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Dabrafenib

Q: What are some common usage challenges or considerations with Dabrafenib?

One key consideration with Dabrafenib is the potential for development of drug resistance over time. Some patients may experience a reduced response to the medication as their cancer cells adapt. Additionally, Dabrafenib can have side effects like fever, fatigue, and skin rashes that require monitoring and management by healthcare providers.

Q: Are there different variations or types of Dabrafenib that patients may receive?

Dabrafenib is typically administered as an oral capsule. There is curently only one approved formulation of the drug, though researchers are exploring potential combianations with other targeted therapies or immuno-oncology agents to enhance its efficacy.

Q: In what specific cancer types and applications is Dabrafenib used?

Dabrafenib is primarily used to treat metastatic or unresectable melanoma with a BRAF V600E or V600K mutation. It is also approved for the treatment of certain types of advanced thyroid cancer. Researchers are investigating its potential use in other BRAF-mutant cancers as well, such as non-small cell lung cancer and colorectal cancer.

Dabrafenib is a targeted therapy used to treat certain types of cancer, including melanoma and thyroid cancer.
It works by blocking a specific mutation in the BRAF gene, which can drive tumor growth.
PubCompare.ai leverages AI to optimize Dabrafenib research by identifying the best protocols and products across literature, pre-prints, and patents.
This allows researchers to locate and evalulate Dabrafenib-related information with unparalleled reproducibility and accuaracy, enhancing the research workflow.
PubCompare.ai's AI-driven comparisons provide a concise, informative overview of Dabrafenib and its uses in cancer treatment.

Most cited protocols related to «Dabrafenib»

Economic Evaluation of Atezolizumab + Bevacizumab for Hepatocellular Carcinoma

Cited 8 times

Only direct medical costs, including costs of acquiring drugs, costs attributed to the patient’s health state, costs for the management of adverse events (AEs), and costs for end-of-life care, were analyzed (Table 1). The costs are reported in 2019 US dollars and were inflated to 2019 values using the Medical-Care Inflation data set in Tom’s Inflation Calculator.¹⁶According to the IMbrave150 trial report,^{5 (link)} patients in the atezolizumab plus bevacizumab group received atezolizumab (1200 mg) plus bevacizumab (15 mg/kg body weight) intravenously every 3 weeks. Patients assigned to the sorafenib group received sorafenib (400 mg) orally twice daily. Treatment continued until disease progression or unacceptable toxicity or, for the immunotherapy regimen group, until 2 years of follow-up. The prices of atezolizumab, bevacizumab, and sorafenib were collected from public databases.^{12 ,13} In the US, the prices of ipilimumab, nivolumab, pembrolizumab, and dabrafenib plus trametinib were discounted by 17% to account for contract pricing.^{17 (link)} To calculate the dosage of bevacizumab, we assumed that a typical patient in the US weighed 71.4 kg.^{18 (link)} After disease progression, 69 of 197 patients (35.0%) in the atezolizumab plus bevacizumab group and 73 of 109 patients (67.0%) in the sorafenib group received subsequent active therapy. The costs associated with subsequent active salvage therapy and the greatest supportive care were $108 336 and $37 084 per patient, respectively, which were estimated from a cost-effectiveness analysis of second-line treatments of advanced HCC.^{14 (link)} The monitoring costs for patients with PFD and patients with PD were $245 per month and $15 308 per month, respectively, which were collected from an economic evaluation of sorafenib for unresectable HCC.^{15 (link)} The cost associated with terminal care was $7893 per patient with advanced HCC.^{14 (link)} The analysis included the costs associated with managing grade 3 or higher AEs, which were extracted from the literature (eTable 3 in the Supplement).^{14 (link),19 (link)}Each health state was assigned a health utility preference on a scale of 0 (death) to 1 (perfect health). The PFD and PD states associated with HCC were 0.76 and 0.68,^{10 (link)} respectively, which were derived from a cost-effectiveness analysis considering patients with HCC. The disutility values due to grade 1 or 2 and grade 3 or 4 AEs were included in this analysis.^{11 (link)} All AEs were assumed to be incurred during the first cycle. The duration-adjusted disutility was subtracted from the baseline PFD utility.

