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Wikipedia

Paclitaxel

February 15, 2024

Paclitaxel, sold under the brand name Taxol among others, is a chemotherapy medication used to treat ovarian cancer, esophageal cancer, breast cancer, lung cancer, Kaposi's sarcoma, cervical cancer, and pancreatic cancer.[4] It is administered by intravenous injection.[4] There is also an albumin-bound formulation.[4]

Paclitaxel
Clinical data
Trade namesTaxol, Abraxane, others
Other namesPTX
AHFS/Drugs.comMonograph
MedlinePlusa607070
License data
Pregnancy
category
Routes of
administration		Intravenous
ATC code
Legal status
Legal status
Pharmacokinetic data
Bioavailability6.5% (by mouth)[3]
Protein binding89 to 98%
MetabolismLiver (CYP2C8 and CYP3A4)
Elimination half-life5.8 hours
ExcretionFecal and urinary
Identifiers
  • (2α,4α,5β,7β,10β,13α)-4,10-Bis(acetyloxy)-13-{[(2R,3S)-3-(benzoylamino)-2-hydroxy-3-phenylpropanoyl]oxy}-1,7-dihydroxy-9-oxo-5,20-epoxytax-11-en-2-yl benzoate
CAS Number
  • 33069-62-4 Y
PubChem CID
  • 36314
IUPHAR/BPS
  • 2770
DrugBank
  • DB01229 Y
ChemSpider
  • 10368587 Y
UNII
  • P88XT4IS4D
KEGG
  • D00491 Y
ChEBI
  • CHEBI:45863 Y
ChEMBL
  • ChEMBL428647 N
PDB ligand
  • TA1 (PDBe, RCSB PDB)
CompTox Dashboard (EPA)
  • DTXSID9023413
ECHA InfoCard100.127.725
Chemical and physical data
FormulaC47H51NO14
Molar mass853.918 g·mol−1
3D model (JSmol)
  • Interactive image
  • CC1=C2[C@@]([C@]([C@H]([C@@H]3[C@]4([C@H](OC4)C[C@@H]([C@]3(C(=O)[C@@H]2OC(=O)C)C)O)OC(=O)C)OC(=O)c5ccccc5)(C[C@@H]1OC(=O)[C@H](O)[C@@H](NC(=O)c6ccccc6)c7ccccc7)O)(C)C
  • InChI=1S/C47H51NO14/c1-25-31(60-43(56)36(52)35(28-16-10-7-11-17-28)48-41(54)29-18-12-8-13-19-29)23-47(57)40(61-42(55)30-20-14-9-15-21-30)38-45(6,32(51)22-33-46(38,24-58-33)62-27(3)50)39(53)37(59-26(2)49)34(25)44(47,4)5/h7-21,31-33,35-38,40,51-52,57H,22-24H2,1-6H3,(H,48,54)/t31-,32-,33+,35-,36+,37+,38-,40-,45+,46-,47+/m0/s1 Y
  • Key:RCINICONZNJXQF-MZXODVADSA-N Y
 NY (what is this?)  (verify)

Common side effects include hair loss, bone marrow suppression, numbness, allergic reactions, muscle pains, and diarrhea.[4] Other side effects include heart problems, increased risk of infection, and lung inflammation.[4] There are concerns that use during pregnancy may cause birth defects.[5][4] Paclitaxel is in the taxane family of medications.[6] It works by interference with the normal function of microtubules during cell division.[4]

Paclitaxel was isolated in 1971 from the Pacific yew and approved for medical use in 1993.[7][8] It is on the World Health Organization's List of Essential Medicines.[9] It has been made from precursors, and more recently through cell culture.[8]

Medical use edit

Paclitaxel is approved in the UK for ovarian, breast, lung, bladder, prostate, melanoma, esophageal, and other types of solid tumor cancers as well as Kaposi's sarcoma.[10]

It is recommended in National Institute for Health and Care Excellence (NICE) guidance of June 2001 for non-small-cell lung cancer in patients unsuitable for curative treatment, and in first-line and second-line treatment of ovarian cancer. In September 2001, NICE recommended paclitaxel for the treatment of advanced breast cancer after the failure of anthracyclic chemotherapy, but that its first-line use should be limited to clinical trials. In September 2006, NICE recommended paclitaxel should not be used in the adjuvant treatment of early node-positive breast cancer.[11]

As of 2018, it is approved in the United States for the treatment of breast, pancreatic, ovarian, Kaposi's sarcoma and non-small-cell lung cancers.[12][13]

Similar compounds edit

Further information: Protein-bound paclitaxel and Docetaxel

Albumin-bound paclitaxel (brand name Abraxane, also called nab-paclitaxel) is an alternative formulation where paclitaxel is bound to albumin nanoparticles. Much of the clinical toxicity of paclitaxel is associated with the solvent Cremophor EL in which it is dissolved for delivery.[14]

Abraxis BioScience developed Abraxane, in which paclitaxel is bonded to albumin as an alternative delivery agent to the often toxic solvent delivery method. This was approved by the FDA in January 2005 for the treatment of breast cancer after failure of combination chemotherapy for metastatic disease or relapse within six months of adjuvant chemotherapy.[15] It has since been approved for locally advanced or metastatic non-small cell lung cancer and metastatic adenocarcinoma of the pancreas as well.[16]

Synthetic approaches to paclitaxel production led to the development of docetaxel. Docetaxel has a similar set of clinical uses to paclitaxel, and it is marketed under the brand name Taxotere.

Taxanes, including paclitaxel, 10-deacetylbaccatin III, baccatin III, paclitaxel C, and 7-epipaclitaxel, have been found in the leaves and shells of hazel.[17] The finding of these compounds in shells, which are considered discarded material and are mass-produced by many food industries, is of interest for the future availability of paclitaxel.[18]

Restenosis edit

Paclitaxel is used as an antiproliferative agent for the prevention of restenosis (recurrent narrowing) of coronary and peripheral stents; locally delivered to the wall of the artery, a paclitaxel coating limits the growth of neointima (scar tissue) within stents.[19] Paclitaxel drug-eluting stents for coronary artery placement are sold under the trade name Taxus by Boston Scientific in the United States. Paclitaxel drug-eluting stents for femoropopliteal artery placement are also available.

Side effects edit

Common side effects include nausea and vomiting, loss of appetite, change in taste, thinned or brittle hair, pain in the joints of the arms or legs lasting two to three days, changes in the color of the nails, and tingling in the hands or toes.[20] More serious side effects such as unusual bruising or bleeding, pain, redness or swelling at the injection site, hand-foot syndrome, change in normal bowel habits for more than two days, fever, chills, cough, sore throat, difficulty swallowing, dizziness, shortness of breath, severe exhaustion, skin rash, facial flushing, female infertility by ovarian damage, and chest pain can also occur.[20] Neuropathy may also occur.[4]

Dexamethasone is given prior to paclitaxel infusion to mitigate some of the side effects.[21]

A number of these side effects are associated with the excipient used, Cremophor EL, a polyoxyethylated castor oil. Allergies to cyclosporine, teniposide, and other drugs delivered in polyoxyethylated castor oil may increase the risk of adverse reactions to paclitaxel.[22]

Mechanism of action edit

 
Complex of α, β tubulin subunits and paclitaxel. Paclitaxel is shown as yellow stick.

Paclitaxel is one of several cytoskeletal drugs that target tubulin. Paclitaxel-treated cells have defects in mitotic spindle assembly, chromosome segregation, and cell division. Unlike other tubulin-targeting drugs, such as colchicine, that inhibit microtubule assembly, paclitaxel stabilizes the microtubule polymer and protects it from disassembly. Chromosomes are thus unable to achieve a metaphase spindle configuration. This blocks the progression of mitosis and prolonged activation of the mitotic checkpoint triggers apoptosis or reversion to the G0-phase of the cell cycle without cell division.[23][24]

The ability of paclitaxel to inhibit spindle function is generally attributed to its suppression of microtubule dynamics,[25] but other studies have demonstrated that suppression of dynamics occurs at concentrations lower than those needed to block mitosis. At the higher therapeutic concentrations, paclitaxel appears to suppress microtubule detachment from centrosomes, a process normally activated during mitosis.[26] Paclitaxel binds to the beta-tubulin subunits of microtubules.[27]

Chemistry edit

The nomenclature for paclitaxel is structured on a tetracyclic 17-atom skeleton. There are a total of 11 stereocenters. The active stereoisomer is (−)-paclitaxel (shown here).

