Tyrosine powder
Requires a prescription from a doctor or prescriber
Tyrosine is a non-essential amino acid.
Official documents, adverse reaction reporting, and safety monitoring
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Official medicine documents
Safety monitoring data
Yellow Card reports
The MHRA Yellow Card scheme collects reports of suspected side effects from healthcare professionals and patients. View the Drug Analysis Profile (iDAP) for real-world adverse reaction data.
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Suspected adverse reactions reported for Tyrosine
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Data from the MHRA Yellow Card scheme. A reported reaction does not necessarily mean the medicine caused it. Contains public sector information licensed under the Open Government Licence v3.0.
EudraVigilance
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EudraVigilance data is published by the European Medicines Agency (EMA). A suspected adverse reaction is not necessarily caused by the medicine.
2 branded products available
Therapeutically similar medicines
Similarity is based on WHO Anatomical Therapeutic Chemical (ATC) classification and on a factual NHS dm+d therapeutic-grouping code prefix. Source data: NHS dm+d via TRUD (OGL v3.0), WHO ATC/DDD Index.
NHS prescribing volume and spending trends
Guidelines from the National Institute for Health and Care Excellence
NICE clinical guidance(14)
Asciminib for treating chronic myeloid leukaemia after 2 or more tyrosine kinase inhibitors (TA813)
Bosutinib for previously treated chronic myeloid leukaemia (TA401)
Lenvatinib and sorafenib for treating differentiated thyroid cancer after radioactive iodine (TA535)
Dasatinib, nilotinib and imatinib for untreated chronic myeloid leukaemia (TA426)
Nivolumab for previously treated advanced renal cell carcinoma (TA417)
Afatinib for treating epidermal growth factor receptor mutation-positive locally advanced or metastatic non-small-cell lung cancer (TA310)
Osimertinib for untreated EGFR mutation-positive non-small-cell lung cancer (TA654)
Dacomitinib for untreated EGFR mutation-positive non-small-cell lung cancer (TA595)
Axitinib for treating advanced renal cell carcinoma after failure of prior systemic treatment (TA333)
Entrectinib for treating NTRK fusion-positive solid tumours in people 12 years and over (terminated appraisal) (TA1118)
Nivolumab with ipilimumab for untreated advanced renal cell carcinoma (TA780)
Lorlatinib for previously treated ALK-positive advanced non-small-cell lung cancer (TA628)
Erlotinib for the first-line treatment of locally advanced or metastatic EGFR-TK mutation-positive non-small-cell lung cancer (TA258)
Osimertinib for treating EGFR T790M mutation-positive advanced non-small-cell lung cancer (TA653)
Source: National Institute for Health and Care Excellence (NICE). Contains public sector information licensed under the Open Government Licence v3.0.
Check stock at pharmacies and supply information
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Supply & safety information
Official UK regulator monitoring and safety alerts
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Codes for healthcare professionals and prescribing systems
These codes are used by healthcare IT systems and prescribers to identify this medicine.
NHS UK identifiers
SNOMED CT and dm+d codes from NHS TRUD (Technology Reference data Update Distribution), licensed under the Open Government Licence v3.0. BNF code shown is the factual mapping value distributed by NHS Business Services Authority (NHSBSA) in the dm+d supplementary file under OGL v3.0; it is not affiliated with, nor licensed from, the publishers of the British National Formulary.
Active and completed clinical studies from ClinicalTrials.gov
Source: ClinicalTrials.gov, a database of the U.S. National Library of Medicine (NLM), National Institutes of Health (NIH). Data accessed via ClinicalTrials.gov API v2. Trial information is provided for research purposes and does not constitute medical advice.
Academic studies and reviews for this medicine's active substance
Showing all 30 studies.
Reviews & meta-analyses: 13 · 1967–2020
Showing all 30 studies, sorted by most relevant.