Su D., Wu B, & Shi L. (2021). Cost-effectiveness of Atezolizumab Plus Bevacizumab vs Sorafenib as First-Line Treatment of Unresectable Hepatocellular Carcinoma. JAMA Network Open, 4(2), e210037.

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Publication 2021

atezolizumab Bevacizumab Body Weight dabrafenib Dietary Supplements Disease Progression Hospice Care Immunotherapy Ipilimumab Nivolumab Patient Monitoring Patients pembrolizumab Salvage Therapy Sorafenib Terminal Care trametinib Treatment Protocols

Personalized Matching Score for Targeted Therapies

Cited 8 times

An exploratory scoring system (“Matching Score”) was
developed, as previously described.^{6 (link),9 (link)} The Matching
Score was calculated post hoc by investigators blinded to outcomes at the time
and it was based upon the actual drugs administered. Under this system, the
higher the Matching Score, the better the match. In general, the Matching Score
was calculated by dividing the number of alterations matched in each patient
(numerator) by the number of characterized aberrations in that patient’s
tumor (denominator). For instance, if a patient’s tumor harboring six
genomic aberrations received two drugs that targeted three of the
patient’s genomic alterations, the Matching Score would be 3/6 or 50%.
This is because certain drugs targeted more than one alteration (e.g., many
small molecule inhibitors often have activity against multiple kinases) and were
counted as matches for each identified genomic alteration that was matched.
Other considerations were as follows:

two mutations in the same gene that had the same effect
(e.g., loss of function) counted as one aberration in the
denominator; two mutations in the same gene that were known to
function differently counted twice.

two different structural alterations in the same gene (e.g.,
amplification and mutation) were counted as two aberrations in the
denominator since they have different functional effects (e.g.,
overexpression versus activation);

two drugs targeting the same alteration were counted twice
in both the numerator and denominator if they had well-established
synergy (e.g. the FDA-approved combinations of dabrafenib and
trametinib for BRAF mutations, or pertuzumab and
trastuzumab ERBB2 alterations);

only if the patient was matched (in part) based on hormone
(ER) positivity in the tissue biopsied for genomic analysis, the ER
status was then added to both the numerator and the denominator;

all variants of unknown significance were excluded;

in the case of cell cycle inhibitors that targeted CDK4/6,
we counted any concomitant CDK4/6 and
CDKN2A/B alterations (N=2 patients) or
CCND1/2/3 and CDKN2A/Balterations (N=2 patients) as one alteration and one drug target in
the numerator and denominator, because the CDKN2A protein,
p16(INK4a), directly binds to the CDK4/CDK6/Cyclin D1 complex, thus
regulating their activity.^{39 (link),40 (link)}

TP53 alterations were considered matched to
anti-angiogenic agents, based on data showing that
TP53 mutations are associated with upregulation
of VEGF-A and that treatment of TP53-mutant tumors
with anti-angiogenic agents is associated with improved
outcomes.^{27 (link),28 ,41 (link),42 (link)}

if the patient was treated with immunotherapy (e.g.,
anti-PD-1 or anti-PD-L1 checkpoint inhibitors), the Matching Score
was 100% for PD-L1 IHC high positive, TMB high, MSI high results (or
MHL1, MSH2,
MSH6, PMS2 alterations), or if
none of the aforementioned were known, but the patient had ≥8
genomic alterations (N=1 patient) based upon the assumption of a
high TMB.

if PD-L1 IHC was low positive, the TMB was intermediate, or
there was a CD274 (PD-L1) amplification, the
Matching Score was 50%; if the patient received a combination of a
checkpoint inhibitor and a gene-targeted drug that matched one or
more of his/her genomic alterations, the score was >50%. As
an example, if a patient had intermediate TMB and a
MET amplification, as well as a
TP53 mutation, and was treated with nivolumab
and the MET inhibitor, crizotinib, the Matching Score would be
>50%.

if more than one NGS report was available, the alterations
in each report were counted (since there can be heterogeneity
between tissue biopsies);

if a patient’s regimen included drugs that did not
match any alteration, those drugs received a Matching Score of
0.

