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monoclonal antibody

 
Dictionary: monoclonal antibody
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n.
Any of the highly specific antibodies produced in large quantity by the clones of a single hybrid cell formed in the laboratory by the fusion of a B cell with a tumor cell.


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Oncology Encyclopedia: Monoclonal Antibodies
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Definition

Monoclonal antibodies are proteins produced in the laboratory from a single clone of a B cell, the type of cells of the immune system that make antibodies.

Description

Antibodies, also known as immunoglobulins (Igs), are proteins that help identify foreign substances to the immune system, such as a bacteria or a virus. Antibodies work by binding to the foreign substance to mark it as foreign. The substance that the antibody binds to is called an antigen. All monoclonal antibodies of a particular type bind to the same antigen, which distinguishes them from polyclonal antibodies.

The structure of most antibodies can be divided into two parts: the section that binds the antigen and a section that identifies the type of antibody. This second region is called a constant region, because it is essentially the same within the same type of antibody. The most common type of antibody is IgG (immunoglobulin gamma), which is found in the blood and body fluids. For cancer treatments, monoclonal antibodies are often humanized. This involves using human sequences for the constant regions and using mouse or other animal-derived sequence for the binding region. Humanization reduces the immune reaction of the patient to the anti-body itself.

When used as a treatment for cancer, there are three general strategies with monoclonal antibodies. One uses the ability of the antibodies to bind to the cancer cells having the tumor antigens on their surface. The immune system will see the cancer cells marked with bound antibodies as foreign and destroy them. A second strategy is to use the antibodies to block the binding of cytokines or other proteins that are needed by the cancerous cells to maintain their uncontrolled growth. Monoclonal antibodies designed to work like this bind to the receptors for the cytokine that are on the tumor cell surface. As doctors don't completely understand how monoclonal antibodies work as drugs, both strategies may help rid the body of the tumor cells.

A final strategy involves special antibodies that are linked (conjugated) to a substance that is deadly to the cancer cells. Both radioactive isotopes, like yttrium 90, and toxins produced by bacteria, like pseudomonas exotoxin, have been successfully conjugated to antibodies. The antibodies are then used to specifically destroy the tumor cells with the radioactivity or toxic substance. The use of monoclonal antibodies is a useful approach to cancer therapy and as scientists learn more about the function of the immune system and cancer, new antibodies and new strategies promise to become more and more effective.

—Michelle Johnson, M.S., J.D.

Sci-Tech Encyclopedia: Monoclonal antibodies
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Antibody proteins that bind to a specific target molecule (antigen) at one specific site (antigenic site). In response to either infection of immunization with a foreign agent, the immune system generates many different antibodies that bind to the foreign molecules. Individual antibodies within this polyclonal antibody pool bind to specific sites on a target molecule known as epitopes. Isolation of an individual antibody within the polyclonal antibody pool would allow biochemical and biological characterization of a highly specific molecular entity targeting only a single epitope. Realization of the therapeutic potential of such specificity launched research into the development of methods to isolate and continuously generate a supply of a single lineage of antibody, a monoclonal antibody (mAb).

In 1974, W. Köhler and C. Milstein developed a process for the generation of monoclonal antibodies. In their process, fusion of an individual B cell (or B lymphocyte), which produces an antibody with a single specificity but has a finite life span, with a myeloma (B cell tumor) cell, which can be grown indefinitely in culture, results in a hybridoma cell. This hybridoma retains desirable characteristics of both parental cells, producing an antibody of a single specificity that can grow in culture indefinitely.

Generation of monoclonal antibodies through the hybridoma process worked well with B cells from rodents but not with B cells from humans. Consequently, the majority of the first monoclonal antibodies were from mice. When administered into humans as therapeutic agents in experimental tests, the human immune system recognized the mouse monoclonal antibodies as foreign agents, causing an immune response, which was sometimes severe. Although encouraging improvements in disease were sometimes seen, this response made murine (mouse) antibodies unacceptable for use in humans with a functional immune system.

Fueled by advances in molecular biology and genetic engineering in the late 1980s, efforts to engineer new generations of monoclonal antibodies with reduced human immunogenicity have come to fruition. Today there are a number of clonal antibodies approved for human therapeutic use in the United States.