Z. Du, C. Lovly
Molecular Cancer, 2018
- Signal Transduction
- Cell Transformation, Neoplastic
- Enzyme Activation
Receptor tyrosine kinases (RTKs) play an important role in a variety of cellular processes including growth, motility, differentiation, and metabolism. As such, dysregulation of RTK signaling leads to an assortment of human diseases, most notably, cancers. Recent large-scale genomic studies have revealed the presence of various alterations in the genes encoding RTKs such as EGFR, HER2/ErbB2, and MET, amongst many others. Abnormal RTK activation in human cancers is mediated by four principal mechanisms: gain-of-function mutations, genomic amplification, chromosomal rearrangements, and / or autocrine activation. In this manuscript, we review the processes whereby RTKs are activated under normal physiological conditions and discuss several mechanisms whereby RTKs can be aberrantly activated in human cancers. Understanding of these mechanisms has important implications for selection of anti-cancer therapies.
Abstract licence: CC BY
Simar Pal Singh, Floris Dammeijer, R. Hendriks
Molecular Cancer, 2018
- Agammaglobulinaemia Tyrosine Kinase
- Antineoplastic Combined Chemotherapy Protocols
- B-Lymphocytes
Bruton's tyrosine kinase (BTK) is a non-receptor kinase that plays a crucial role in oncogenic signaling that is critical for proliferation and survival of leukemic cells in many B cell malignancies. BTK was initially shown to be defective in the primary immunodeficiency X-linked agammaglobulinemia (XLA) and is essential both for B cell development and function of mature B cells. Shortly after its discovery, BTK was placed in the signal transduction pathway downstream of the B cell antigen receptor (BCR). More recently, small-molecule inhibitors of this kinase have shown excellent anti-tumor activity, first in animal models and subsequently in clinical studies. In particular, the orally administered irreversible BTK inhibitor ibrutinib is associated with high response rates in patients with relapsed/refractory chronic lymphocytic leukemia (CLL) and mantle-cell lymphoma (MCL), including patients with high-risk genetic lesions. Because ibrutinib is generally well tolerated and shows durable single-agent efficacy, it was rapidly approved for first-line treatment of patients with CLL in 2016. To date, evidence is accumulating for efficacy of ibrutinib in various other B cell malignancies. BTK inhibition has molecular effects beyond its classic role in BCR signaling. These involve B cell-intrinsic signaling pathways central to cellular survival, proliferation or retention in supportive lymphoid niches. Moreover, BTK functions in several myeloid cell populations representing important components of the tumor microenvironment. As a result, there is currently a considerable interest in BTK inhibition as an anti-cancer therapy, not only in B cell malignancies but also in solid tumors. Efficacy of BTK inhibition as a single agent therapy is strong, but resistance may develop, fueling the development of combination therapies that improve clinical responses. In this review, we discuss the role of BTK in B cell differentiation and B cell malignancies and highlight the importance of BTK inhibition in cancer therapy.
Abstract licence: CC BY
Guoshuang Shen, F. Zheng, Dengfeng Ren, et al.
Journal of Hematology & Oncology, 2018
- Indoles
- Neoplasms
- Quinolines
Anlotinib is a new, orally administered tyrosine kinase inhibitor that targets vascular endothelial growth factor receptor (VEGFR), fibroblast growth factor receptor (FGFR), platelet-derived growth factor receptors (PDGFR), and c-kit. Compared to the effect of placebo, it improved both progression-free survival (PFS) and overall survival (OS) in a phase III trial in patients with advanced non-small-cell lung cancer (NSCLC), despite progression of the cancer after two lines of prior treatments. Recently, the China Food and Drug Administration (CFDA) approved single agent anlotinib as a third-line treatment for patients with advanced NSCLC. Moreover, a randomized phase IIB trial demonstrated that anlotinib significantly prolonged the median PFS in patients with advanced soft tissue sarcoma (STS). Anlotinib also showed promising efficacy in patients with advanced medullary thyroid carcinoma and metastatic renal cell carcinoma (mRCC). The tolerability profile of anlotinib is similar to that of other tyrosine kinase inhibitors that target VEGFR and other tyrosine kinase-mediated pathways; however, anlotinib has a significantly lower incidence of grade 3 or higher side effects compared to that of sunitinib. We review the rationale, clinical evidence, and future perspectives of anlotinib for the treatment of multiple cancers.
