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N21-MAX Media Supplement (50X)

Catalog #: AR008
26 Citations 6 Reviews Datasheet
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AR008
N21-MAX Media Supplement (50X)_AR008
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N21-MAX Media Supplement (50X) Summary

Kit Summary

For the reliable maturation and superior long-term culture of primary neurons.

Key Benefits

  • Provides reliable maturation and superior function of neurons in culture
  • Can be used to improve stem cell and 3D culture conditions
  • Rigorous quality control testing ensures consistency across experiments
  • Is nutrient-rich and serum-free
  • Eliminates the need for an astrocyte feeder layer in neuronal cultures

Why Culture Neurons in Serum-Free N21-MAX Media Supplement?

The N21-MAX Media Supplement improves upon the traditional B271 and NS212 neuronal supplements, offering a serum-free and fully-defined formulation that is optimized for the reliable maturation, consistent health, and superior function of neurons in culture. There is an increase in the use of B27-like supplements to optimize stem cell and 3D cell culture media. N21-MAX improves stem cell differentiation and increases the viability and health of differentiated cell types during long-term cell culture conditions.

N21-MAX was designed to eliminate uncontrolled variables, such as those found in both serum-containing media and in some commercial serum-free neuronal supplements. Use of undefined media supplements can confound neuronal growth and maturation. N21-MAX contains a cocktail of factors optimized for neuronal survival, neurite extension, and synaptic maturation. Each lot of N21-MAX is tested on primary hippocampal neurons to ensure consistent performance for the user.

The N21-MAX Media Supplement:

  • Is fully defined and quality tested to reduce unwanted experimental variation.
  • Contains factors qualified to support reproducible and long-term neuron culture.
  • Modified from the published B27 formulation1.
  • Does not require an astrocyte feeder layer.
  • Has been tested to support the viability and growth of E18 rat hippocampal neurons.
  1. Brewer et al., (1993) J. Neurosci. Res. 32:567
  2. Chen et al., (2008) J. Neurosci. Methods 171:239

Kit Contents

N21-MAX is optimized for the maturation and long-term culturing of neuronal cells. The supplement is supplied as a 50X concentrated solution and contains the following 21 components:

  • Albumin (bovine)
  • L-Carnitine
  • Catalase
  • Corticosterone
  • Ethanolamine
  • Glutathione
  • Galactose
  • Holo-Transferrin
  • Insulin
  • Linoleic Acid
  • Linolenic Acid
  • Lipoic Acid
  • Progesterone
  • Putrescine
  • Retinyl acetate
  • Retinol
  • Selenite
  • Superoxide dismutase
  • Triiodo-L-thyronine
  • D,L-alpha-Tocopherol
  • D,L-alpha-Tocopherol acetate

Supplied in a volume sufficient to supplement 500 mL of media at the recommended concentration. N21-MAX is tested for use in Neurobasal Media.

Precautions

This product contains human transferrin. This transferrin was purified from donor plasma and tested at the donor level using an FDA licensed method and found to be non-reactive for anti-HIV-1/2 and Hepatitis B surface antigen. 

Specifications

Source
N/A
Shipping Conditions
The product is shipped with dry ice or equivalent. Upon receipt, store it immediately at the temperature recommended below.
Storage
Store the unopened product at -20 to -70 °C. Use a manual defrost freezer and avoid repeated freeze-thaw cycles. Do not use past expiration date.

Product Datasheets

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Product Datasheet

Scientific Data

Cell Stress N21-MAX Reduces Spontaneous Stress Rod Formation. View Larger

N21-MAX Reduces Spontaneous Stress Rod Formation. E18 rat hippocampal neuron cultures were plated on poly-D-lysine coated coverslips and grown for 5 days in media supplement with either N21-MAX (Catalog # AR008) or another commercial neural media supplement (Competitor). Cells were fixed and immunostained for rod formation, and indicator of cellular stress, using an antibody against cofilin (% of Neurons with Rods). A lower percentage of hippocampal neurons that were cultured in N21-MAX had spontaneous cofilin rod formation (4.5%) compared to neurons cultured in competitor media (16.8%). Data courtesy of the laboratory of Dr. James Bamburg at Colorado State University.