 
Position numbering
 
Absolute stereochemistry
(1S,2S,3R,4S,7R,9S,10S,12R,15S)-4,12-Diacetoxy-15-{[(2R,3S)-3-(benzoylamino)-2-hydroxy-3-phenylpropanoyl]oxy}-1,9-dihydroxy-10,14,17,17-tetramethyl-11-oxo-6-oxatetracyclo[11.3.1.0~3,10~.0~4,7~]heptadec-13-en-2-yl rel-benzoate

Production edit

 
Undisturbed Pacific yew bark contains paclitaxel and related chemicals.

Bark processing edit

 
The bark is peeled and processed to provide paclitaxel.

From 1967 to 1993, almost all paclitaxel produced was derived from bark of the Pacific yew, Taxus brevifolia, the harvesting of which kills the tree in the process.[28] The processes used were descendants of the original isolation method of Monroe Wall and Mansukh Wani; by 1987, the U.S. National Cancer Institute (NCI) had contracted Hauser Chemical Research of Boulder, Colorado, to handle bark on the scale needed for phase II and III trials.[citation needed] While both the size of the wild population of the Pacific yew and the magnitude of the eventual demand for paclitaxel were uncertain, it was clear that an alternative, sustainable source of the natural product would be needed. Initial attempts to broaden its sourcing used needles from the tree, or material from other related Taxus species, including cultivated ones,[citation needed] but these attempts were challenged by the relatively low and often highly variable yields obtained. Early in the 1990s, coincident with increased sensitivity to the ecology of the forests of the Pacific Northwest, paclitaxel was successfully extracted on a clinically useful scale from these sources.[29]

Semisynthesis edit

Concurrently, synthetic chemists in the U.S. and France had been interested in paclitaxel, beginning in the late 1970s.[citation needed] As noted, by 1992 extensive efforts were underway to accomplish the total synthesis of paclitaxel, efforts motivated by the desire to generate new chemical understanding rather than to achieve practical commercial production. In contrast, the French group of Pierre Potier at the Centre national de la recherche scientifique (CNRS) addressed the matter of overall process yield, showing that it was feasible to isolate relatively large quantities of the compound 10-deacetylbaccatin from the European yew, Taxus baccata, which grew on the CNRS campus and whose needles were available in large quantity.[citation needed] By virtue of its structure, 10-deacetylbaccatin was seen as a viable starting material for a short semisynthesis to produce paclitaxel. By 1988, Poitier and collaborators had published a semisynthetic route from needles of the European yew to paclitaxel.[30]

The view of the NCI, however, was that even this route was not practical.[citation needed] The group of Robert A. Holton had also pursued a practical semisynthetic production route; by late 1989, Holton's group had developed a semisynthetic route to paclitaxel with twice the yield of the Potier process.[31] The main innovation was "Ojima−Holton coupling", a ring-opening method independently discovered by Holton and Ojima.[32] Florida State University, where Holton worked, signed a deal with Bristol-Myers Squibb (BMS) to license their semisynthesis and future patents.[citation needed] In 1992, Holton patented an improved process with an 80% yield, and BMS took the process in-house and started to manufacture paclitaxel in Ireland from 10-deacetylbaccatin isolated from the needles of the European yew.[citation needed] In early 1993, BMS announced that it would cease reliance on Pacific yew bark by the end of 1995, effectively terminating ecological controversy over its use.[citation needed] This announcement also made good their commitment to develop an alternative supply route, made to the NCI in their cooperative research and development agreement (CRADA) application of 1989.

As of 2013, BMS was using the semisynthetic method utilizing needles from the European yew to produce paclitaxel.[33] Another company which worked with BMS until 2012,[34] Phyton Biotech, Inc., uses plant cell fermentation (PCF) technology.[35] By cultivating a specific Taxus cell line in fermentation tanks, they no longer need ongoing sourcing of material from actual yew tree plantations.[36] Paclitaxel is then captured directly from the suspension broth by a resin allowing concentration to highly enriched powder containing about 40% paclitaxel. The compound is then purified by one chromatographic step followed by crystallization.[37] Compared to the semisynthesis method, PCF eliminates the need for many hazardous chemicals and saves a considerable amount of energy.[38]

In 1993, paclitaxel was discovered as a natural product in a newly described endophytic fungus living in the yew tree.[39] It has since been reported in a number of other endophytic fungi, including Nodulisporium sylviforme,[citation needed] Alternaria taxi, Cladosporium cladosporioides MD2, Metarhizium anisopliae, Aspergillus candidus MD3, Mucor rouxianus, Chaetomella raphigera, Phyllosticta tabernaemontanae, Phomopsis, Pestalotiopsis pauciseta, Phyllosticta citricarpa, Podocarpus sp., Fusarium solani, Pestalotiopsis terminaliae, Pestalotiopsis breviseta, Botryodiplodia theobromae, Gliocladium sp., Alternaria alternata var. monosporus, Cladosporium cladosporioides, Nigrospora sp., Pestalotiopsis versicolor, and Taxomyces andreanae. However, there has been contradictory evidence for its production by endophytes, with other studies finding independent production is unlikely.[40][41]

Biosynthesis edit

 
Biosynthesis of Taxol

Taxol is a tetracyclic diterpene, and the biosynthesis of diterpenes starts with an FPP molecule being elongated by the addition of an IPP molecule in order to form geranylgeranyl diphosphate (GGPP).[42] The biosynthesis of Taxol contains nineteen steps.[43] These 19 steps can be considered in several steps, with the first step being the formation of the taxane skeleton, which then undergoes a series of oxygenations. Following the oxygenations, two acetylations and a benzoylation occur on the intermediate. The oxygenation of the taxane core is believed to occur on C5 and C10, C2 and C9, C13 followed by C7, and a C1 hydroxylation later on in the pathway. Later in the pathway, an oxidation at C9 forms a ketone functional group and an oxetane, forming the intermediate baccatin III. The final steps of the pathway include the formation of a C13-side chain which is attached to baccatin III.[44] The biosynthesis of Taxol is illustrated in more detail in the figure, with steps 1-7 all occurring in the enzyme taxadiene synthase (TS on the figure). Taxol's biosynthesis begins with E,E,E-GGPP losing pyrophosphate via an SN1 mechanism (step 1 in the figure). The double-bond attacks the cation via electrophilic addition, yielding a tertiary cation and creating the first ring closure (step 2). Another electrophilic attack occurs, further cyclizing the structure by creating the first 6-membered ring and creating another tertiary cation (step 3). An intramolecular proton transfer occurs, attacking the verticillyl cation (step 4) and creating a double bond, yielding a tertiary cation. An electrophilic cyclization occurs in step 5, and an intramolecular proton transfer attacks the taxenyl cation (step 6). This forms the fused ring structure intermediate known as taxadiene. Taxadiene then undergoes a series of 10 oxidations via NADPH, forming the intermediate taxadiene-5α-acetoxy-10β-ol (multiple steps later in the figure). A series of hydroxylations and esterficiations occur, forming the intermediate 10-deacetyl-baccatin III, which undergoes a further series of esterifications and a side-chain hydroxylation.[42] This finally yields the product taxol.

Total synthesis edit

Main article: Paclitaxel total synthesis
 
Paclitaxel, with rings labeled and accepted numbering scheme shown.