Abstract licence: CC BY
G. Ferrer-Sueta, Nicolás Campolo, M. Trujillo, et al.
Chemical reviews, 2018
- Carbon Dioxide
- Coenzymes
- Electron Transport Complex IV
S. Bartesaghi, R. Radi
Redox Biology, 2017
- Models, Molecular
- Nitric Oxide
- Proteins
NO-dependent oxidative processes. Recently, mechanisms responsible of tyrosine nitration in hydrophobic biostructures such as membranes and lipoproteins have been assessed and involve the parallel occurrence and connection with lipid peroxidation. Experimental strategies to reveal the proximal oxidizing mechanism during tyrosine nitration in given pathophysiologically-relevant conditions include mapping and identification of the tyrosine nitration sites in specific proteins.
Abstract licence: CC BY-NC-ND
Liling Huang, Shiyu Jiang, Yuankai Shi
Journal of Hematology & Oncology, 2020
- Clinical Decision-Making
- Antineoplastic Agents
- Neoplasms
Tyrosine kinases are implicated in tumorigenesis and progression, and have emerged as major targets for drug discovery. Tyrosine kinase inhibitors (TKIs) inhibit corresponding kinases from phosphorylating tyrosine residues of their substrates and then block the activation of downstream signaling pathways. Over the past 20 years, multiple robust and well-tolerated TKIs with single or multiple targets including EGFR, ALK, ROS1, HER2, NTRK, VEGFR, RET, MET, MEK, FGFR, PDGFR, and KIT have been developed, contributing to the realization of precision cancer medicine based on individual patient's genetic alteration features. TKIs have dramatically improved patients' survival and quality of life, and shifted treatment paradigm of various solid tumors. In this article, we summarized the developing history of TKIs for treatment of solid tumors, aiming to provide up-to-date evidence for clinical decision-making and insight for future studies.
Abstract licence: CC BY
Qinlian Jiao, Lei Bi, Yidan Ren, et al.
Molecular Cancer, 2018
- Neoplasms
- Protein-Tyrosine Kinases
- Signal Transduction
Protein tyrosine kinase (PTK) is one of the major signaling enzymes in the process of cell signal transduction, which catalyzes the transfer of ATP-γ-phosphate to the tyrosine residues of the substrate protein, making it phosphorylation, regulating cell growth, differentiation, death and a series of physiological and biochemical processes. Abnormal expression of PTK usually leads to cell proliferation disorders, and is closely related to tumor invasion, metastasis and tumor angiogenesis. At present, a variety of PTKs have been used as targets in the screening of anti-tumor drugs. Tyrosine kinase inhibitors (TKIs) compete with ATP for the ATP binding site of PTK and reduce tyrosine kinase phosphorylation, thereby inhibiting cancer cell proliferation. TKI has made great progress in the treatment of cancer, but the attendant acquired acquired resistance is still inevitable, restricting the treatment of cancer. In this paper, we summarize the role of PTK in cancer, TKI treatment of tumor pathways and TKI acquired resistance mechanisms, which provide some reference for further research on TKI treatment of tumors.
Abstract licence: CC BY
A. Ullrich, J. Schlessinger
Cell, 1990
- Signal Transduction
- Cell Membrane
- Models, Biological
C. Marshall
Cell, 1995
- Signal Transduction
- Caenorhabditis
- Drosophila
M. Lemmon, J. Schlessinger
Cell, 2000
- Signal Transduction
- Enzyme Activation
- Neoplasms
Sources: aggregated from Europe PMC (EMBL-EBI), OpenAlex, Crossref, PubMed and other open scholarly databases. Retracted articles are excluded. Study information is provided for research purposes and does not constitute medical advice.