Cell Differentiation/ Maturation Improved Resolution of Rod Induction in Neurons Cultured in N21-MAX. View Larger

Improved Resolution of Rod Induction in Neurons Cultured in N21-MAX. E18 rat hippocampal neuron cultures were plated on poly-D-lysine coated coverslips and grown for 5 days in N21-MAX (Catalog # AR008). Neurons were then treated with rod-inducing agents or maintained in N21-MAX alone (Untreated). Neurons were fixed and immunostained for rod formation using an antibody against cofilin (% of Neurons with Rods). The low background of rod formation in untreated cultures enabled detection of mild rod induction using Synthetic Amyloid beta, Amyloid beta dimer/trimer, and TNF-alpha. As a positive control, treatment with an ATP depletion solution or glutamate resulted in robust rod induction. Data courtesy of the laboratory of Dr. James Bamburg at Colorado State University.

Cell Differentiation/ Maturation N21-MAX Media Supplement Enhances Synaptic Development. View Larger

N21-MAX Media Supplement Enhances Synaptic Development. E18 rat hippocampal neurons were grown for 19 days in vitro in media supplemented with either N21-MAX Media Supplement or the neural media supplement from the most widely-used competitor. Cells were incubated with the synaptic vesicle dye, SynaptoRedC2 (10 µM; Catalog # 5118), for 1 minute prior to depolarization with 50 mM KCl. Cells were imaged for SynaptoRedC2-positive synaptic puncta using the Operetta CLSHigh Content Analysis System. (A) Quantification of SynaptoRedC2-positive puncta shows that neurons grown in N21-MAX have an increased number of synaptic puncta compared to the competitor media. (B) Quantification of dye intensity shows that neurons grown in N21-MAX have more robust synaptic activity than neurons cultured in the competitor media. (C) Representative images of SynaptoRed-C2 staining in neurons cultured in N21-MAX or competitor media. (D) Representative images showing the quantification of synaptic puncta in neurons cultured in N21-MAX or competitor media. Colored circles indicate a SynaptoRed-positive synaptic puncta.

Immunocytochemistry Synaptotagmin and CAM Kinase II Expression in Neurons Cultured in Media Supplemented with N21-MAX. View Larger

Synaptotagmin and CAM Kinase II Expression in Neurons Cultured in Media Supplemented with N21-MAX. Synaptotagmin and CAM Kinase II Expression in Neurons Cultured in Media Supplemented with N21-MAX.E18 rat hippocampal neurons were grown for 21 daysin vitroin media supplemented with N21-MAX Media Supplement (Catalog # AR008). Cells were stained with either (A) a Mouse Anti-Rat Synaptotagmin-1 Monoclonal Antibody (Catalog # MAB4364), followed by the NorthernLights(NL)557-conjugated Donkey Anti-Mouse IgG Secondary Antibody (Catalog # NL007; yellow), or (B) a Mouse Anti-Human CaM Kinase II alpha Monoclonal Antibody (Catalog # MAB5584), followed by the NL557-conjugated Donkey Anti-Mouse IgG Secondary Antibody (Catalog # NL007; green). The nuclei were counterstained with DAPI (blue). View our protocol for Fluorescent ICC Staining of Cells on Coverslips.

Cell Differentiation/ Maturation Increased Synaptic Puncta and Neurite Outgrowth of Primary Neurons Cultured in N21-MAX. View Larger

Increased Synaptic Puncta and Neurite Outgrowth of Primary Neurons Cultured in N21-MAX. Increased Synaptic Puncta and Neurite Outgrowth of Primary Neurons Cultured in N21-MAX.E18 rat hippocampal neurons were grown for 21 daysin vitroin media supplemented with either N21-MAX Media Supplement (Catalog # AR008) or the neural media supplement from the most widely-used competitor. Staining for Synaptotagmin (yellow) showed more robust synaptic puncta and increased neurite outgrowth in neurons cultured in N21-MAX compared to those cultured in competitor media. Cells were staineed with a Mouse Anti-Rat Synaptotagmin-1 Monoclonal Antibody (Catalog # MAB4364) followed by the NorthernLights(NL)557-conjugated Donkey Anti-Mouse IgG Secondary Antibody (Catalog # NL007). Nuclei were counterstained with DAPI (blue).