The cut-off of 50% for the analyses of low versus high Matching Scores
was chosen according to the minimum P-value criteria.^{19 (link)} See Supplemental Text for selected
examples of therapy and Matching Score methodology.

Sicklick J.K., Kato S., Okamura R., Schwaederle M., Hahn M.E., Williams C.B., De P., Krie A., Piccioni D.E., Miller V.A., Ross J.S., Benson A., Webster J., Stephens P.J., Lee J.J., Fanta P.T., Lippman S.M., Leyland-Jones B, & Kurzrock R. (2019). Molecular profiling of cancer patients enables personalized combination therapy: the I-PREDICT study. Nature medicine, 25(5), 744-750.

Publication 2019

angiogen Angiogenesis Inhibitors Biopsy BRAF protein, human CD274 protein, human CDK6 protein, human CDKN2A Gene Cell Cycle Cell Cycle Checkpoints Crizotinib Cyclin-Dependent Kinase Inhibitor p16 Cyclin D1 dabrafenib Drug Delivery Systems ERBB2 protein, human Genes Genome Hormones Immunotherapy inhibitors MSH6 protein, human Mutation Neoplasms Patients PD-L1 Inhibitors pertuzumab Pharmaceutical Preparations Phosphotransferases PMS2 protein, human Therapeutics Tissues TP53 protein, human Treatment Protocols Vascular Endothelial Growth Factors

Phase I Trial of Dabrafenib for BRAF-Mutant Cancers

Cited 6 times

Protocol full text hidden due to copyright restrictions

Open the protocol to access the free full text link

Publication 2012

BRAF protein, human Brain Metastases dabrafenib Disease Progression Drug Kinetics Melanoma Neoplasms Patients Safety Titrimetry

Comprehensive Anticancer Drug Sourcing

Cited 6 times

Sodium valproate was from Sigma (St. Louis, MO). Neratinib was supplied by Puma Biotechnology Inc. (Los Angeles, CA). Sorafenib tosylate, dasatinib, ruxolitinib, dabrafenib, trametinib and sildenafil were from Selleckchem (Houston TX). Trypsin-EDTA, DMEM, RPMI, penicillin-streptomycin were purchased from GIBCOBRL (GIBCOBRL Life Technologies, Grand Island, NY). All “H” series NSCLC lines were purchased from the ATCC and were not further validated beyond that claimed by ATCC. Cells were re-purchased every ~6 months. ADOR cells were a gift to the Dent lab from a female NSCLC patient. Spiky ovarian cancer cells were kindly provided by Dr. Karen Paz (Champions Oncology, NJ). Commercially available validated short hairpin RNA molecules to knock down RNA / protein levels were from Qiagen (Valencia, CA) (Supplementary Figure 24). Control IgG, anti-PD-1 and anti-CTLA4 endotoxin-free antibodies were purchased from Bio-X cell (West Lebanon, NH). Reagents and performance of experimental procedures were described in refs: 1, 24-28, 45, 46.

Booth L., Roberts J.L., Poklepovic A., Avogadri-Connors F., Cutler R.E., Lalani A.S, & Dent P. (2017). HDAC inhibitors enhance neratinib activity and when combined enhance the actions of an anti-PD-1 immunomodulatory antibody in vivo. Oncotarget, 8(52), 90262-90277.

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Publication 2017

anti-endotoxin antibodies Cells Cytotoxic T-Lymphocyte Antigen 4 dabrafenib Dasatinib Edetic Acid Neoplasms neratinib Non-Small Cell Lung Carcinoma Ovarian Cancer Patients Penicillins Proteins Puma ruxolitinib Short Hairpin RNA Sildenafil Sodium Valproate Sorafenib Streptomycin trametinib Trypsin Woman

Optimized Tissue Digestion Protocol

Cited 6 times

See supplementary information for this section.

Jung B., Kang H., Lee W., Noh H.J., Kim Y.S., Han M.S., Baek M.C., Kim J, & Bae J.S. (2016). Anti-septic effects of dabrafenib on HMGB1-mediated inflammatory responses. BMB Reports, 49(4), 214-219.