By 1992, at least thirty academic research teams globally were working to achieve a total synthesis of this natural product, with the synthesis proceeding from simple natural products and other readily available starting materials.[45] This total synthesis effort was motivated primarily by the desire to generate new chemical understanding, rather than with an expectation of the practical commercial production of paclitaxel. The first laboratories to complete the total synthesis from much less complex starting materials were the research groups of Robert A. Holton, who had the first article to be accepted for publication, and of K. C. Nicolaou who had the first article to appear in print (by a week, on 7 February 1994). Though the Holton submission preceded the Nicolaou by a month (21 December 1993 versus 24 January 1994),[46] the near coincidence of the publications arising from each of these massive, multiyear efforts—11–18 authors appearing on each of the February 1994 publications—has led the ending of the race to be termed a "tie"[47] or a "photo finish",[45] though each group has argued that their synthetic strategy and tactics were superior.[47]

As of 2006, five additional research groups had reported successful total syntheses of paclitaxel: Wender et al. in 1997, and Kuwajima et al. and Mukaiyama et al. in 1998 with further linear syntheses, and Danishefsky et al. in 1996 and Takahashi et al. in 2006 with further convergent syntheses.[needs update] As of that date, all strategies had aimed to prepare a 10-deacetylbaccatin-type core containing the ABCD ring system, followed generally by last stage addition of the "tail" to the 13-hydroxyl group.[45]

While the "political climate surrounding [paclitaxel] and [the Pacific yew] in the early 1990s ... helped bolster [a] link between total synthesis and the [paclitaxel] supply problem," and though total synthesis activities were a requisite to explore the structure-activity relationships of paclitaxel via generation of analogs for testing, the total synthesis efforts were never seen "as a serious commercial route" to provide significant quantities of the natural product for medical testing or therapeutic use.[48]

History edit

The discovery of paclitaxel began in 1962 as a result of a NCI-funded screening program.[8] A number of years later it was isolated from the bark of the Pacific yew, Taxus brevifolia, hence its name "taxol".[8]

The discovery was made by Monroe E. Wall and Mansukh C. Wani at the Research Triangle Institute, Research Triangle Park, North Carolina, in 1971.[49] These scientists isolated the natural product from the bark of the Pacific yew tree, determined its structure and named it "taxol", and arranged for its first biological testing.[50] The compound was then developed commercially by BMS, who had the generic name assigned as "paclitaxel".[citation needed]

Plant screening program edit

In 1955, the NCI in the United States set up the Cancer Chemotherapy National Service Center (CCNSC) to act as a public screening center for anticancer activity in compounds submitted by external institutions and companies.[51] Although the majority of compounds screened were of synthetic origin, one chemist, Jonathan Hartwell, who was employed there from 1958 onwards, had experience with natural product derived compounds, and began a plant screening operation.[52] After some years of informal arrangements, in July 1960, the NCI commissioned the United States Department of Agriculture (USDA) botanists to collect samples from about 1,000 plant species per year.[53] On 21 August 1962, one of those botanists, Arthur S. Barclay, collected bark from a single Pacific yew tree in a forest north of the town of Packwood, Washington, as part of a four-month trip to collect material from over 200 different species. The material was then processed by a number of specialist CCNSC subcontractors, and one of the tree's samples was found to be cytotoxic in a cellular assay on 22 May 1964.[54]

Accordingly, in late 1964 or early 1965, the fractionation and isolation laboratory run by Monroe E. Wall in Research Triangle Park, North Carolina, began work on fresh Taxus samples, isolating the active ingredient in September 1966 and announcing their findings at an April 1967 American Chemical Society meeting in Miami Beach.[55] They named the pure compound taxol in June 1967.[54] Wall and his colleague Wani published their results, including the chemical structure, in 1971.[56]

The NCI continued to commission work to collect more Taxus bark and to isolate increasing quantities of taxol. By 1969, 28 kg (62 lb) of crude extract had been isolated from almost 1,200 kg (2,600 lb) of bark, although this ultimately yielded only 10 g (0.35 oz) of pure material,[57] but for several years, no use was made of the compound by the NCI. In 1975, it was shown to be active in another in vitro system; two years later, a new department head reviewed the data and finally recommended taxol be moved on to the next stage in the discovery process.[58] This required increasing quantities of purified taxol, up to 600 g (21 oz), and in 1977 a further request for 7,000 lb (3,200 kg) of bark was made.

In 1978, two NCI researchers published a report showing taxol was mildly effective in leukaemic mice.[59] In November 1978, taxol was shown to be effective in xenograft studies.[60] Meanwhile, taxol began to be well known in the cell biology, as well as the cancer community, with a publication in early 1979 by Susan B. Horwitz, a molecular pharmacologist at Albert Einstein College of Medicine, showing taxol had a previously unknown mechanism of action involving the stabilization of microtubules. Together with formulation problems, this increased interest from researchers meant that, by 1980, the NCI envisaged needing to collect 20,000 lb (9,100 kg) of bark.[61] Animal toxicology studies were complete by June 1982, and in November NCI applied for the IND necessary to begin clinical trials in humans.[61]

Early clinical trials, supply and the transfer to BMS edit

Phase I clinical trials began in April 1984, and the decision to start Phase II trials was made a year later.[62] These larger trials needed more bark and collection of a further 12,000 pounds was commissioned, which enabled some phase II trials to begin by the end of 1986. But by then it was recognized that the demand for taxol might be substantial and that more than 60,000 pounds of bark might be needed as a minimum. This unprecedentedly large amount brought ecological concerns about the impact on yew populations into focus for the first time, as local politicians and foresters expressed unease at the program.[63]

The first public report from a phase II trial in May 1988 showed promising effects in melanoma and refractory ovarian cancer.[64] At this point, Gordon Cragg of the NCI's Natural Product Branch calculated the synthesis of enough taxol to treat all the ovarian cancer and melanoma cases in the US would require the destruction of 360,000 trees annually. For the first time, serious consideration was given to the problem of supply.[63] Because of the practical and, in particular, the financial scale of the program needed, the NCI decided to seek association with a pharmaceutical company, and in August 1989, it published a Cooperative Research and Development Agreement (CRADA) offering its current stock and supply from current bark stocks, and proprietary access to the data so far collected, to a company willing to commit to providing the funds to collect further raw material, isolate taxol, and fund a large proportion of clinical trials. In the words of Goodman and Welsh, authors of a substantial scholarly book on taxol, "The NCI was thinking, not of collaboration, ... but of a hand-over of taxol (and its problems)".[63]

Although the offer was widely advertised, only four companies responded to the CRADA, including the American firm Bristol-Myers Squibb (BMS), which was selected as the partner in December 1989. The choice of BMS later became controversial and was the subject of Congressional hearings in 1991 and 1992. While it seems clear the NCI had little choice but to seek a commercial partner, there was also controversy about the terms of the deal, eventually leading to a report by the General Accounting Office in 2003, which concluded the NIH had failed to ensure value for money.[65] In related CRADAs with the USDA and Department of the Interior, Bristol-Myers Squibb was given exclusive first refusal on all Federal supplies of Taxus brevifolia. This exclusive contract lead to some criticism for giving BMS a "cancer monopoly".[66] Eighteen months after the CRADA, BMS filed a new drug application (NDA), which was given FDA approval at the very end of 1992. [63] Although there was no patent on the compound, the provisions of the Waxman-Hatch Act gave Bristol-Myers Squibb five years exclusive marketing rights.

In 1990, BMS applied to trademark the name taxol as Taxol(R). This was controversially approved in 1992. At the same time, paclitaxel replaced taxol as the generic (INN) name of the compound. Critics, including the journal Nature, argued the name taxol had been used for more than two decades and in more than 600 scientific articles and suggested the trademark should not have been awarded and the BMS should renounce its rights to it.[67] BMS argued changing the name would cause confusion among oncologists and possibly endanger the health of patients. BMS has continued to defend its rights to the name in the courts.[68] BMS has also been criticized for misrepresentation by Goodman and Walsh, who quote from a company report saying "It was not until 1971 that ... testing ... enabled the isolation of paclitaxel, initially described as 'compound 17".[69] This quote is, strictly speaking, accurate: the objection seems to be that this misleadingly neglects to explain that it was the scientist doing the isolation who named the compound taxol and it was not referred to in any other way for more than twenty years. Annual sales peaked in 2000, reaching US$1.6 billion; paclitaxel is now available in generic form.

Society and culture edit

Legal status edit

Paclitaxel was approved for medical use in the European Union in 2008.[70]

In November 2023, the Committee for Medicinal Products for Human Use of the European Medicines Agency adopted a positive opinion, recommending the granting of a marketing authorization for the medicinal product Naveruclif, intended for the treatment of metastatic breast cancer, metastatic adenocarcinoma of the pancreas and non-small cell lung cancer.[70] The applicant for this medicinal product is Accord Healthcare S.L.U.[70]

Economics edit

As of 2006, the cost to the NHS per patient in early breast cancer, assuming four cycles of treatment, was about £4,000 (approx. $6,000).[71]

Research edit

Caffeine has been speculated to inhibit paclitaxel-induced apoptosis in colorectal cancer cells.[72]

