PEG300 (Glycols polyethylene)

Name: PEG300 (Glycols polyethylene)
Brand: GlpBio
SKU: GC30022
Availability: InStock
Rating: 5 (31 reviews)

Catalog No.GC30022

PEG300 (Glycols polyethylene), un polímero neutro con un peso molecular de 300, es un polímero soluble en agua, de baja inmunogenicidad y biocompatible, formado por unidades repetitivas de etilenglicol.

Products are for research use only. Not for human use. We do not sell to patients.

PEG300 (Glycols polyethylene) Chemical Structure

Cas No.: 25322-68-3

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Precio

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Cantidad

50mL	28,00 $	Disponible
100mL	36,00 $	Disponible
200mL	61,00 $	Disponible
300mL	84,00 $	Disponible
500mL	112,00 $	Disponible

Tel：(909) 407-4943 Email: sales@glpbio.com

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Based on customer reviews.

Sample solution is provided at 25 µL, 10mM.

Product has been cited by 2 publications

Description Protocol Chemical Properties Product Documents Related Video

Product Documents

Quality Control & SDS

View current batch:

Purity: >98.00%

Protocol

Experimentos celulares [1]:
Líneas celulares	Células Caco-2
Método de preparación	Se añadieron células Caco-2 y se agregaron 1.5 ml de medio completo en la parte superior [compartimento apical (AP)] y 2.6 ml en la parte inferior [compartimento basolateral (BL)] de cada transwell. La actividad de la P-gp en estas monocapas celulares se evaluó rutinariamente mediante estudios de transporte bidireccional del sustrato de P-gp [3H] paclitaxel.
Condiciones de reacción	0/20% durante 3 horas
Áreas de aplicación	Se determinó el flujo AP-BL de testosterona (0.3 mM) a través de monocapas de células Caco-2 en ausencia y presencia de la concentración más alta (20%, v/v) de PEG-300 utilizada en estos estudios para probar cualquier posible efecto de este excipiente en la vía transcelular pasiva a través de células Caco-2. Los resultados experimentales sugieren que el PEG-300 no altera la vía transcelular pasiva a través de monocapas de células Caco-2.
Referencias: [1]. Hugger E D, Audus K L, Borchardt R T. Efectos del polietilenglicol en la actividad del transportador de eflujo en monocapas de células Caco-2[J]. Journal of Pharmaceutical Sciences, 2002, 91(9): 1980-1990.

Niveles relativamente altos pero clínicamente alcanzables de PEG-300 pueden inhibir la actividad de P-gp en monocapas de células Caco-2, mejorando así la permeabilidad de fármacos anticancerígenos como el paclitaxel y la doxorrubicina. Por ejemplo, aumentar la concentración de PEG-300 conducirá al aumento de Papp y AP a BL de [3H] paclitaxel [sustrato de P-gp] [3-6]12-14,28 y a la disminución de Papp y BL a AP. A altas concentraciones (20%, v/v) de PEG-300, parece que el paclitaxel es transportado a través de las monocapas de células Caco-2 por simple difusión transcelular pasiva. Se observó una inhibición similar inducida por PEG de los transportadores de eflujo (por ejemplo, la actividad de P-gp y/o P-gp/MRP) en células Caco-2 [5], doxorrubicina, lo que indica que la inhibición del eflujo inducida por PEG no es un fenómeno único del paclitaxel.

References:
[1] Lee C C, Su Y C, Ko T P, et al. Structural basis of polyethylene glycol recognition by antibody[J]. Journal of biomedical science, 2020, 27(1): 1-13.
[2] Billingham J, Breen C, Yarwood J. Adsorption of polyamine, polyacrylic acid and polyethylene glycol on montmorillonite: An in situ study using ATR-FTIR[J]. Vibrational Spectroscopy, 1997, 14(1): 19-34.
[3] Krishna R, Mayer L D. Multidrug resistance (MDR) in cancer: mechanisms, reversal using modulators of MDR and the role of MDR modulators in influencing the pharmacokinetics of anticancer drugs[J]. European Journal of Pharmaceutical Sciences, 2000, 11(4): 265-283.
[4] Van Asperen J, Van Tellingen O, Sparreboom A, et al. Enhanced oral bioavailability of paclitaxel in mice treated with the P-glycoprotein blocker SDZ PSC 833[J]. British Journal of Cancer, 1997, 76(9): 1181-1183.
[5] van Asperen J, van Tellingen O, van der Valk M A, et al. Enhanced oral absorption and decreased elimination of paclitaxel in mice cotreated with cyclosporin A[J]. Clinical cancer research: an official journal of the American Association for Cancer Research, 1998, 4(10): 2293-2297.