Publication 2016

Most recents protocols related to «Dabrafenib»

Establishment of Dabrafenib-Insensitive HT-29 Cells

Barcoded HT-29 cells frozen and thawed for the establishment of dabrafenib-insensitive counterparts. A total of 5 × 10⁶ barcoded HT-29 cells were thawed and seeded into a 15 cm tissue culture dish. Following the cells reaching the confluency, they were trypsinized and well-mixed before seeding equal number of cells (2 × 10⁶ cells) per new 15 cm dishes. A total of 4 dishes that are namely DMSO Control, Replica A, B, and C was formed. As an initial time-point, frozen cell stocks and cell pellets from 2 × 10⁶ cells in each were collected. Harvesting used medium through the experiment was performed at monthly intervals. Barcoded HT-29 cell line replicates A, B, and C were treated with 2XIC50 (199.6 nM) of dabrafenib concentration for the duration of 3 months.

Baygin R.C., Yilmaz K.C, & Acar A. (2024). Characterization of dabrafenib-induced drug insensitivity via cellular barcoding and collateral sensitivity to second-line therapeutics. Scientific Reports, 14, 286.

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Publication 2024

Expanded Access Protocol for Dabrafenib and Trametinib in BRAF V600E-Mutated Thyroid Cancer

Not available on PMC !

The MAP of dabrafenib plus trametinib initiated on February 2, 2021, to enable early access to dabrafenib plus trametinib in patients with BRAF V600E -mutated PTC or anaplastic transformation who were unable to participate in clinical studies. We retrospectively analyzed the efficacy and safety of dabrafenib plus trametinib in patients with BRAF V600Emutated PTC or anaplastic transformation enrolled in the MAP of dabrafenib plus trametinib at Samsung Medical Center, Korea. We included patients aged 18 years or older with a symptomatic disease that had progressed less than 12 months before treatment. There were no limitations on the quantity or type of prior systemic treatments. Patients who received dabrafenib plus trametinib before the initiation of MAP were also included.
The patient received an initial dose of dabrafenib 150 mg twice daily and trametinib 2 mg once daily. The patients were treated with dabrafenib plus trametinib for 28 days until disease progression, unacceptable toxicity, withdrawal of consent, or death. Dose reduction and temporary interruption were permitted based on the physician's judgment.
Baseline neck and chest contrast computed tomography were performed within 4 weeks before starting the first dose of dabrafenib plus trametinib. Disease progression was assessed using the Response Evaluation Criteria in Solid Tumors (RECIST) ver. 1.1. Treatment-related adverse events were graded using the Common Terminology Criteria for Adverse Events (CTCAE) ver. 5.0. The baseline characteristics, treatment history, efficacy, and safety outcomes were evaluated.
We evaluated progression-free survival (PFS), the investigator-assessed objective response rate (ORR), overall survival (OS), and safety profiles.
PFS was defined as the time from the first dose of dabrafenib plus trametinib to the first occurrence of disease progression or death. Patients who had not experienced treatment discontinuation at the analysis cutoff date were censored at the analysis cutoff date. The investigator-assessed ORR per RECIST ver. 1.1. ORR was defined as the proportion of patients with a confirmed complete response and partial response (PR) according to RECIST ver. 1.1. The OS is the time between the start of dabrafenib plus trametinib treatment and the occurrence of death from any cause. We censored patients who were alive at the time of the last data cutoff and the last follow-up.

Jeon Y., Park S., Lee S.H., Kim T.H., Kim S.W., Ahn M.J., Jung H.A, & Chung J.H. (2024). Combination of Dabrafenib and Trametinib in Patients with Metastatic BRAFV600E-Mutated Thyroid Cancer. Cancer research and treatment.