Characterization of the structure of antibodies and their genes laid the foundation for antibody engineering. In most mammals, each antibody is composed of two different polypeptides, the immunoglobulin heavy chain (IgH) and the immunoglobulin light chain (IgL). Comparison of the protein sequences of either heavy of light antibody chain reveals a portion that typically varies from one antibody to the next, the variable region, and a portion that is conserved, the constant region. A heavy and a light chain are folded together in an antibody to align their respective variable and constant regions. The unique shape of the cofolded heavy- and light-chain variable domains creates the variable domain of the antibody, which fits around the shape of the target epitope and confers the binding specificity of the antibody.

Mice genetically engineered to produce fully human antibodies allow the use of established hybridoma technology to generate fully human antibodies directly, without the need for additional engineering. These transgenic mice contain a large portion of human DNA encoding the antibody heavy and light chains. Inactivation of the mouse's own heavy- and light-chain genes forces the mouse to use the human genes to make antibodies. Current versions of these mice generate a diverse polyclonal antibody response, thereby enabling the generation and recovery of optimal monoclonal antibodies using hybridoma technology.

Disease areas that currently are especially amenable to antibody-based treatments include cancer, immune dysregulation, and infection. Depending upon the disease and the biology of the target, therapeutic monoclonal antibodies can have different mechanisms of action. A therapeutic monoclonal antibody may bind and neutralize the normal function of a target. For example, a monoclonal antibody that blocks the activity of the of protein needed for the survival of a cancer cell causes the cell's death. Another therapeutic monoclonal antibody may bind and activate the normal function of a target. For example, a monoclonal antibody can bind to a protein on a cell and trigger an apoptosis signal. Finally, if a monoclonal antibody binds to a target expressed only on diseased tissue, conjugation of a toxic payload (effective agent), such as a chemotherapeutic or radioactive agent, to the monoclonal antibody can create a guided missile for specific delivery of the toxic payload to the diseased tissue, reducing harm to healthy tissue. See also Antibody; Antigen; Genetic engineering; Immunology.

Dental Dictionary: monoclonal antibody
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n

Produced by a clone or genetically homogeneous population of hybrid cells.

 
Columbia Encyclopedia: monoclonal antibody
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monoclonal antibody, an antibody that is mass produced in the laboratory from a single clone and that recognizes only one antigen. Monoclonal antibodies are typically made by fusing a normally short-lived, antibody-producing B cell (see immunity) to a fast-growing cell, such as a cancer cell (sometimes referred to as an "immortal" cell). The resulting hybrid cell, or hybridoma, multiplies rapidly, creating a clone that produces large quantities of the antibody.

Monoclonal antibodies engendered much excitement in the medical world and in the financial world in the 1980s, especially as potential cures for cancer. They have been used in laboratory research and in medical tests since the mid-1970s, but their effectiveness in disease treatment has been limited. By the mid-1990s, however, some of the technical problems had been overcome. Experimental cancer therapies have used drugs, radioactive materials, or immune killer cells attached to monoclonal antibodies that, when injected into patients, home in on antigens that grow only on the surface of cancer cells.

Science Q&A: What are monoclonal antibodies?
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Monoclonal antibodies are artificially produced antibodies designed to neutralize a specific foreign protein (antigen). Cloned cells (genetically identical) are stimulated to produce antibodies to the target antigen. Most monoclonal antibody work so far has used cloned cells from mice infected with cancer. In some cases they are used to destroy cancer cells directly; in others they carry other drugs to combat the cancer cells.

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Essay: Monoclonal antibodies
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The human immune system is complex, but one of the most easily accessible parts is a group of chemicals called antibodies that circulate in the bloodstream. Antibodies are the key to the success of vaccination. Injection of a vaccine stimulates a kind of white blood cell (lymphocyte) called a B cell to produce antibodies against proteins in the vaccine. Such antibodies home in on specific foreign proteins so that they can be destroyed. Vaccination confers long-lasting immunity because the B cells that have been stimulated to produce the antibodies reproduce, and the B-cell line remains in the bloodstream, prepared to produce antibodies against a reinvasion of the specific protein. The same process, of course, happens naturally in response to infection.