Pharmacology and chemical data from DrugBank
Key facts
Drug status
Approved
Major interactions
None known
Half-life
Not available
Mechanism
Tyrosine is produced in cells by hydroxylating the essential amino acid phenylalanine.
Food interactions
None known
Human targets
4 targets
Data: DrugBank · CC BY-NC 4.0
Pharmacokinetics at a glance
Absorption
Metabolism
Pharmacokinetic data: DrugBank · CC BY-NC 4.0
Known interactions with other medications. Always consult a healthcare professional.
Showing 1 of 1 interactions
How the body processes this drug — absorption, distribution, metabolism, and elimination
Proteins and enzymes this drug interacts with in the body
Positively regulates the regression of retinal hyaloid vessels during postnatal development (By similarity)
PMID:25533949
Also acts as a positive regulator of poly-ADP-ribosylation in the nucleus, independently of its tyrosine--tRNA ligase activity .
PMID:25533949
Activity is switched upon resveratrol-binding: resveratrol strongly inhibits the tyrosine--tRNA ligase activity and promotes relocalization to the nucleus, where YARS1 specifically stimulates the poly-ADP-ribosyltransferase activity of PARP1 PMID:25533949
Has much lower affinity and transaminase activity towards phenylalanine
Proteins that transport this drug across cell membranes
PMID:16887882 PMID:18337592 PMID:20628049 PMID:23550058 PMID:26426690 PMID:27805744 PMID:31436139
Acts as an important mediator of thyroid hormone transport, especially T3, through the blood-brain barrier (Probable) PMID:28526555
PMID:11827462 PMID:18337592 PMID:28754537
Mediates both uptake and efflux of 3,5,3'-triiodothyronine (T3) and 3,5,3',5'-tetraiodothyronine (T4) with high affinity, suggesting a role in the homeostasis of thyroid hormone levels .
PMID:18337592
Responsible for low affinity bidirectional transport of the aromatic amino acids, such as phenylalanine, tyrosine, tryptophan and L-3,4-dihydroxyphenylalanine (L-dopa) .
PMID:11827462 PMID:28754537
Plays an important role in homeostasis of aromatic amino acids (By similarity)
Involved compounds
Involved compounds
Involved compounds
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Chemical identifiers
CAS, UNII, InChI Key and database cross-references
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Chemical identifiers
CAS, UNII, InChI Key and database cross-references
Linked compound data from DrugBank Open Data (CC BY-NC 4.0)
Tyrosine
Additional database identifiers
Drugs Product Database (DPD)
897
Drugs Product Database (DPD)
9750
ChemSpider
5833
BindingDB
18129
PDB
TYR
ZINC
ZINC000000266964
HUGO Gene Nomenclature Committee (HGNC)
HGNC:11782
GenAtlas
TH
GeneCards
TH
GenBank Gene Database
Y00414
GenBank Protein Database
37127
UniProt Accession
TY3H_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:24249
GenAtlas
YARS2
GeneCards
YARS2
GenBank Gene Database
AF132939
GenBank Protein Database
4680649
UniProt Accession
SYYM_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:12840
GenAtlas
YARS
GeneCards
YARS1
GenBank Gene Database
U40714
GenBank Protein Database
1184699
UniProt Accession
SYYC_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:11573
GenAtlas
TAT
GeneCards
TAT
GenBank Gene Database
X52520
GenBank Protein Database
36713
UniProt Accession
ATTY_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:10923
GenAtlas
SLC16A2
GeneCards
SLC16A2
GenBank Gene Database
U05321
GenBank Protein Database
458255
UniProt Accession
MOT8_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:17027
GeneCards
SLC16A10
GenBank Gene Database
AB057445
GenBank Protein Database
18640047
UniProt Accession
MOT10_HUMAN
DrugBank citations
If you use DrugBank data in your research, please cite the following publications:
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Structured knowledge from the free knowledge base
Linked open data from Wikidata (Q106345477), a free and open knowledge base operated by the Wikimedia Foundation. Data is available under the Creative Commons CC0 1.0 Public Domain Dedication.