Publication 2024

Dabrafenib-insensitive HT-29 Cell Proliferation

Dabrafenib-insensitive HT-29, DMSO controls, and initial cell populations were seeded into separate 96 well plates at 10 × 10³ cells per well. After 24 h, DMSO control HT-29 cells and dabrafenib-insensitive HT-29 cells were treated with DMSO and dabrafenib, respectively, while the initial control cells were given full fresh growth medium. After 24 h, 48 h, and 72 h in the incubator, the cells were fixed, stained with crystal violet and destained with 20% acetic acid. Finally, absorbance values were measured at 570 nm using a microplate spectrophotometer (Multiskan GO; Thermo Fisher Scientific, USA). Cell proliferation rates were calculated using GraphPad Prism 8 and absorbance values (GraphPad Software Inc., USA).

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Publication 2024

Scratch Assay for Cell Migration

The scratch assay was used to examine the migration of drug-insensitive, DMSO-control, and dabrafenib-insensitive HT-29 cell lines. A 24-well plate containing growth was seeded with an equal number of cells per cell line group (4 × 10⁵/well). After the cells had reached approximately 80% confluence, they were treated for 2 h with 2 g/ml Mitomycin (Serva, VWR International). Scratches were created with a 200 μl pipette tip, and the cells were washed three times to remove debris. DMSO control HT-29 cells were treated with DMSO, while dabrafenib-insensitive HT-29 cells with dabrafenib and fresh growth medium was given to the initial control cells. Cell migration was monitored every 4 h using a Nikon Eclipse Ti2e microscope. The area of closure was calculated via ImageJ.

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Publication 2024

Cytotoxicity Assessment of Anticancer Drugs

dabrafenib-insensitive, DMSO control and initial HT-29 cells were seeded into 96-well plates at 10 × 10³ cells/well density. After 24 h of seeding, a medium was replaced with drugs according to dose range. The drugs were used as following: dabrafenib (AdooQ Bioscience, USA), oxaliplatin (LC Laboratories, USA.), capecitabine (LC Laboratories, USA). After 72 h of drug treatment, MTT cell viability assay was performed. We used GraphPad Prism software to calculate IC50 values in all cell viability results through following the software’s guidelines^{63 (link)}. The drug concentrations used in the experiment were initially transformed as a logarithmic concentration. Then, we analysed the data using log(inhibitor) vs. normalised response model and non-linear regression. The dose response model estimated the IC50 value according to the rest of data points used in the regression model.

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Publication 2024

Top products related to «Dabrafenib»

Dabrafenib by Selleck Chemicals

Sourced in United States, Germany, France, Italy

Dabrafenib is a small molecule inhibitor of mutant BRAF kinases. It is used as a research tool in the study of BRAF-mediated signaling pathways.

Trametinib by Selleck Chemicals

Sourced in United States, Germany, United Kingdom, France, China, Italy

Trametinib is a selective inhibitor of mitogen-activated protein kinase kinase (MEK) enzymes 1 and 2. It is a white to almost white crystalline powder that is used in various biomedical research applications.

Vemurafenib by Selleck Chemicals

Sourced in United States, Germany, France, China

Vemurafenib is a laboratory reagent used in research applications. It functions as a kinase inhibitor, specifically targeting the BRAF V600E mutation. This product is intended for research use only and its specific applications may vary depending on the research objectives.

Dimethyl sulfoxide (dmso) by Merck Group

Sourced in United States, Germany, United Kingdom, China, Italy, Sao Tome and Principe, France, Macao, India, Canada, Switzerland, Japan, Australia, Spain, Poland, Belgium, Brazil, Czechia, Portugal, Austria, Denmark, Israel, Sweden, Ireland, Hungary, Mexico, Netherlands, Singapore, Indonesia, Slovakia, Cameroon, Norway, Thailand, Chile, Finland, Malaysia, Latvia, New Zealand, Hong Kong, Pakistan, Uruguay, Bangladesh

DMSO is a versatile organic solvent commonly used in laboratory settings. It has a high boiling point, low viscosity, and the ability to dissolve a wide range of polar and non-polar compounds. DMSO's core function is as a solvent, allowing for the effective dissolution and handling of various chemical substances during research and experimentation.

Sch772984 by Selleck Chemicals

Sourced in United States, China, Germany, United Kingdom, Switzerland

SCH772984 is a chemical compound used in laboratory research. It functions as a small molecule inhibitor. The core purpose of this product is for use in scientific experimentation and analysis.