Flow Cytometry N21-MAX Media Supplement Increases Efficiency of Pancreatic Cell Differentiation.  View Larger

N21-MAX Media Supplement Increases Efficiency of Pancreatic Cell Differentiation.  N21-MAX Media Supplement Increases Efficiency of Pancreatic Cell Differentiation.Differentiation of PDX-1+pancreatic cells from induced pluripotent stem cells (iPS2) was performed with base media containing either the N21-MAX Media Supplement (green) or the competitor equivalent (red).A) Compared to competitor media, N21-MAX improved pancreatic cell differentiation as observed by flow cytometry.B) Bar graph quantifying PDX-1+cells in N21-MAX and the competitor media.

Assay Procedure

Refer to the product datasheet for complete product details.

Briefly, completed N21-MAX-supplemented medium is prepared using the following procedure:

  • Dilute the media supplement in basal media
  • Store completed media
  • Use within 2 weeks

Reagents Provided

Reagents provided in the N21-MAX Media Supplement (Catalog # AR008):

  • Albumin (bovine)
  • L-Carnitine
  • Catalase
  • Corticosterone
  • Ethanolamine
  • Glutathione
  • Galactose
  • Holo-Transferrin
  • Insulin
  • Linoleic Acid
  • Linolenic Acid
  • Lipoic Acid
  • Progesterone
  • Putrescine
  • Retinyl acetate
  • Retinol
  • Selenite
  • Superoxide dismutase
  • Triiodo-L-thyronine
  • D,L-alpha-Tocopherol
  • D,L-alpha-Tocopherol acetate
 

Other Supplies Required

Reagents

  • Basal media (e.g., Neurobasal Media from Invitrogen®, Catalog # 21103-029 or equivalent)
  • L-Glutamine

Materials

  • Serological pipettes
  • Pipettes and pipette tips

Equipment

  • 2 °C to 8 °C refrigerator

Protocol Overview

Dilute 50-fold with a basal media (e.g., Neurobasal Media from Invitrogen, Catalog # 21103-029) and supplement with 0.5 mM L-glutamine before use. The medium may be stored in the dark at 2 °C to 8 °C for up to 2 weeks.

 

Invitrogen is a registered trademark of Invitrogen Corp.

Citations for N21-MAX Media Supplement (50X)

R&D Systems personnel manually curate a database that contains references using R&D Systems products. The data collected includes not only links to publications in PubMed, but also provides information about sample types, species, and experimental conditions.

