Di-8-ANEPPS CAS#: 157134-53-7

Ordering information

Price
Catalog Number
Unit Size
Quantity

Add to cart

Additional ordering information

Telephone	1-800-990-8053
Fax	1-800-609-2943
Email	sales@aatbio.com
International	See distributors
Bulk request	Inquire
Custom size	Inquire
Shipping	Standard overnight for United States, inquire for international

Physical properties

Molecular weight	592.88
Solvent	DMSO

Spectral properties

Extinction coefficient (cm ^-1 M ^-1)	31622
Excitation (nm)	467
Emission (nm)	631

Storage, safety and handling

Certificate of Origin	Download PDF
H-phrase	H303, H313, H333
Hazard symbol	XN
Intended use	Research Use Only (RUO)
R-phrase	R20, R21, R22
Storage	Freeze (< -15 °C); Minimize light exposure
UNSPSC	12352200

Overview SDS Protocol

CAS

157134-53-7

Molecular weight

592.88

Extinction coefficient (cm ^-1 M ^-1)

31622

Excitation (nm)

467

Emission (nm)

631

Di-8-ANEPPS is widely used for monitoring fast membrane potential changes. ANEP dyes belong to the class of the fast-response membrane potential dyes. Their optical response is fast enough to detect transient membrane potential changes in excitable cells where they demonstrate a membrane potential-dependent shift in excitation spectra. This feature allows the measurement of membrane potential changes by excitation ratio. These dyes are weakly fluorescent in aqueous media, and become strongly fluorescent upon binding to lipophilic environments (such as membranes). Di-8-ANEPPS is less susceptible for cellular internalization than other ANEP dyes probably due to its sulfonate group. In general, fast-response probes operate by means of a change in their electronic structure, and consequently their fluorescence properties, in response to a change in the surrounding electric field. Their optical response is sufficiently fast to detect transient (millisecond) potential changes in excitable cells, including single neurons, cardiac cells and intact brains. However, the magnitude of their potential-dependent fluorescence change is often small; fast-response probes typically show a 2-10% fluorescence change per 100 mV.

Calculators

Common stock solution preparation

Table 1. Volume of DMSO needed to reconstitute specific mass of Di-8-ANEPPS *CAS#: 157134-53-7* to given concentration. Note that volume is only for preparing stock solution. Refer to sample experimental protocol for appropriate experimental/physiological buffers.

	0.1 mg	0.5 mg	1 mg	5 mg	10 mg
1 mM	168.668 µL	843.341 µL	1.687 mL	8.433 mL	16.867 mL
5 mM	33.734 µL	168.668 µL	337.336 µL	1.687 mL	3.373 mL
10 mM	16.867 µL	84.334 µL	168.668 µL	843.341 µL	1.687 mL

Molarity calculator

Enter any two values (mass, volume, concentration) to calculate the third.

Mass (Calculate)		Molecular weight		Volume (Calculate)		Concentration (Calculate)		Moles
	/		=		x		=

Spectrum

Open in Advanced Spectrum Viewer

Spectral properties

Extinction coefficient (cm ^-1 M ^-1)	31622
Excitation (nm)	467
Emission (nm)	631

Product Family

Name	Excitation (nm)	Emission (nm)	Extinction coefficient (cm ^-1 M ^-1)
Di-4-ANEPPS CAS#: 90134-00-2	482	686	31622

Images

Figure 1. Chemical structure for Di-8-ANEPPS *CAS#: 157134-53-7*

Citations

View all 4 citations: Citation Explorer

Destructive role of TMAO in T-tubule and excitation-contraction coupling in the adult cardiomyocytes
Authors: Jin, Bu and Ji, Fangfang and Zuo, Anjun and Liu, Huiting and Qi, Lin and He, Yun and Wang, Qingyao and Zhao, Peng
Journal: International Heart Journal (2020): 355--363

Cholesterol is required for maintaining T-tubule integrity and intercellular connections at intercalated discs in cardiomyocytes
Authors: Zhu, Yanqi and Zhang, Caimei and Chen, Biyi and Chen, Rong and Guo, Ang and Hong, Jiang and Song, Long-Sheng
Journal: Journal of molecular and cellular cardiology (2016): 204--212

Preserving transverse tubule function in adult cardiac myocytes in short-term culture.
Authors: Young, Kester EJ and Young, Kester EJ
Journal: Cardiol : 804--812

Multiple Functions for Targeted Self-delivery and Cancer Treatments
Authors: Luo, Shi-Zhong

References

View all 109 references: Citation Explorer

Optical imaging of medullary ventral respiratory network during eupnea and gasping in situ
Authors: Potts JT, Paton JF.
Journal: Eur J Neurosci (2006): 3025

Membrane dipole potential as measured by ratiometric 3-hydroxyflavone fluorescence probes: accounting for hydration effects
Authors: M'Baye G, Shynkar VV, Klymchenko AS, Mely Y, Duportail G.
Journal: J Fluoresc (2006): 35

Cholesterol effect on the dipole potential of lipid membranes
Authors: Starke-Peterkovic T, Turner N, Vitha MF, Waller MP, Hibbs DE, Clarke RJ.
Journal: Biophys J (2006): 4060

Three fluorescent protein voltage sensors exhibit low plasma membrane expression in mammalian cells
Authors: Baker BJ, Lee H, Pieribone VA, Cohen LB, Isacoff EY, Knopfel T, Kosmidis EK.
Journal: J Neurosci Methods. (2006)

Imaging of cardiac movement using ratiometric and nonratiometric optical mapping: effects of ischemia and 2, 3-butaneodione monoxime
Authors: Himel HDt, Knisley SB.
Journal: IEEE Trans Med Imaging (2006): 122

Effect of Cholesterol on the Interaction of the HIV GP41 Fusion Peptide with Model Membranes. Importance of the Membrane Dipole Potential
Authors: Buzon V, Cladera J.
Journal: Biochemistry (2006): 15768

Membrane potential of rat ventricular myocytes responds to axial stretch in phase, amplitude and speed-dependent manners
Authors: Nishimura S, Kawai Y, Nakajima T, Hosoya Y, Fujita H, Katoh M, Yamashita H, Nagai R, Sugiura S.
Journal: Cardiovasc Res (2006): 403

The Gurvich waveform has lower defibrillation threshold than the rectilinear waveform and the truncated exponential waveform in the rabbit heart
Authors: Qu F, Zarubin F, Wollenzier B, Nikolski VP, Efimov IR.
Journal: Can J Physiol Pharmacol (2005): 152

Near infrared two-photon excitation cross-sections of voltage-sensitive dyes
Authors: Fisher JA, Salzberg BM, Yodh AG.
Journal: J Neurosci Methods (2005): 94

Characteristics of a charged-coupled-device-based optical mapping system for the study of cardiac arrhythmias
Authors: Tang D, Li Y, Wong J, Po S, Patterson E, Chen WR, Jackman W, Liu H.
Journal: J Biomed Opt (2005): 24009