Aside from its direct clinical use, paclitaxel is used extensively in biological and biomedical research as a microtubule stabilizer. In general, in vitro assays involving microtubules, such as motility assays, rely on paclitaxel to maintain microtubule integrity in the absence of the various nucleating factors and other stabilizing elements found in the cell. For example, it is used for in vitro tests of drugs that aim to alter the behavior of microtubule motor proteins, or for studies of mutant motor proteins. Moreover, Paclitaxel has been used in vitro to inhibit insulin fibrillation; in a molar ratio of 10:1 (insulin:paclitaxel), it hindered insulin fibrillation near 70%. Iso-thermal titration calorimetry (ITC) findings indicated a spontaneous tendency of paclitaxel to interact with insulin through hydrogen bonds and van der Waal's forces.[73] Also, the inhibitory role of paclitaxel is attributed to its impact on the colloidal stability of protein solution, as it was observed that paclitaxel inhibited lysozyme fibrillation by inducing the formation of "off-pathway" oligomeric intermediates and increasing the colloidal stability subsequently.[74] Paclitaxel is sometimes used for in vivo studies as well; it can be fed to test organisms, such as fruit flies, or injected into individual cells, to inhibit microtubule disassembly or to increase the number of microtubules in the cell. Paclitaxel induces remyelination in a demyelinating mouse in vivo[75] and inhibits hPAD2 in vitro though its methyl ester side chain.[76] Angiotech Pharmaceuticals Inc. began phase II clinical trials in 1999[77] as a multiple sclerosis treatment but in 2002, reported that the results showed no statistical significance.[78]

In 2016 in vitro multi-drug resistant mouse tumor cells were treated with paclitaxel encased in exosomes. Doses 98% less than common dosing had the same effect. Also, dye-marked exosomes were able to mark tumor cells, potentially aiding in diagnosis.[79][80]

Additional images edit

  •  
    Space-filling model of paclitaxel
  •  
    Rotating paclitaxel molecule model
  •  
    Crystal structure of paclitaxel
  •  
    Total charge surface of taxol. Minimum energy conformation.

References edit

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Further reading edit

  • Jordan G, Vivien W (5 March 2001). The Story of Taxol: Nature and Politics in the Pursuit of an Anti-Cancer Drug. Cambridge University Press. ISBN 978-0-521-56123-5. from the original on 14 January 2023. Retrieved 2 June 2021.