The key to antibody action is that a line of antibodies that bind to one kind of protein or other molecule -- called the antigen -- is very specific. Normally, antibodies in a given line do not bind to any molecules except that antigen, although sometimes antibodies can be fooled by a protein that closely resembles the antigen in some way; this can result in autoimmune diseases such as type I diabetes or rheumatoid arthritis.

In 1975 César Milstein and Georges Köhler developed in England a method of producing large amounts of antibodies specific to a given antigen by a cloning technique. Antigens from human cells are injected into a mouse. Some B cells in the mouse start producing antibodies that attack the antigen. B cells are then removed from the mouse and fused with cancerous mouse B cells, forming hybrid cells called hybridomas that live and reproduce indefinitely. (B cells alone soon die out.) The hybridomas continue to produce large amounts of antibodies of various types. Probes based on the original antigen are used to pick out a hybridoma that produces a specific desired antibody; this cell is separated from the others and encouraged to reproduce in large quantities. Antibodies from such a cell line are called monoclonal because they are produced from the clones of a single hybridoma. All of the monoclonal antibodies from a single B cell react with the chosen antigen.

The original mouse-produced antibodies sometimes caused undesired immune reactions when injected into a human. The problem is that human immune systems view mouse proteins as foreign. More recently, scientists have used human cells to make the hybridomas, reducing such unwanted reactions when monoclonal antibodies are injected into humans.

Just like natural antibodies, monoclonal antibodies track down proteins or other chemicals with exquisite specificity. Thus, they can be used in diagnosis of such diseases as muscular dystrophy, one of the first applications. By combining a monoclonal antibody with a poison, cells that have a given protein on their surface can be tracked down by the antibody and destroyed. This has been successful against some types of cancer, especially certain breast cancers and leukemias. Antibodies are also used to prevent organ rejection and to inhibit clogging of arteries. Although the concepts involved date from the mid-1970s, practical applications were slow to develop. But by the early 21st century, several drugs based on monoclonal antibodies had become routinely used.

Wikipedia: Monoclonal antibodies
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A general representation of the methods used to produce monoclonal antibodies.

Monoclonal antibodies (mAb or moAb) are monospecific antibodies that are identical because they are produced by one type of immune cell that are all clones of a single parent cell. Given almost any substance, it is possible to create monoclonal antibodies that specifically bind to that substance; they can then serve to detect or purify that substance. This has become an important tool in biochemistry, molecular biology and medicine. When used as medications, the non-proprietary drug name ends in -mab (see "Nomenclature of monoclonal antibodies").

Contents

Discovery

The idea of a "magic bullet" was first proposed by Paul Ehrlich who at the beginning of the 20th century postulated that if a compound could be made that selectively targeted a disease-causing organism, then a toxin for that organism could be delivered along with the agent of selectivity.

In the 1970s the B-cell cancer multiple myeloma was known, and it was understood that these cancerous B-cells all produce a single type of antibody (a paraprotein). This was used to study the structure of antibodies, but it was not yet possible to produce identical antibodies specific to a given antigen.

A process of producing monoclonal antibodies involving human-mouse hybrid cells was described by Jerrold Schwaber in 1973[1] and remains widely cited among those using human-derived hybridomas,[2] but claims to priority have been controversial. A science history paper on the subject gave some credit to Schwaber for inventing a technique that was widely cited, but stopped short of suggesting that he had been cheated.[3] The invention is generally accredited to Georges Köhler, César Milstein, and Niels Kaj Jerne in 1975;[4] who shared the Nobel Prize in Physiology or Medicine in 1984 for the discovery. The key idea was to use a line of myeloma cells that had lost their ability to secrete antibodies, come up with a technique to fuse these cells with healthy antibody-producing B-cells, and be able to select for the successfully fused cells.

In 1988 Greg Winter and his team pioneered the techniques to humanize monoclonal antibodies,[5] removing the reactions that many monoclonal antibodies caused in some patients.