26 Citations: Showing 1 - 10
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  1. Fluorescent identification of axons, dendrites and soma of neuronal retinal ganglion cells with a genetic marker as a tool for facilitating the study of neurodegeneration
    Authors: Sripinun, P;Lu, W;Nikonov, S;Patel, S;Hennessy, S;Bell, BA;Mitchell, CH;
    bioRxiv : the preprint server for biology  2024-06-25
  2. Activity-driven synaptic translocation of LGI1 controls excitatory neurotransmission
    Authors: Cuhadar, U;Calzado-Reyes, L;Pascual-Caro, C;Aberra, AS;Ritzau-Jost, A;Aggarwal, A;Ibata, K;Podgorski, K;Yuzaki, M;Geis, C;Hallerman, S;Hoppa, MB;de Juan-Sanz, J;
    Cell reports  2024-05-02
  3. ?-Synuclein triggers cofilin pathology and dendritic spine impairment via a PrPC-CCR5 dependent pathway
    Authors: Oliveira da Silva, MI;Santejo, M;Babcock, IW;Magalhães, A;Minamide, LS;Won, SJ;Castillo, E;Gerhardt, E;Fahlbusch, C;Swanson, RA;Outeiro, TF;Taipa, R;Ruff, M;Bamburg, JR;Liz, MA;
    Cell death & disease  2024-04-13
  4. Mitochondrial pyruvate transport regulates presynaptic metabolism and neurotransmission
    Authors: Tiwari, A;Myeong, J;Hashemiaghdam, A;Zhang, H;Niu, X;Laramie, MA;Stunault, MI;Sponagel, J;Patti, G;Shriver, L;Klyachko, V;Ashrafi, G;
    bioRxiv : the preprint server for biology  2024-03-20
  5. Neuronal miR-9 promotes HSV-1 epigenetic silencing and latency by repressing Oct-1 and Onecut family genes
    Authors: Deng, Y;Lin, Y;Chen, S;Xiang, Y;Chen, H;Qi, S;Oh, HS;Das, B;Komazin-Meredith, G;Pesola, JM;Knipe, DM;Coen, DM;Pan, D;
    Nature communications  2024-03-05
  6. Metabolic Regulation of Single Synaptic Vesicle Exo- and Endocytosis in Hippocampal Synapses
    Authors: Myeong, J;Stunault, MI;Klyachko, VA;Ashrafi, G;
    bioRxiv : the preprint server for biology  2023-11-11
  7. Characterization of a Human Neuronal Culture System for the Study of Cofilin-Actin Rod Pathology
    Authors: Tahtamouni, LH;Alderfer, SA;Kuhn, TB;Minamide, LS;Chanda, S;Ruff, MR;Bamburg, JR;
    Biomedicines  2023-10-31
  8. Interaction between estrogen receptor-? and PNPLA3 p.I148M variant drives fatty liver disease susceptibility in women
    Authors: Cherubini, A;Ostadreza, M;Jamialahmadi, O;Pelusi, S;Rrapaj, E;Casirati, E;Passignani, G;Norouziesfahani, M;Sinopoli, E;Baselli, G;Meda, C;Dongiovanni, P;Dondossola, D;Youngson, N;Tourna, A;Chokshi, S;Bugianesi, E;EPIDEMIC Study Investigators, ;Della Torre, S;Prati, D;Romeo, S;Valenti, L;
    Nature medicine  2023-09-25
  9. Developmental transcriptional control of mitochondrial homeostasis is required for activity-dependent synaptic connectivity
    Authors: Mohylyak, I;Bengochea, M;Pascual-Caro, C;Asfogo, N;Fonseca-Topp, S;Danda, N;Atak, ZK;De Waegeneer, M;Plaçais, PY;Preat, T;Aerts, S;Corti, O;de Juan-Sanz, J;Hassan, BA;
    bioRxiv : the preprint server for biology  2023-06-11
  10. Targeting BRD3 eradicates nuclear TYRO3-induced colorectal cancer metastasis
    Authors: PL Hsu, CW Chien, YA Tang, BW Lin, SC Lin, YS Lin, SY Chen, HS Sun, SJ Tsai
    Science Advances, 2023-04-12;9(15):eade3422.  2023-04-12
  11. Stem-Cell-Derived beta-Like Cells with a Functional PTPN2 Knockout Display Increased Immunogenicity
    Authors: TM Triolo, JQ Matuschek, R Castro-Gut, AH Shilleh, SPM Williams, MS Hansen, K McDaniel, JM Barra, A Michels, HA Russ
    Cells, 2022-11-30;11(23):.  2022-11-30
  12. CNS myelination requires VAMP2/3-mediated membrane expansion in oligodendrocytes
    Authors: M Lam, K Takeo, RG Almeida, MH Cooper, K Wu, M Iyer, H Kantarci, JB Zuchero