External links edit

February 15, 2024
paclitaxel, sold, under, brand, name, taxol, among, others, chemotherapy, medication, used, treat, ovarian, cancer, esophageal, cancer, breast, cancer, lung, cancer, kaposi, sarcoma, cervical, cancer, pancreatic, cancer, administered, intravenous, injection, t. Paclitaxel sold under the brand name Taxol among others is a chemotherapy medication used to treat ovarian cancer esophageal cancer breast cancer lung cancer Kaposi s sarcoma cervical cancer and pancreatic cancer 4 It is administered by intravenous injection 4 There is also an albumin bound formulation 4 PaclitaxelClinical dataTrade namesTaxol Abraxane othersOther namesPTXAHFS Drugs comMonographMedlinePlusa607070License dataEU EMA by INN US DailyMed PaclitaxelPregnancycategoryAU D 1 Routes ofadministrationIntravenousATC codeL01CD01 WHO Legal statusLegal statusAU S4 Prescription only CA only UK POM Prescription only US WARNING 2 Rx only EU Rx onlyPharmacokinetic dataBioavailability6 5 by mouth 3 Protein binding89 to 98 MetabolismLiver CYP2C8 and CYP3A4 Elimination half life5 8 hoursExcretionFecal and urinaryIdentifiersIUPAC name 2a 4a 5b 7b 10b 13a 4 10 Bis acetyloxy 13 2R 3S 3 benzoylamino 2 hydroxy 3 phenylpropanoyl oxy 1 7 dihydroxy 9 oxo 5 20 epoxytax 11 en 2 yl benzoateCAS Number33069 62 4 YPubChem CID36314IUPHAR BPS2770DrugBankDB01229 YChemSpider10368587 YUNIIP88XT4IS4DKEGGD00491 YChEBICHEBI 45863 YChEMBLChEMBL428647 NPDB ligandTA1 PDBe RCSB PDB CompTox Dashboard EPA DTXSID9023413ECHA InfoCard100 127 725Chemical and physical dataFormulaC 47H 51N O 14Molar mass853 918 g mol 13D model JSmol Interactive imageSMILES CC1 C2 C C C H C H 3 C 4 C H OC4 C C H C 3 C O C H 2OC O C C O OC O C OC O c5ccccc5 C C H 1OC O C H O C H NC O c6ccccc6 c7ccccc7 O C CInChI InChI 1S C47H51NO14 c1 25 31 60 43 56 36 52 35 28 16 10 7 11 17 28 48 41 54 29 18 12 8 13 19 29 23 47 57 40 61 42 55 30 20 14 9 15 21 30 38 45 6 32 51 22 33 46 38 24 58 33 62 27 3 50 39 53 37 59 26 2 49 34 25 44 47 4 5 h7 21 31 33 35 38 40 51 52 57H 22 24H2 1 6H3 H 48 54 t31 32 33 35 36 37 38 40 45 46 47 m0 s1 YKey RCINICONZNJXQF MZXODVADSA N Y N Y what is this verify Common side effects include hair loss bone marrow suppression numbness allergic reactions muscle pains and diarrhea 4 Other side effects include heart problems increased risk of infection and lung inflammation 4 There are concerns that use during pregnancy may cause birth defects 5 4 Paclitaxel is in the taxane family of medications 6 It works by interference with the normal function of microtubules during cell division 4 Paclitaxel was isolated in 1971 from the Pacific yew and approved for medical use in 1993 7 8 It is on the World Health Organization s List of Essential Medicines 9 It has been made from precursors and more recently through cell culture 8 Contents 1 Medical use 1 1 Similar compounds 1 2 Restenosis 2 Side effects 3 Mechanism of action 4 Chemistry 5 Production 5 1 Bark processing 5 2 Semisynthesis 5 3 Biosynthesis 5 4 Total synthesis 6 History 6 1 Plant screening program 6 2 Early clinical trials supply and the transfer to BMS 7 Society and culture 7 1 Legal status 7 2 Economics 8 Research 9 Additional images 10 References 11 Further reading 12 External linksMedical use editPaclitaxel is approved in the UK for ovarian breast lung bladder prostate melanoma esophageal and other types of solid tumor cancers as well as Kaposi s sarcoma 10 It is recommended in National Institute for Health and Care Excellence NICE guidance of June 2001 for non small cell lung cancer in patients unsuitable for curative treatment and in first line and second line treatment of ovarian cancer In September 2001 NICE recommended paclitaxel for the treatment of advanced breast cancer after the failure of anthracyclic chemotherapy but that its first line use should be limited to clinical trials In September 2006 NICE recommended paclitaxel should not be used in the adjuvant treatment of early node positive breast cancer 11 As of 2018 update it is approved in the United States for the treatment of breast pancreatic ovarian Kaposi s sarcoma and non small cell lung cancers 12 13 Similar compounds edit Further information Protein bound paclitaxel and Docetaxel Albumin bound paclitaxel brand name Abraxane also called nab paclitaxel is an alternative formulation where paclitaxel is bound to albumin nanoparticles Much of the clinical toxicity of paclitaxel is associated with the solvent Cremophor EL in which it is dissolved for delivery 14 Abraxis BioScience developed Abraxane in which paclitaxel is bonded to albumin as an alternative delivery agent to the often toxic solvent delivery method This was approved by the FDA in January 2005 for the treatment of breast cancer after failure of combination chemotherapy for metastatic disease or relapse within six months of adjuvant chemotherapy 15 It has since been approved for locally advanced or metastatic non small cell lung cancer and metastatic adenocarcinoma of the pancreas as well 16 Synthetic approaches to paclitaxel production led to the development of docetaxel Docetaxel has a similar set of clinical uses to paclitaxel and it is marketed under the brand name Taxotere Taxanes including paclitaxel 10 deacetylbaccatin III baccatin III paclitaxel C and 7 epipaclitaxel have been found in the leaves and shells of hazel 17 The finding of these compounds in shells which are considered discarded material and are mass produced by many food industries is of interest for the future availability of paclitaxel 18 Restenosis edit Paclitaxel is used as an antiproliferative agent for the prevention of restenosis recurrent narrowing of coronary and peripheral stents locally delivered to the wall of the artery a paclitaxel coating limits the growth of neointima scar tissue within stents 19 Paclitaxel drug eluting stents for coronary artery placement are sold under the trade name Taxus by Boston Scientific in the United States Paclitaxel drug eluting stents for femoropopliteal artery placement are also available Side effects editCommon side effects include nausea and vomiting loss of appetite change in taste thinned or brittle hair pain in the joints of the arms or legs lasting two to three days changes in the color of the nails and tingling in the hands or toes 20 More serious side effects such as unusual bruising or bleeding pain redness or swelling at the injection site hand foot syndrome change in normal bowel habits for more than two days fever chills cough sore throat difficulty swallowing dizziness shortness of breath severe exhaustion skin rash facial flushing female infertility by ovarian damage and chest pain can also occur 20 Neuropathy may also occur 4 Dexamethasone is given prior to paclitaxel infusion to mitigate some of the side effects 21 A number of these side effects are associated with the excipient used Cremophor EL a polyoxyethylated castor oil Allergies to cyclosporine teniposide and other drugs delivered in polyoxyethylated castor oil may increase the risk of adverse reactions to paclitaxel 22 Mechanism of action edit nbsp Complex of a b tubulin subunits and paclitaxel Paclitaxel is shown as yellow stick Paclitaxel is one of several cytoskeletal drugs that target tubulin Paclitaxel treated cells have defects in mitotic spindle assembly chromosome segregation and cell division Unlike other tubulin targeting drugs such as colchicine that inhibit microtubule assembly paclitaxel stabilizes the microtubule polymer and protects it from disassembly Chromosomes are thus unable to achieve a metaphase spindle configuration This blocks the progression of mitosis and prolonged activation of the mitotic checkpoint triggers apoptosis or reversion to the G0 phase of the cell cycle without cell division 23 24 The ability of paclitaxel to inhibit spindle function is generally attributed to its suppression of microtubule dynamics 25 but other studies have demonstrated that suppression of dynamics occurs at concentrations lower than those needed to block mitosis At the higher therapeutic concentrations paclitaxel appears to suppress microtubule detachment from centrosomes a process normally activated during mitosis 26 Paclitaxel binds to the beta tubulin subunits of microtubules 27 Chemistry editThe nomenclature for paclitaxel is structured on a tetracyclic 17 atom skeleton There are a total of 11 stereocenters The active stereoisomer is paclitaxel shown here nbsp Position numbering nbsp Absolute stereochemistry 1S 2S 3R 4S 7R 9S 10S 12R 15S 4 12 Diacetoxy 15 2R 3S 3 benzoylamino 2 hydroxy 3 phenylpropanoyl oxy 1 9 dihydroxy 10 14 17 17 tetramethyl 11 oxo 6 oxatetracyclo 11 3 1 0 3 10 0 4 7 heptadec 13 en 2 yl rel benzoateProduction edit nbsp Undisturbed Pacific yew bark contains paclitaxel and related chemicals Bark processing edit nbsp The bark is peeled and processed to provide paclitaxel From 1967 to 1993 almost all paclitaxel produced was derived from bark of the Pacific yew Taxus brevifolia the harvesting of which kills the tree in the process 28 The processes used were descendants of the original isolation method of Monroe Wall and Mansukh Wani by 1987 the U S National Cancer Institute NCI had contracted Hauser Chemical Research of Boulder Colorado to handle bark on the scale needed for phase II and III trials citation needed While both the size of the wild population of the Pacific yew and the magnitude of the eventual demand for paclitaxel were uncertain it was clear that an alternative sustainable source of the natural product would be needed Initial attempts to broaden its sourcing used needles from the tree or material from other related Taxus species including cultivated ones citation needed but these attempts were challenged by the relatively low and often highly variable yields obtained Early in the 1990s coincident with increased sensitivity to the ecology of the forests of the Pacific Northwest paclitaxel was successfully extracted on a clinically useful scale from these sources 29 Semisynthesis edit Concurrently synthetic chemists in the U S and France had been interested in paclitaxel beginning in the late 1970s citation needed As noted by 1992 extensive efforts were underway to accomplish the total synthesis of paclitaxel efforts motivated by the desire to generate new chemical understanding rather than to achieve practical commercial production In contrast the French group of Pierre Potier at the Centre national de