Production

Researchers looking at slides of cultures of cells that make monoclonal antibodies. These are grown in a lab and the researchers are analyzing the products to select the most promising of them.
Monoclonal antibodies can be grown in unlimited quantities in the bottles shown in this picture.
Technician hand-filling wells with a liquid for a research test. This test involves preparation of cultures in which hybrids are grown in large quantities to produce desired antibody. This is effected by fusing myeloma cell and mouse lymphocyte to form a hybrid cell (hybridoma).
Lab technician bathing prepared slides in a solution. This technician prepares slides of monoclonal antibodies for researchers. The cells shown are labeling human breast cancer.

Hybridoma cell production

Monoclonal antibodies are typically made by fusing myeloma cells with the spleen cells from a mouse that has been immunized with the desired antigen. However, recent advances have allowed the use of rabbit B-cells. Polyethylene glycol is used to fuse adjacent plasma membranes, but the success rate is low so a selective medium is used in which only fused cells can grow. This is because myeloma cells have lost the ability to synthesize hypoxanthine-guanine-phosphoribosyl transferase (HGPRT), an enzyme necessary for the salvage synthesis of nucleic acids. The absence of HGPRT is not a problem for these cells unles the de novo purine synthesis pathway is also disrupted. By exposing cells to Aminopterin (a folic acid analogue, which inhibits Dihydrofolate reductase, DHFR), they are unable to use the de novo pathway and become fully auxotrophic for nucleic acids requiring supplementation to survive.

The selective culture medium is called HAT medium because it contains Hypoxanthine, Aminopterin, and Thymidine. This medium is selective for fused (hybridoma) cells. Unfused myeloma cells cannot grow because they lack HGPRT, and thus cannot replicate their DNA. Unfused spleen cells cannot grow indefinitely because of their limited life span. Only fused hybrid cells, referred to as hybridomas, are able to grow indefinitely in the media because the spleen cell partner supplies HGPRT and the myeloma partner has traits that make it immortal (as it is a cancer cell).

This mixture of cells is then diluted and clones are grown from single parent cells on microtitre wells. The antibodies secreted by the different clones are then assayed for their ability to bind to the antigen (with a test such as ELISA or Antigen Microarray Assay) or immuno-dot blot. The most productive and stable clone is then selected for future use.

The hybridomas can be grown indefinitely in a suitable cell culture media, or they can be injected in mice (in the peritoneal cavity, the gut), they produce tumors containing an antibody-rich fluid called ascites fluid. The medium must be enriched during selection to further favour hybridoma growth. This can be achieved by the use of a layer of feeder fibrocyte cells or supplement medium such as briclone. Production in cell culture is usually preferred as the ascites technique is painful to the animal and if replacement techniques exist, this method is considered unethical.

Purification of monoclonal antibodies

After obtaining either a media sample of cultured hybridomas or a sample of ascites fluid, the desired antibodies must be extracted. The contaminants in the cell culture sample would consist primarily of media components such as growth factors, hormones, and transferrins. In contrast, the in vivo sample is likely to have host antibodies, proteases, nucleases, nucleic acids, and viruses. In both cases, other secretions by the hybridomas such as cytokines may be present. There may also be bacterial contamination and, as a result, endotoxins which are secreted by the bacteria. Depending on the complexity of the media required in cell culture, and thus the contaminants in question, one method (in vivo or in vitro) may be preferable to the other.

The sample is first conditioned, or prepared for purification. Cells, cell debris, lipids, and clotted material are first removed, typically by filtration with a 0.45 µm filter. These large particles can cause a phenomenon called membrane fouling in later purification steps. Additionally, the concentration of product in the sample may not be sufficient, especially in cases where the desired antibody is one produced by a low-secreting cell line. The sample is therefore condensed by ultrafiltration or dialysis.

Most of the charged impurities are usually anions such as nucleic acids and endotoxins. These are often separated by ion exchange chromatography. Either cation exchange chromatography is used at a low enough pH that the desired antibody binds to the column while anions flow through, or anion exchange chromatography is used at a high enough pH that the desired antibody flows through the column while anions bind to it. Various proteins can also be separated out along with the anions based on their isoelectric point (pI). For example, albumin has a pI of 4.8, which is significantly lower than that of most monoclonal antibodies, which have a pI of 6.1. In other words, at a given pH, the average charge of albumin molecules is likely to be more negative. Transferrin, on the other hand, has a pI of 5.9, so it cannot easily be separated out by this method. A difference in pI of at least 1 is necessary for a good separation.

