Finafloxacin-d₄ hydrochloride

Cat. No.: HY-13451AS: Data Sheet Handling Instructions
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Finafloxacin-d₄ (hydrochloride) is deuterium-labeled Finafloxacin (hydrochloride) (HY-13451A).

For research use only. We do not sell to patients.

Finafloxacin-d<sub>4</sub> hydrochloride Chemical Structure

Finafloxacin-d₄ hydrochloride Chemical Structure

CAS No. : 2012598-36-4

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1 mg		Get quote	Estimated Time of Arrival: June 3

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Other Forms of Finafloxacin-d₄ hydrochloride:

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Finafloxacin hydrochloride Get quote

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Description	Finafloxacin-d₄ (hydrochloride) is deuterium-labeled Finafloxacin (hydrochloride) (HY-13451A)^[1].
In Vitro	Stable or radioisotope-labeled compounds allow precise tracking and quantification of individual atoms in metabolic pathways. Stable isotopes generally do not change molecular properties but may slightly affect metabolic kinetics; radioactive isotopes may interfere with cells. Markers can distinguish endogenous and exogenous metabolites, reduce false positives, and are beneficial to quantification and reconstruction of metabolic pathways^[2]. In cell culture or enzymatic reactions, the use of isotope markers can precisely control the concentration and exposure time, making it easy to study metabolic reactions and enzyme activities. Through stable isotope analytical metabolomics (SIRM), cellular metabolic networks can be studied, key metabolic nodes and regulatory mechanisms can be identified, and targets can be provided for compound development. Isotope-labeled compounds can be used in competition binding experiments to evaluate the affinity and binding kinetics of compounds to receptors to help optimize design. Stable isotope labels are used as internal standards in mass spectrometry analysis to improve analysis accuracy and reproducibility and reduce matrix effect interference^[3]. MedChemExpress (MCE) has not independently confirmed the accuracy of these methods. They are for reference only.
In Vivo	Isotopic labels can non-invasively track the distribution, transformation and clearance of compounds and their metabolites in the body through techniques such as mass spectrometry (MS) and nuclear magnetic resonance (NMR), which is beneficial to the study of pharmacometabolic kinetics (ADME). Isotope labeling can reveal specific steps in metabolic pathways. Using compounds with stable isotope labels at specific locations directly in humans or animal models can also help verify drug mechanisms and evaluate unexpected side effects, improving the accuracy and efficiency of clinical research^[3]. MedChemExpress (MCE) has not independently confirmed the accuracy of these methods. They are for reference only.
Molecular Weight	438.87
Formula	C₂₀H₁₆D₄ClFN₄O₄
CAS No.	2012598-36-4
Unlabeled CAS	209342-41-6
SMILES	O=C(C1=CN(C2C([2H])([2H])C2([2H])[2H])C3=C(C=C(F)C(N4C[C@]5([H])OCCN[C@@]5([H])C4)=C3C#N)C1=O)O.Cl
Shipping	Room temperature in continental US; may vary elsewhere.
Storage	Please store the product under the recommended conditions in the Certificate of Analysis.
Purity & Documentation	Data Sheet (274 KB) Handling Instructions (2659 KB)
References	[1]. Russak EM, et al. Impact of Deuterium Substitution on the Pharmacokinetics of Pharmaceuticals. Ann Pharmacother. 2019;53(2):211-216. [Content Brief] [2]. Smith K A, et al. Soil and environmental analysis[M]. Marcel Dekker Incorporated, 2000. [3]. Fan T W M, et al. Stable isotope-resolved metabolomics and applications for drug development[J]. Pharmacology & therapeutics, 2012, 133(3): 366-391. [Content Brief]

Finafloxacin-d₄ hydrochloride Related Classifications

Infection

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The molarity calculator equation

Mass (g) = Concentration (mol/L) × Volume (L) × Molecular Weight (g/mol)

Mass		Concentration		Volume		Molecular Weight *
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The dilution calculator equation

Concentration _(start) × Volume _(start) = Concentration _(final) × Volume _(final)

This equation is commonly abbreviated as: C₁V₁ = C₂V₂

Concentration _(start)	×	Volume _(start)	=	Concentration _(final)	×	Volume _(final)
	×		=		×
C1		V1		C2		V2

Help & FAQs

How should lyophilized recombinant proteins be reconstituted and stored?
1. Before opening the cap, centrifuge the vial at 13000 rpm for 20-30 seconds. This step will ensure that any lyophilized powder that may have adhered to the cap or walls is collected at the bottom of the vial, minimizing the risk of product loss. 2. Taking 10 μg as an example, first add 20 μL of reconstituted solution provided by MCE and use a pipette to gently resuspend the lyophilized protein until it is fully dissolved.. (For most proteins, the reconstitution solution we provide is sterile water. If a diluent other than water is required, it will be indicated in the product's Certificate of Analysis (COA).). 3. Add an additional 80 μL of buffer/culture medium containing carrier protein (either 0.1% BSA, 5% HSA, 10% FBS, or 5% trehalose), and then use a pipette to gently mix until uniform. The final concentration is should not be lower than 100 μg/mL. 4. Aliquot at least 20 μL per tube. 5. After aliquoting, store it frozen at a temperature ranging from -20ºC to -80ºC, and it can be preserved for 3 to 6 months.
How should solution-form recombinant proteins be stored?
1. The product can be stored in its original form and diluted as needed upon use. 2. Alternatively, dilute with a buffer/culture medium containing a carrier protein (either 0.1% BSA, 5% HSA, 10% FBS, or 5% alginate), mix well by pipetting, and ensure that
Why is it necessary to add carrier proteins?
Carrier proteins are commonly added to enhance the stability of recombinant proteins, preventing them from adhering to the walls of the container during freezing or thawing processes. Plastic tubes have a certain adsorptive capacity for proteins, which may lead to difficulty in separating the protein from the tube walls, resulting in a decrease in the actual concentration of the protein in the solution and thus affecting its activity. To minimize such losses, it is recommended to add a commonly used carrier protein solution prior to the long-term storage of recombinant protein products.
Carrier protein types and options?
In cases where the carrier protein is not expected to influence the experimental outcomes, an appropriate carrier protein, such as 0.1% BSA (Bovine Serum Albumin), 5% HSA (Human Serum Albumin), 10% FBS (Fetal Bovine Serum), or 5% trehalose, can be incorpo

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Finafloxacin-d₄2012598-36-4BacterialIsotope-Labeled CompoundsInhibitorinhibitorinhibit

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Finafloxacin-d4 hydrochloride

Other Forms of Finafloxacin-d4 hydrochloride:

Biological Activity

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Finafloxacin-d4 hydrochloride Related Classifications

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