la recherche scientifique CNRS addressed the matter of overall process yield showing that it was feasible to isolate relatively large quantities of the compound 10 deacetylbaccatin from the European yew Taxus baccata which grew on the CNRS campus and whose needles were available in large quantity citation needed By virtue of its structure 10 deacetylbaccatin was seen as a viable starting material for a short semisynthesis to produce paclitaxel By 1988 Poitier and collaborators had published a semisynthetic route from needles of the European yew to paclitaxel 30 The view of the NCI however was that even this route was not practical citation needed The group of Robert A Holton had also pursued a practical semisynthetic production route by late 1989 Holton s group had developed a semisynthetic route to paclitaxel with twice the yield of the Potier process 31 The main innovation was Ojima Holton coupling a ring opening method independently discovered by Holton and Ojima 32 Florida State University where Holton worked signed a deal with Bristol Myers Squibb BMS to license their semisynthesis and future patents citation needed In 1992 Holton patented an improved process with an 80 yield and BMS took the process in house and started to manufacture paclitaxel in Ireland from 10 deacetylbaccatin isolated from the needles of the European yew citation needed In early 1993 BMS announced that it would cease reliance on Pacific yew bark by the end of 1995 effectively terminating ecological controversy over its use citation needed This announcement also made good their commitment to develop an alternative supply route made to the NCI in their cooperative research and development agreement CRADA application of 1989 As of 2013 BMS was using the semisynthetic method utilizing needles from the European yew to produce paclitaxel 33 Another company which worked with BMS until 2012 34 Phyton Biotech Inc uses plant cell fermentation PCF technology 35 By cultivating a specific Taxus cell line in fermentation tanks they no longer need ongoing sourcing of material from actual yew tree plantations 36 Paclitaxel is then captured directly from the suspension broth by a resin allowing concentration to highly enriched powder containing about 40 paclitaxel The compound is then purified by one chromatographic step followed by crystallization 37 Compared to the semisynthesis method PCF eliminates the need for many hazardous chemicals and saves a considerable amount of energy 38 In 1993 paclitaxel was discovered as a natural product in a newly described endophytic fungus living in the yew tree 39 It has since been reported in a number of other endophytic fungi including Nodulisporium sylviforme citation needed Alternaria taxi Cladosporium cladosporioides MD2 Metarhizium anisopliae Aspergillus candidus MD3 Mucor rouxianus Chaetomella raphigera Phyllosticta tabernaemontanae Phomopsis Pestalotiopsis pauciseta Phyllosticta citricarpa Podocarpus sp Fusarium solani Pestalotiopsis terminaliae Pestalotiopsis breviseta Botryodiplodia theobromae Gliocladium sp Alternaria alternata var monosporus Cladosporium cladosporioides Nigrospora sp Pestalotiopsis versicolor and Taxomyces andreanae However there has been contradictory evidence for its production by endophytes with other studies finding independent production is unlikely 40 41 Biosynthesis edit nbsp Biosynthesis of TaxolTaxol is a tetracyclic diterpene and the biosynthesis of diterpenes starts with an FPP molecule being elongated by the addition of an IPP molecule in order to form geranylgeranyl diphosphate GGPP 42 The biosynthesis of Taxol contains nineteen steps 43 These 19 steps can be considered in several steps with the first step being the formation of the taxane skeleton which then undergoes a series of oxygenations Following the oxygenations two acetylations and a benzoylation occur on the intermediate The oxygenation of the taxane core is believed to occur on C5 and C10 C2 and C9 C13 followed by C7 and a C1 hydroxylation later on in the pathway Later in the pathway an oxidation at C9 forms a ketone functional group and an oxetane forming the intermediate baccatin III The final steps of the pathway include the formation of a C13 side chain which is attached to baccatin III 44 The biosynthesis of Taxol is illustrated in more detail in the figure with steps 1 7 all occurring in the enzyme taxadiene synthase TS on the figure Taxol s biosynthesis begins with E E E GGPP losing pyrophosphate via an SN1 mechanism step 1 in the figure The double bond attacks the cation via electrophilic addition yielding a tertiary cation and creating the first ring closure step 2 Another electrophilic attack occurs further cyclizing the structure by creating the first 6 membered ring and creating another tertiary cation step 3 An intramolecular proton transfer occurs attacking the verticillyl cation step 4 and creating a double bond yielding a tertiary cation An electrophilic cyclization occurs in step 5 and an intramolecular proton transfer attacks the taxenyl cation step 6 This forms the fused ring structure intermediate known as taxadiene Taxadiene then undergoes a series of 10 oxidations via NADPH forming the intermediate taxadiene 5a acetoxy 10b ol multiple steps later in the figure A series of hydroxylations and esterficiations occur forming the intermediate 10 deacetyl baccatin III which undergoes a further series of esterifications and a side chain hydroxylation 42 This finally yields the product taxol Total synthesis edit Main article Paclitaxel total synthesis nbsp Paclitaxel with rings labeled and accepted numbering scheme shown By 1992 at least thirty academic research teams globally were working to achieve a total synthesis of this natural product with the synthesis proceeding from simple natural products and other readily available starting materials 45 This total synthesis effort was motivated primarily by the desire to generate new chemical understanding rather than with an expectation of the practical commercial production of paclitaxel The first laboratories to complete the total synthesis from much less complex starting materials were the research groups of Robert A Holton who had the first article to be accepted for publication and of K C Nicolaou who had the first article to appear in print by a week on 7 February 1994 Though the Holton submission preceded the Nicolaou by a month 21 December 1993 versus 24 January 1994 46 the near coincidence of the publications arising from each of these massive multiyear efforts 11 18 authors appearing on each of the February 1994 publications has led the ending of the race to be termed a tie 47 or a photo finish 45 though each group has argued that their synthetic strategy and tactics were superior 47 As of 2006 five additional research groups had reported successful total syntheses of paclitaxel Wender et al in 1997 and Kuwajima et al and Mukaiyama et al in 1998 with further linear syntheses and Danishefsky et al in 1996 and Takahashi et al in 2006 with further convergent syntheses needs update As of that date all strategies had aimed to prepare a 10 deacetylbaccatin type core containing the ABCD ring system followed generally by last stage addition of the tail to the 13 hydroxyl group 45 While the political climate surrounding paclitaxel and the Pacific yew in the early 1990s helped bolster a link between total synthesis and the paclitaxel supply problem and though total synthesis activities were a requisite to explore the structure activity relationships of paclitaxel via generation of analogs for testing the total synthesis efforts were never seen as a serious commercial route to provide significant quantities of the natural product for medical testing or therapeutic use 48 History editThe discovery of paclitaxel began in 1962 as a result of a NCI funded screening program 8 A number of years later it was isolated from the bark of the Pacific yew Taxus brevifolia hence its name taxol 8 The discovery was made by Monroe E Wall and Mansukh C Wani at the Research Triangle Institute Research Triangle Park North Carolina in 1971 49 These scientists isolated the natural product from the bark of the Pacific yew tree determined its structure and named it taxol and arranged for its first biological testing 50 The compound was then developed commercially by BMS who had the generic name assigned as paclitaxel citation needed Plant screening program edit In 1955 the NCI in the United States set up the Cancer Chemotherapy National Service Center CCNSC to act as a public screening center for anticancer activity in compounds submitted by external institutions and companies 51 Although the majority of compounds screened were of synthetic origin one chemist Jonathan Hartwell who was employed there from 1958 onwards had experience with natural product derived compounds and began a plant screening operation 52 After some years of informal arrangements in July 1960 the NCI commissioned the United States Department of Agriculture USDA botanists to collect samples from about 1 000 plant species per year 53 On 21 August 1962 one of those botanists Arthur S Barclay collected bark from a single Pacific yew tree in a forest north of the town of Packwood Washington as part of a four month trip to collect material from over 200 different species The material was then processed by a number of specialist CCNSC subcontractors and one of the tree s samples was found to be cytotoxic in a cellular assay on 22 May 1964 54 Accordingly in late 1964 or early 1965 the fractionation and isolation laboratory run by Monroe E Wall in Research Triangle Park North Carolina began work on fresh Taxus samples isolating the active ingredient in September 1966 and announcing their findings at an April 1967 American Chemical Society meeting in Miami Beach 55 They named the pure compound taxol in June 1967 54 Wall and his colleague Wani published their results including the chemical structure in 1971 56 The NCI continued to commission work to collect more Taxus bark and to isolate increasing quantities of taxol By 1969 28 kg 62 lb of crude extract had been isolated from almost 1 200 kg 2 600 lb of bark although this ultimately yielded only 10 g 0 35 oz of pure material 57 but for several years no use was made of the compound by the NCI In 1975 it was shown to be active in another in vitro system two years later a new department head reviewed the data and finally