Transferrin can instead be removed by size exclusion chromatography. The advantage of this purification method is that it is one of the more reliable chromatography techniques. Since we are dealing with proteins, properties such as charge and affinity are not consistent and vary with pH as molecules are protonated and deprotonated, while size stays relatively constant. Nonetheless, it has drawbacks such as low resolution, low capacity and low elution times.

A much quicker, single-step method of separation is Protein A/G affinity chromatography. The antibody selectively binds to Protein A/G, so a high level of purity (generally >80%) is obtained. However, this method may be problematic for antibodies that are easily damaged, as harsh conditions are generally used. A low pH can break the bonds to remove the antibody from the column. In addition to possibly affecting the product, low pH can cause Protein A/G itself to leak off the column and appear in the eluted sample. Gentle elution buffer systems that employ high salt concentrations are also available to avoid exposing sensitive antibodies to low pH. Cost is also an important consideration with this method because immobilized Protein A/G is a more expensive resin.

To achieve maximum purity in a single step, affinity purification can be performed, using the antigen to provide exquisite specificity for the antibody. In this method, the antigen used to generate the antibody is covalently attached to an agarose support. If the antigen is a peptide, it is commonly synthesized with a terminal cysteine which allows selective attachment to a carrier protein, such as KLH during development and to the support for purification. The antibody-containing media is then incubated with the immobilized antigen, either in batch or as the antibody is passed through a column, where it selectively binds and can be retained while impurities are washed away. An elution with a low pH buffer or a more gentle, high salt elution buffer is then used to recover purified antibody from the support.

To further select for antibodies, the antibodies can be precipitated out using sodium sulfate or ammonium sulfate. Antibodies precipitate at low concentrations of the salt, while most other proteins precipitate at higher concentrations. The appropriate level of salt is added in order to achieve the best separation. Excess salt must then be removed by a desalting method such as dialysis.

The final purity can be analyzed using a chromatogram. Any impurities will produce peaks, and the volume under the peak indicates the amount of the impurity. Alternatively, gel electrophoresis and capillary electrophoresis can be carried out. Impurities will produce bands of varying intensity, depending on how much of the impurity is present.

Recombinant

The production of recombinant monoclonal antibodies involves technologies, referred to as repertoire cloning or phage display/yeast display. Recombinant antibody engineering involves the use of viruses or yeast to create antibodies, rather than mice. These techniques rely on rapid cloning of immunoglobulin gene segments to create libraries of antibodies with slightly different amino acid sequences from which antibodies with desired specificities can be selected.[6] These techniques can be used to enhance the specificity with which antibodies recognize antigens, their stability in various environmental conditions, their therapeutic efficacy, and their detectability in diagnostic applications.[7] Fermentation chambers have been used to produce these antibodies on a large scale.

Applications

Diagnostic tests

Once monoclonal antibodies for a given substance have been produced, they can be used to detect the presence of this substance. The Western blot test and immuno dot blot tests detect the protein on a membrane. They are also very useful in immunohistochemistry which detect antigen in fixed tissue sections and immunofluorescence test which detect the substance in a frozen tissue section or in live cells.

Monoclonal antibodies for cancer treatment

Main article: Monoclonal antibody therapy

One possible treatment for cancer involves monoclonal antibodies that bind only to cancer cell-specific antigens and induce an immunological response against the target cancer cell. Such mAb could also be modified for delivery of a toxin, radioisotope, cytokine or other active conjugate; it is also possible to design bispecific antibodies that can bind with their Fab regions both to target antigen and to a conjugate or effector cell. In fact, every intact antibody can bind to cell receptors or other proteins with its Fc region.