Cobimetinib by Selleck Chemicals

Sourced in United States, France

Cobimetinib is a lab equipment product that functions as a mitogen-activated protein kinase (MEK) inhibitor. It is designed for research and experimental use.

Dabrafenib by Merck Group

Sourced in United States

Dabrafenib is a laboratory product manufactured by Merck Group. It is a small molecule inhibitor used for scientific research purposes.

Selumetinib by Selleck Chemicals

Sourced in United States, China, Germany

Selumetinib is a selective inhibitor of mitogen-activated protein kinase kinase (MEK), a key component in the RAS/RAF/MEK/ERK signaling pathway. It is a powder-form laboratory reagent used in research and development applications.

Fetal bovine serum (fbs) by Thermo Fisher Scientific

Sourced in United States, China, United Kingdom, Germany, Australia, Japan, Canada, Italy, France, Switzerland, New Zealand, Brazil, Belgium, India, Spain, Israel, Austria, Poland, Ireland, Sweden, Macao, Netherlands, Denmark, Cameroon, Singapore, Portugal, Argentina, Holy See (Vatican City State), Morocco, Uruguay, Mexico, Thailand, Sao Tome and Principe, Hungary, Panama, Hong Kong, Norway, United Arab Emirates, Czechia, Russian Federation, Chile, Moldova, Republic of, Gabon, Palestine, State of, Saudi Arabia, Senegal

Fetal Bovine Serum (FBS) is a cell culture supplement derived from the blood of bovine fetuses. FBS provides a source of proteins, growth factors, and other components that support the growth and maintenance of various cell types in in vitro cell culture applications.

Sorafenib by Selleck Chemicals

Sourced in United States, China, Germany, Australia

Sorafenib is a laboratory reagent that functions as a multi-kinase inhibitor. It is commonly used in research settings to study cellular signaling pathways and their modulation.

What is Dabrafenib and how does it work in cancer treatment?

What are some common usage challenges or considerations with Dabrafenib?

Are there different variations or types of Dabrafenib that patients may receive?

In what specific cancer types and applications is Dabrafenib used?

How can PubCompare.ai assist in the optimal use and comparison of Dabrafenib?

PubCompre.ai allows researchers to more efficiently screen the protocol literature related to Dabrafenib. The platform's AI-driven analysis can pinpoint critical insights, helping identify the most effective protocols for your specific research goals. By highlighting key differences in protocol effectiveness, PubCompare.ai enables you to choose the best option for reproducibility and accmuracy, enhancing your Dabrafenib research workflow.

More about "Dabrafenib"

Dabrafenib is a targeted therapy used to treat certain types of cancer, including malignant melanoma and thyroid carcinoma.
It works by blocking a specific mutation in the BRAF gene, which can drive tumor growth.
PubCompare.ai, an AI-powered platform, helps optimize Dabrafenib research by identifying the best protocols and products across literature, pre-prints, and patents.
This allows researchers to locate and evalulate Dabrafenib-related information with unparalleled reproducibility and accuaracy, enhancing the research workflow.
PubCompare.ai's AI-driven comparisons provide a concise, informative overview of Dabrafenib and its uses in cancer treatment.
Dabrafenib is often used in combination with other therapies, such as Trametinib, Vemurafenib, and Cobimetinib, to treat advanced or metastatic melanoma and other BRAF-mutant cancers.
These targeted therapies work by inhibiting specific components of the MAPK signaling pathway, which is commonly dysregulated in these types of cancers.
In addition to its use in cancer treatment, Dabrafenib has also been studied in the context of other diseases, such as Parkinson's disease, where it may have neuroprotective effects.
Researchers have also investigated the use of Dabrafenib in combination with other compounds, like DMSO and SCH772984, to enhance its efficacy or overcome resistance.
Overall, Dabrafenib is an important tool in the fight against cancer, and PubCompare.ai's AI-powered platform helps researchers navigate the ever-expanding body of Dabrafenib-related information with greater efficiency and accuracy.