recommended taxol be moved on to the next stage in the discovery process 58 This required increasing quantities of purified taxol up to 600 g 21 oz and in 1977 a further request for 7 000 lb 3 200 kg of bark was made In 1978 two NCI researchers published a report showing taxol was mildly effective in leukaemic mice 59 In November 1978 taxol was shown to be effective in xenograft studies 60 Meanwhile taxol began to be well known in the cell biology as well as the cancer community with a publication in early 1979 by Susan B Horwitz a molecular pharmacologist at Albert Einstein College of Medicine showing taxol had a previously unknown mechanism of action involving the stabilization of microtubules Together with formulation problems this increased interest from researchers meant that by 1980 the NCI envisaged needing to collect 20 000 lb 9 100 kg of bark 61 Animal toxicology studies were complete by June 1982 and in November NCI applied for the IND necessary to begin clinical trials in humans 61 Early clinical trials supply and the transfer to BMS edit Phase I clinical trials began in April 1984 and the decision to start Phase II trials was made a year later 62 These larger trials needed more bark and collection of a further 12 000 pounds was commissioned which enabled some phase II trials to begin by the end of 1986 But by then it was recognized that the demand for taxol might be substantial and that more than 60 000 pounds of bark might be needed as a minimum This unprecedentedly large amount brought ecological concerns about the impact on yew populations into focus for the first time as local politicians and foresters expressed unease at the program 63 The first public report from a phase II trial in May 1988 showed promising effects in melanoma and refractory ovarian cancer 64 At this point Gordon Cragg of the NCI s Natural Product Branch calculated the synthesis of enough taxol to treat all the ovarian cancer and melanoma cases in the US would require the destruction of 360 000 trees annually For the first time serious consideration was given to the problem of supply 63 Because of the practical and in particular the financial scale of the program needed the NCI decided to seek association with a pharmaceutical company and in August 1989 it published a Cooperative Research and Development Agreement CRADA offering its current stock and supply from current bark stocks and proprietary access to the data so far collected to a company willing to commit to providing the funds to collect further raw material isolate taxol and fund a large proportion of clinical trials In the words of Goodman and Welsh authors of a substantial scholarly book on taxol The NCI was thinking not of collaboration but of a hand over of taxol and its problems 63 Although the offer was widely advertised only four companies responded to the CRADA including the American firm Bristol Myers Squibb BMS which was selected as the partner in December 1989 The choice of BMS later became controversial and was the subject of Congressional hearings in 1991 and 1992 While it seems clear the NCI had little choice but to seek a commercial partner there was also controversy about the terms of the deal eventually leading to a report by the General Accounting Office in 2003 which concluded the NIH had failed to ensure value for money 65 In related CRADAs with the USDA and Department of the Interior Bristol Myers Squibb was given exclusive first refusal on all Federal supplies of Taxus brevifolia This exclusive contract lead to some criticism for giving BMS a cancer monopoly 66 Eighteen months after the CRADA BMS filed a new drug application NDA which was given FDA approval at the very end of 1992 63 Although there was no patent on the compound the provisions of the Waxman Hatch Act gave Bristol Myers Squibb five years exclusive marketing rights In 1990 BMS applied to trademark the name taxol as Taxol R This was controversially approved in 1992 At the same time paclitaxel replaced taxol as the generic INN name of the compound Critics including the journal Nature argued the name taxol had been used for more than two decades and in more than 600 scientific articles and suggested the trademark should not have been awarded and the BMS should renounce its rights to it 67 BMS argued changing the name would cause confusion among oncologists and possibly endanger the health of patients BMS has continued to defend its rights to the name in the courts 68 BMS has also been criticized for misrepresentation by Goodman and Walsh who quote from a company report saying It was not until 1971 that testing enabled the isolation of paclitaxel initially described as compound 17 69 This quote is strictly speaking accurate the objection seems to be that this misleadingly neglects to explain that it was the scientist doing the isolation who named the compound taxol and it was not referred to in any other way for more than twenty years Annual sales peaked in 2000 reaching US 1 6 billion paclitaxel is now available in generic form Society and culture editLegal status edit Paclitaxel was approved for medical use in the European Union in 2008 70 In November 2023 the Committee for Medicinal Products for Human Use of the European Medicines Agency adopted a positive opinion recommending the granting of a marketing authorization for the medicinal product Naveruclif intended for the treatment of metastatic breast cancer metastatic adenocarcinoma of the pancreas and non small cell lung cancer 70 The applicant for this medicinal product is Accord Healthcare S L U 70 Economics edit As of 2006 update the cost to the NHS per patient in early breast cancer assuming four cycles of treatment was about 4 000 approx 6 000 71 Research editThis section may require cleanup to meet Wikipedia s quality standards The specific problem is Huge paragraph needs to be split and sorted Please help improve this section if you can September 2023 Learn how and when to remove this template message Caffeine has been speculated to inhibit paclitaxel induced apoptosis in colorectal cancer cells 72 Aside from its direct clinical use paclitaxel is used extensively in biological and biomedical research as a microtubule stabilizer In general in vitro assays involving microtubules such as motility assays rely on paclitaxel to maintain microtubule integrity in the absence of the various nucleating factors and other stabilizing elements found in the cell For example it is used for in vitro tests of drugs that aim to alter the behavior of microtubule motor proteins or for studies of mutant motor proteins Moreover Paclitaxel has been used in vitro to inhibit insulin fibrillation in a molar ratio of 10 1 insulin paclitaxel it hindered insulin fibrillation near 70 Iso thermal titration calorimetry ITC findings indicated a spontaneous tendency of paclitaxel to interact with insulin through hydrogen bonds and van der Waal s forces 73 Also the inhibitory role of paclitaxel is attributed to its impact on the colloidal stability of protein solution as it was observed that paclitaxel inhibited lysozyme fibrillation by inducing the formation of off pathway oligomeric intermediates and increasing the colloidal stability subsequently 74 Paclitaxel is sometimes used for in vivo studies as well it can be fed to test organisms such as fruit flies or injected into individual cells to inhibit microtubule disassembly or to increase the number of microtubules in the cell Paclitaxel induces remyelination in a demyelinating mouse in vivo 75 and inhibits hPAD2 in vitro though its methyl ester side chain 76 Angiotech Pharmaceuticals Inc began phase II clinical trials in 1999 77 as a multiple sclerosis treatment but in 2002 reported that the results showed no statistical significance 78 In 2016 in vitro multi drug resistant mouse tumor cells were treated with paclitaxel encased in exosomes Doses 98 less than common dosing had the same effect Also dye marked exosomes were able to mark tumor cells potentially aiding in diagnosis 79 80 Additional images edit nbsp Space filling model of paclitaxel nbsp Rotating paclitaxel molecule model nbsp Crystal structure of paclitaxel nbsp Total charge surface of taxol Minimum energy conformation References edit Paclitaxel Use During Pregnancy Drugs com 24 January 2019 Archived from the original on 3 December 2020 Retrieved 19 May 2020 FDA sourced list of all drugs with black box warnings Use Download Full Results and View Query links nctr crs fda gov FDA Retrieved 22 October 2023 Peltier S Oger JM Lagarce F Couet W Benoit JP June 2006 Enhanced oral paclitaxel bioavailability after administration of paclitaxel loaded lipid nanocapsules Pharmaceutical Research 23 6 1243 1250 doi 10 1007 s11095 006 0022 2 PMID 16715372 S2CID 231917 a b c d e f g h Paclitaxel The American Society of Health System Pharmacists Archived from the original on 14 September 2017 Retrieved 2 January 2015 Berveiller P Mir O 2012 Taxanes during pregnancy probably safe but still to be optimized Oncology 83 4 239 240 doi 10 1159 000341820 PMID 22907122 Chang AE Ganz PA Hayes DF Kinsella T Pass HI Schiller JH et al 2007 Oncology An Evidence Based Approach Springer Science amp Business Media p 34 ISBN 9780387310565 Archived from the original on 21 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Wayback Machine on 4 October 2018 Ottaggio L Bestoso F Armirotti A Balbi A Damonte G Mazzei M et al January 2008 Taxanes from Shells and Leaves of Corylus avellana Journal of Natural Products 71 1 58 60 doi 10 1021 np0704046 PMID 18163585 Zhang C Yin G 2022 Safety of paclitaxel coated devices in the femoropopliteal arteries A systematic review and meta analysis PLOS ONE 17 10 e0275888 Bibcode 2022PLoSO 1775888Z doi 10 1371 journal pone 0275888 PMC 9560511 PMID 36227807 Heldman AW Cheng L Jenkins GM Heller PF Kim DW Ware M et al May 2001 Paclitaxel stent coating inhibits neointimal hyperplasia at 4 weeks in a porcine model of coronary restenosis Circulation 103 18 2289 2295 doi 10 1161 01 CIR 103 18 2289 PMID 11342479 a b Abou Donia M 5 February 2015 Mammalian Toxicology John Wiley amp Sons p 626 ISBN 978 1 118 68285 2 Hoskins WJ 2005 Principles and Practice of Gynecologic Oncology Lippincott Williams amp Wilkins p 531 ISBN 978 0 7817 4689 2 Paclitaxel Injection Medline Plus U S National Library of Medicine Archived from the original on 12 February 2010 Bharadwaj R Yu H March 2004 The spindle checkpoint