Monoclonal antibodies for cancer. ADEPT, antibody directed enzyme prodrug therapy; ADCC, antibody dependent cell-mediated cytotoxicity; CDC, complement dependent cytotoxicity; MAb, monoclonal antibody; scFv, single-chain Fv fragment.[8]

The illustration below shows all these possibilities:

MAbs approved by the FDA include[9]

Chimeric and humanized antibodies

Main article: humanized antibody

One problem in medical applications is that the standard procedure of producing monoclonal antibodies yields mouse antibodies. Although murine antibodies are very similar to human ones there are differences. The human immune system hence recognizes mouse antibodies as foreign, rapidly removing them from circulation and causing systemic inflammatory effects. Such responses are recognised as producing HACA (Human Anti-Chimeric) antibody antibodies or HAMA (Human Anti-Mouse) antibodies.

A solution to this problem would be to generate human antibodies directly from humans. However, this is not easy, primarily because it is generally not seen as ethical to challenge humans with antigen in order to produce antibody; the ethics of doing the same to non-humans is a matter of debate. Furthermore, it is not easy to generate human antibodies against human tissues.

Various approaches using recombinant DNA technology to overcome this problem have been tried since the late 1980s. In one approach, one takes the DNA that encodes the binding portion of monoclonal mouse antibodies and merges it with human antibody-producing DNA. One then uses mammalian cell cultures to express this DNA and produce these half-mouse and half-human antibodies. (Bacteria cannot be used for this purpose, since they cannot produce this kind of glycoprotein.) Depending on how big a part of the mouse antibody is used, one talks about chimeric antibodies or humanized antibodies.

'Fully' Human Monoclonal Antibodies

Ever since the discovery that monoclonal antibodies could be generated in-vitro, scientists have targeted the creation of 'fully' human antibodies to avoid some of the side effects of humanised and chimeric antibodies. Two successful approaches were identified - phage display-generated antibodies and mice genetically engineered to produce more human-like antibodies.

One of the most successful commercial organisations behind therapeutic monoclonal antibodies was Cambridge Antibody Technology (CAT). Scientists at CAT demonstrated that phage display could be used such that variable antibody domains could be expressed on filamentous phage antibodies. This was reported in a key Nature publication[10].

Other significant publications include:

  • D. Marks, H.R. Hoogenboom, T.P. Bonnert, J. McCafferty, A.D. Griffiths and G. Winter (1991) "By-passing immunisation. Human antibodies from V-gene libraries displayed on phage." J.Mol.Biol., 222, 581-597.
  • S. Carmen and L. Jermutus, "Concepts in antibody phage display". Briefings in Functional Genomics and Proteomics 2002 1(2):189-203[11]

CAT developed their display technologies further into several, patented antibody discovery/functional genomics tools which were named ProximolTM[12] and ProAbTM. ProAb was announced in December 1997[13] and involved highthroughput screening of antibody libraries against diseased and non-diseased tissue, whilst Proximol used a free radical enzymatic reaction to label molecules in proximity to a given protein[14][15].

Genetically engineered mice, so called transgenic mice, can be modified to produce human antibodies[16], and this has been exploited by a number of commercial organisations:

  • Medarex - who market their UltiMab platform[17]
  • Abgenix - who marketed their Xenomouse technology. Abgenix were acquired in April 2006 by Amgen[18].
  • Regeneron's VelocImmune technology[19].

Monoclonal antibodies have been generated and approved to treat: cancer, cardiovascular disease, inflammatory diseases, macular degeneration, transplant rejection, multiple sclerosis, and viral infection (see monoclonal antibody therapy).

In August 2006 the Pharmaceutical Research and Manufacturers of America reported that U.S. companies had 160 different monoclonal antibodies in clinical trials or awaiting approval by the Food and Drug Administration.[20]

Examples

Monoclonal antibodies[21]
Type Application Mechanism Mode
infliximab inhibits TNF-α chimeric
basiliximab inhibits IL-2 on activated T cells chimeric
bevacizumab inhibits VEGF humanized
abciximab inhibits the receptor GpIIb/IIIa on platelets chimeric
daclizumab inhibits IL-2 on activated T cells humanized
gemtuzumab targets an antigen on leukemia cells humanized
alemtuzumab targets an antigen CD52 on T- and B-lymphocytes humanized
rituximab targets phosphoprotein CD20 on B lymphocytes chimeric
palivizumab
  • RSV infections in children
 inhibits an RSV protein humanized
trastuzumab
  • anti-cancer therapy for a specific kind of breast cancer
 targets the HER2/neu (erbB2) receptor humanized
etanercept contains TNF receptor fusion protein
adalimumab inhibits TNF-α human
nimotuzumab
  • Approved in SCCHN, Glioma
  • Clinical trials for other indications underway
 EGFR inhibitor Humanized