Cas No.	25322-68-3	SDF
Canonical SMILES	OCCCCOC[H].[n]
Formula	H(OCH₂CH₂)_nOH	M.Wt	300
Solubility	DMSO : 100 mg/mL (960.15 mM);Water : ≥ 50 mg/mL (480.08 mM)	Storage	Store at RT
General tips	Please select the appropriate solvent to prepare the stock solution according to the solubility of the product in different solvents; once the solution is prepared, please store it in separate packages to avoid product failure caused by repeated freezing and thawing.Storage method and period of the stock solution: When stored at -80°C, please use it within 6 months; when stored at -20°C, please use it within 1 month. To increase solubility, heat the tube to 37°C and then oscillate in an ultrasonic bath for some time.
Shipping Condition	Evaluation sample solution: shipped with blue ice. All other sizes available: with RT, or with Blue Ice upon request.

Complete Stock Solution Preparation Table

Prepare stock solution
		1 mg	5 mg	10 mg
	1 mM	3.3333 mL	16.6667 mL	33.3333 mL
	5 mM	0.6667 mL	3.3333 mL	6.6667 mL
	10 mM	0.3333 mL	1.6667 mL	3.3333 mL

Molarity Calculator
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In vivo Formulation Calculator (Clear solution)

Step 1: Enter information below (Recommended: An additional animal making an allowance for loss during the experiment)

Dosage: mg/kg

Average weight of animals: g

Dosing volume per animal:μL

Number of animals:

Step 2: Enter the in vivo formulation (This is only the calculator, not formulation. Please contact us first if there is no in vivo formulation at the solubility Section.)

% DMSO + % + % Tween 80 + % ddH₂O

%DMSO+ %

Calculation results:

Working concentration: mg/ml;

Method for preparing DMSO master liquid: mg drug pre-dissolved in μL DMSO ( Master liquid concentration mg/mL, Please contact us first if the concentration exceeds the DMSO solubility of the batch of drug. )

Method for preparing in vivo formulation: Take μL DMSO master liquid, next addμL PEG300, mix and clarify, next addμL Tween 80, mix and clarify, next add μL ddH₂O, mix and clarify.

Method for preparing in vivo formulation: Take μL DMSO master liquid, next add μL Corn oil, mix and clarify.

Note: 1. Please make sure the liquid is clear before adding the next solvent.
2. Be sure to add the solvent(s) in order. You must ensure that the solution obtained, in the previous addition, is a clear solution before proceeding to add the next solvent. Physical methods such as vortex, ultrasound or hot water bath can be used to aid dissolving.
3. All of the above co-solvents are available for purchase on the GlpBio website.

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Review for PEG300 (Glycols polyethylene)

Average Rating: 5 ★★★★★ (Based on Reviews and 31 reference(s) in Google Scholar.)

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PEG300 (Glycols polyethylene)

Reseñas de cliente

GlpBio Citations

Bioactive Compounds Premium Provider

Product has been cited by 2 publications

Product Documents

Quality Control & SDS

Protocol

Complete Stock Solution Preparation Table

Molarity Calculator

Dilution Calculator

Molecular Weight Calculator

In vivo Formulation Calculator (Clear solution)

Related Video

Reseñas

PEG300 (Glycols polyethylene)

Reseñas de cliente

GlpBio Citations

Bioactive Compounds Premium Provider

Product has been cited by 2 publications

Product Documents

Quality Control & SDS

Protocol

Complete Stock Solution Preparation Table

Molarity Calculator

Dilution Calculator

Molecular Weight Calculator

In vivo Formulation Calculator (Clear solution)

Related Video

Related Products

Reseñas