aneuploidy and cancer Oncogene 23 11 2016 2027 doi 10 1038 sj onc 1207374 PMID 15021889 S2CID 11114877 Brito DA Yang Z Rieder CL August 2008 Microtubules do not promote mitotic slippage when the spindle assembly checkpoint cannot be satisfied The Journal of Cell Biology 182 4 623 629 doi 10 1083 jcb 200805072 PMC 2518701 PMID 18710927 Jordan MA Wilson L April 2004 Microtubules as a target for anticancer drugs Nature Reviews Cancer 4 4 253 265 doi 10 1038 nrc1317 PMID 15057285 S2CID 10228718 Ganguly A Yang H Cabral F November 2010 Paclitaxel dependent cell lines reveal a novel drug activity Molecular Cancer Therapeutics 9 11 2914 2923 doi 10 1158 1535 7163 MCT 10 0552 PMC 2978777 PMID 20978163 Lowe J Li H Downing KH Nogales E November 2001 Refined structure of alpha beta tubulin at 3 5 A resolution Journal of Molecular Biology 313 5 1045 1057 doi 10 1006 jmbi 2001 5077 PMID 11700061 Archived from the original on 22 January 2021 Retrieved 29 August 2020 Gersmann H Aldred J 10 November 2011 Medicinal tree used in chemotherapy drug faces extinction The Guardian Archived from the original on 16 February 2017 Retrieved 15 February 2017 Goodman amp Walsh 2001 pp 172 5 sfn error no target CITEREFGoodmanWalsh2001 help Goodman amp Walsh 2001 pp 100 1 sfn error no target CITEREFGoodmanWalsh2001 help Holton RA Biediger RJ Boatman PD 1999 Semisynthesis of taxol and taxotere In Suffness M ed Taxol Science and Applications Boca Raton CRC press pp 97 121 ISBN 978 0 13 873736 8 Ojima I Wang X Jing Y Wang C March 2018 Quest for Efficacious Next Generation Taxoid Anticancer Agents and Their Tumor Targeted Delivery Journal of Natural Products 81 3 703 721 doi 10 1021 acs jnatprod 7b01012 PMC 5869464 PMID 29468872 Paclitaxel Injection USP PDF Injectable Pharmaceuticals Archived from the original PDF on 18 September 2016 Retrieved 22 April 2016 History Archived from the original on 24 May 2016 Retrieved 22 April 2016 Phyton BioTech Paclitaxel Archived from the original on 7 August 2016 Retrieved 22 April 2016 Imseng N Schillberg S Schurch C Schmid D Schutte K Gorr G et al 2014 Suspension Culture of Plant Cells under Heterotrophic Conditions In Meyer HP Schmidhalter D eds Industrial Scale Suspension Culture of Living Cells Wiley Blackwell pp 224 257 ISBN 978 3 527 33547 3 Gilbert Gorr and Roland Franke Commercial Pharmaceutical Production of Complex APIs via Plant Cell Fermentation PCF Technology Presentation at CPhI 2015 13 Oct 2004 Greener Synthetic Pathways Award Bristol Myers Squibb Company Development of a Green Synthesis for TAXOL Manufacture via Plant Cell Fermentation and Extraction Archived from the original on 2 October 2006 Stierle A Strobel G Stierle D April 1993 Taxol and taxane production by Taxomyces andreanae an endophytic fungus of Pacific yew Science 260 5105 214 216 Bibcode 1993Sci 260 214S doi 10 1126 science 8097061 PMID 8097061 Staniek A Woerdenbag HJ Kayser O December 2009 Taxomyces andreanae a presumed paclitaxel producer demystified Planta Medica 75 15 1561 1566 doi 10 1055 s 0029 1186181 PMID 19809969 S2CID 260283080 Heinig U Scholz S Jennewein S 2013 Getting to the bottom of taxol biosynthesis by fungi PDF Fungal Diversity 60 161 170 doi 10 1007 s13225 013 0228 7 S2CID 18642421 Archived PDF from the original on 9 October 2022 a b Dewick PM 6 February 2009 Medicinal Natural Products Chichester UK John Wiley amp Sons Ltd doi 10 1002 9780470742761 ISBN 978 0 470 74276 1 Howat S Park B Oh IS Jin YW Lee EK Loake GJ May 2014 Paclitaxel biosynthesis production and future prospects New Biotechnology 31 3 242 245 doi 10 1016 j nbt 2014 02 010 PMID 24614567 Croteau R Ketchum RE Long RM Kaspera R Wildung MR February 2006 Taxol biosynthesis and molecular genetics Phytochemistry Reviews 5 1 75 97 Bibcode 2006PChRv 5 75C doi 10 1007 s11101 005 3748 2 PMC 2901146 PMID 20622989 a b c Hall N March 2003 Creating complexity the beauty and logic of synthesis Chemical Communications 6 661 664 doi 10 1039 b212248k PMID 12703766 See N Hall ibid See also the American Chemical Society publication Chemical and Engineering News C amp EN 21 February 1994 page 32 and primary citations appearing at Holton and Nicolaou taxol total synthesis articles a b Flam F February 1994 Race to synthesize taxol ends in a tie Science 263 5149 911 Bibcode 1994Sci 263 911F doi 10 1126 science 7906053 PMID 7906053 Goodman amp Walsh 2001 pp 179 182 sfn error no target CITEREFGoodmanWalsh2001 help Wall ME Wani MC February 1995 Camptothecin and taxol discovery to clinic thirteenth Bruce F Cain Memorial Award Lecture Cancer Research 55 4 753 760 PMID 7850785 Archived from the original on 24 November 2016 Donehower RC 1996 The Clinical Development of Paclitaxel A Successful Collaboration of Academia Industry and the National Cancer Institute Stem Cells 14 1 25 28 doi 10 1002 stem 140025 ISSN 1066 5099 PMID 8820947 Goodman amp Walsh 2001 p 17 sfn error no target CITEREFGoodmanWalsh2001 help Goodman amp Walsh 2001 p 22 sfn error no target CITEREFGoodmanWalsh2001 help Goodman amp Walsh 2001 pp 25 28 sfn error no target CITEREFGoodmanWalsh2001 help a b Goodman amp Walsh 2001 p 51 sfn error no target CITEREFGoodmanWalsh2001 help Wall ME Wani MC February 1995 Camptothecin and taxol discovery to clinic thirteenth Bruce F Cain Memorial Award Lecture Cancer Research 55 4 753 760 PMID 7850785 Wani MC Taylor HL Wall ME Coggon P McPhail AT May 1971 Plant antitumor agents VI The isolation and structure of taxol a novel antileukemic and antitumor agent from Taxus brevifolia Journal of the American Chemical Society 93 9 2325 2327 doi 10 1021 ja00738a045 PMID 5553076 Goodman amp Walsh 2001 p 81 sfn error no target CITEREFGoodmanWalsh2001 help Goodman amp Walsh 2001 pp 79 81 sfn error no target CITEREFGoodmanWalsh2001 help Fuchs DA Johnson RK August 1978 Cytologic evidence that taxol an antineoplastic agent from Taxus brevifolia acts as a mitotic spindle poison Cancer Treatment Reports 62 8 1219 1222 PMID 688258 Goodman amp Walsh 2001 p 95 sfn error no target CITEREFGoodmanWalsh2001 help a b Goodman amp Walsh 2001 p 97harvnb error no target CITEREFGoodmanWalsh2001 help Goodman amp Walsh 2001 p 115 sfn error no target CITEREFGoodmanWalsh2001 help a b c d Goodman amp Walsh 2001 p 120harvnb error no target CITEREFGoodmanWalsh2001 help Rowinsky EK Donehower RC Rosenshein NB Ettinger DS McGuire WP 1988 Phase II study of taxol in advanced epithelial malignancies Proceedings of the Association of Clinical Oncology 7 136 Technology Transfer NIH Private Sector Partnership in the Development of Taxol PDF Archived from the original PDF on 26 July 2007 Retrieved 17 July 2016 Nader R Love J February 1993 Looting the medicine chest how Bristol Myers Squibb made off with the public s cancer research The Progressive Archived from the original on 24 September 2004 Names for hi jacking Nature 373 6513 370 February 1995 Bibcode 1995Natur 373 370 doi 10 1038 373370a0 PMID 7830775 S2CID 31510966 Goodman amp Walsh 2001 p 170 sfn error no target CITEREFGoodmanWalsh2001 help Bristol Myers Squibb The development of TAXOL paclitaxel March 1997 as cited in Goodman amp Walsh 2001 p 2harvnb error no target CITEREFGoodmanWalsh2001 help a b c Naveruclif EPAR European Medicines Agency EMA 9 November 2023 Retrieved 28 December 2023 Text was copied from this source which is copyright European Medicines Agency Reproduction is authorized provided the source is acknowledged NICE Guidance TA108 27 September 2006 Archived from the original on 30 June 2007 Mhaidat NM Alzoubi KH Al Azzam SI Alsaad AA January 2014 Caffeine inhibits paclitaxel induced apoptosis in colorectal cancer cells through the upregulation of Mcl 1 levels Molecular Medicine Reports 9 1 243 248 doi 10 3892 mmr 2013 1763 PMID 24173825 Archived from the original on 22 June 2015 Kachooei E Moosavi Movahedi AA Khodagholi F Mozaffarian F Sadeghi P Hadi Alijanvand H et al June 2014 Inhibition study on insulin fibrillation and cytotoxicity by paclitaxel Journal of Biochemistry 155 6 361 373 doi 10 1093 jb mvu012 PMID 24535601 Kachooei E Mozaffarian F Khodagholi F Sadeghi P Karami L Ghasemi A et al May 2018 Paclitaxel inhibited lysozyme fibrillation by increasing colloidal stability through formation of off pathway oligomers International Journal of Biological Macromolecules 111 870 879 doi 10 1016 j ijbiomac 2018 01 072 PMID 29352977 Moscarello MA Mak B Nguyen TA Wood DD Mastronardi F Ludwin SK April 2002 Paclitaxel Taxol attenuates clinical disease in a spontaneously demyelinating transgenic mouse and induces remyelination Multiple Sclerosis 8 2 130 138 doi 10 1191 1352458502ms776oa PMID 11990870 S2CID 45994154 Musse AA Polverini E Raijmakers R Harauz G October 2008 Kinetics of human peptidylarginine deiminase 2 hPAD2 reduction of Ca2 dependence by phospholipids and assessment of proposed inhibition by paclitaxel side chains Biochemistry and Cell Biology 86 5 437 447 doi 10 1139 o08 124 PMID 18923545 MS Society of Canada Phase II Clinical trial of Micellar Paclitaxel for secondary progressive MS underway in Canada Archived 15 March 2012 at the Wayback Machine MS Society of Canada Angiotech Halts Study of Micellar Paclitaxel stating no benefit of statistical significance seen Archived 15 March 2012 at the Wayback Machine Lavars N 14 January 2016 Cloaking chemo drugs in cellular bubbles destroys cancer with one fiftieth of a regular dose www gizmag com Archived from the original on 24 February 2016 Retrieved 14 February 2016 Kim MS Haney MJ Zhao Y Mahajan V Deygen I Klyachko NL et al April 2016 Development of exosome encapsulated paclitaxel to overcome MDR in cancer cells Nanomedicine 12 3 655 664 doi 10 1016 j nano 2015 10 012 PMC 4809755 PMID 26586551 Further reading editJordan G Vivien W 5 March 2001 The Story of Taxol Nature and Politics in the Pursuit of an Anti Cancer Drug Cambridge University Press ISBN 978 0 521 56123 5 Archived from the original on 14 January 2023 Retrieved 2 June 2021 External links edit Paclitaxel National Cancer Institute 5 October 2006 Paclitaxel NCI Drug Dictionary 2 February 2011 Molecule of the Month TAXOL by Neil Edwards University of Bristol A Tale of Taxol from Florida State University Berenson A 1 October 2006 Hope at 4 200 a Dose The New York Times Retrieved 31 March 2007 Portal nbsp Medicine Retrieved from https en wikipedia org w index php title Paclitaxel amp oldid 1199824409, wikipedia, wiki, book, books, library,

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