See also

References

  1. ^ Schwaber, J and Cohen, E. P., "Human x Mouse Somatic Cell Hybrid Clones Secreting Immunoglobulins of Both Parental Types," Nature, 244 (1973), 444--447.
  2. ^ Science Citation Index
  3. ^ Alberto Cambrosio Peter Keating, Journal of the History of Biology. Between fact and technique: The beginnings of hybridoma technology, Volume 25,Issue 2,175- 230.[1]
  4. ^ Kohler G, Milstein C. Continuous cultures of fused cells secreting antibody of predefined specificity. Nature 1975;256:495-7. PMID 1172191. doi:10.1038/256495a0 Reproduced in J Immunol 2005;174:2453-5. PMID 15728446.
  5. ^ Riechmann L, Clark M, Waldmann H, Winter G. Reshaping human antibodies for therapy. Nature 1988;332:323-7. PMID 3127726.
  6. ^ Siegel DL (2002). "Recombinant monoclonal antibody technology". Transfusion clinique et biologique : journal de la Société française de transfusion sanguine 9 (1): 15–22. PMID 11889896. 
  7. ^ Schmitz U, Versmold A, Kaufmann P, Frank HG (2000). "Phage display: a molecular tool for the generation of antibodies--a review". Placenta 21 Suppl A: S106–12. doi:10.1053/plac.1999.0511. PMID 10831134. 
  8. ^ Modified from Carter P: Improving the efficacy of antibody-based cancer therapies. Nat Rev Cancer 2001;1:118-129
  9. ^ Takimoto CH, Calvo E. "Principles of Oncologic Pharmacotherapy" in Pazdur R, Wagman LD, Camphausen KA, Hoskins WJ (Eds) Cancer Management: A Multidisciplinary Approach. 11 ed. 2008.
  10. ^ http://www.nature.com/nature/journal/v348/n6301/abs/348552a0.html
  11. ^ http://bfgp.oxfordjournals.org/cgi/content/abstract/1/2/189
  12. ^ http://www.ncbi.nlm.nih.gov/pubmed/11968489
  13. ^ http://www.ukbusinesspark.co.uk/cay92125.htm
  14. ^ http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6T76-3WBNNJS-6&_user=10&_rdoc=1&_fmt=&_orig=search&_sort=d&_docanchor=&view=c&_searchStrId=960781456&_rerunOrigin=google&_acct=C000050221&_version=1&_urlVersion=0&_userid=10&md5=eacedcd4604792172fc18143a590a454
  15. ^ http://www.chidb.com/newsarticles/issue3_1.ASP
  16. ^ http://www.ncbi.nlm.nih.gov/pubmed/7494109
  17. ^ http://www.medarex.com/Development/UltiMAb.htm
  18. ^ http://wwwext.amgen.com/media/media_pr_detail.jsp?year=2006&releaseID=837754
  19. ^ http://www.regeneron.com/velocimmune.html
  20. ^ PhRMA Reports Identifies More than 400 Biotech Drugs in Development. Pharmaceutical Technology, August 24, 2006. Retrieved 2006-09-04.
  21. ^ Rang, H. P. (2003). Pharmacology. Edinburgh: Churchill Livingstone. pp. 241, for the examples infliximab, basiliximab, abciximab, daclizumab, palivusamab, palivusamab, gemtuzumab, alemtuzumab, etanercept and rituximab, and mechanism and mode. ISBN 0-443-07145-4. 
  • Olson, Wayne P. Separations Technology: Pharmaceutical and Biotechnology Applications. Buffalo Grove, IL: Interpharm Press, Inc., 1995.
  • Shepherd, Philip. Christopher Dean. Monoclonal Antibodies. New York: Oxford University Press, 2000.

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