundreds of millions of dollars annually. In 2010, the field attracted about $200 million in venture capital and in 2016, that figure had quadrupled. Stem cell technology attracts the vast majority of investment; $700 million of the $800 million dedicated to regenerative medicine in 2016 went to stem cell projects.
But analysts noted that the number of deals hasnt increased accordingly. Between 2010 and 2016 deals remained in a range of 30 to 40 while investment rose pretty steadily. This suggests that a few companies attracted larger investments per deal over time from venture capital firms.
Companies partnered with science giantslike BlueRock Therapeutics, which works with stem cell pioneer and Nobel laureate Shinya Yamanaka of Kyoto Universityget the largest investments and valuations, according to Goldman Sachs.
Analysts also remarked on Unity Biotechnology, which is developing a technique to eliminate senescent cellsor expiring cellsto increase longevity and maintain youthfulness, and has been shown to work in mice. Senescence is like a biological emergency brake cells use to stop dividing and multiplying out of control. But after the brakes been pulled, the senescent cells remain and accumulate, secreting inflammatory molecules that harm neighboring cells and tissues. Selectively removing them could keep people younger, healthier longer, according to the company.
Scientists seek funding from public sources too, of course. At the University of Washingtons Institute for Stem Cell and Regenerative Medicine, for example, researchers are manipulating stem cells to heal and restore the function in hearts, eyes, kidneys and other tissues, according to Charles Murray, the institutes interim director. In an April 9 editorial in the Seattle Times, he writes, This year, we also seek a first-time investment from our state legislature.
See the article here:
Venture capitalists are betting big on regenerative medicine, but it's ... - Quartz