    Nature Communications, 2022-09-23;13(1):5583.  2022-09-23
  13. Lysosomal exocytosis releases pathogenic alpha-synuclein species from neurons in synucleinopathy models
    Authors: YX Xie, NN Naseri, J Fels, P Kharel, Y Na, D Lane, J Burré, M Sharma
    Nature Communications, 2022-08-22;13(1):4918.  2022-08-22
  14. Cardiac glycoside-mediated turnover of Na, K-ATPases as a rational approach to reducing cell surface levels of the cellular prion protein
    Authors: M Mehrabian, X Wang, S Eid, BQ Yan, M Grinberg, M Siegner, C Sackmann, M Sulman, W Zhao, D Williams, G Schmitt-Ul
    PLoS ONE, 2022-07-01;17(7):e0270915.  2022-07-01
  15. Impact of schizophrenia GWAS loci converge onto distinct pathways in cortical interneurons vs glutamatergic neurons during development
    Authors: D Liu, A Zinski, A Mishra, H Noh, GH Park, Y Qin, O Olorife, JM Park, CP Abani, JS Park, J Fung, F Sawaqed, JT Coyle, E Stahl, J Bendl, JF Fullard, P Roussos, X Zhang, PK Stanton, C Yin, W Huang, HY Kim, H Won, JH Cho, S Chung
    Molecular Psychiatry, 2022-06-14;0(0):.  2022-06-14
  16. Cis- and trans-resveratrol have opposite effects on histone serine-ADP-ribosylation and tyrosine induced neurodegeneration
    Authors: M Jhanji, CN Rao, JC Massey, MC Hope, X Zhou, CD Keene, T Ma, MD Wyatt, JA Stewart, M Sajish
    Nature Communications, 2022-06-10;13(1):3244.  2022-06-10
  17. The cellular prion protein interacts with and promotes the activity of Na,K-ATPases
    Authors: D Williams, M Mehrabian, H Arshad, S Eid, C Sackmann, W Zhao, X Wang, F Ghodrati, CE Verkuyl, JC Watts, G Schmitt-Ul
    PLoS ONE, 2021-11-30;16(11):e0258682.  2021-11-30
  18. Direct interaction of HIV gp120 with neuronal CXCR4 and CCR5 receptors induces cofilin-actin rod pathology via a cellular prion protein- and NOX-dependent mechanism
    Authors: LK Smith, IW Babcock, LS Minamide, AE Shaw, JR Bamburg, TB Kuhn
    PLoS ONE, 2021-03-11;16(3):e0248309.  2021-03-11
  19. Regulation of host and virus genes by neuronal miR-138 favours herpes simplex virus 1 latency
    Authors: B Sun, X Yang, F Hou, X Yu, Q Wang, HS Oh, P Raja, JM Pesola, EAH Vanni, S McCarron, J Morris-Lov, AHM Ng, GM Church, DM Knipe, DM Coen, D Pan
    Nature Microbiology, 2021-02-08;0(0):.  2021-02-08
  20. Live Neuron High-Content Screening Reveals Synaptotoxic Activity in Alzheimer Mouse Model Homogenates
    Authors: H Jiang, TJ Esparza, TT Kummer, H Zhong, J Rettig, DL Brody
    Sci Rep, 2020-02-25;10(1):3412.  2020-02-25
  21. Silencing of AURKA augments the antitumor efficacy of the AURKA inhibitor MLN8237 on neuroblastoma cells
    Authors: Y Yang, L Ding, Q Zhou, L Fen, Y Cao, J Sun, X Zhou, A Liu
    Cancer Cell Int., 2020-01-07;20(0):9.  2020-01-07
  22. Tau interactome analyses in CRISPR-Cas9 engineered neuronal cells reveal ATPase-dependent binding of wild-type but not P301L Tau to non-muscle myosins
    Authors: X Wang, D Williams, I Müller, M Lemieux, R Dukart, IBL Maia, H Wang, AL Woerman, G Schmitt-Ul
    Sci Rep, 2019-11-07;9(1):16238.  2019-11-07
  23. Neural stem cell small extracellular vesicle-based delivery of 14-3-3t reduces apoptosis and neuroinflammation following traumatic spinal cord injury by enhancing autophagy by targeting Beclin-1
    Authors: Y Rong, W Liu, C Lv, J Wang, Y Luo, D Jiang, L Li, Z Zhou, W Zhou, Q Li, G Yin, L Yu, J Fan, W Cai
    Aging (Albany NY), 2019-09-28;11(18):7723-7745.  2019-09-28
  24. Axonal G3BP1 stress granule protein limits axonal mRNA translation and nerve regeneration
    Authors: PK Sahoo, SJ Lee, PB Jaiswal, S Alber, AN Kar, S Miller-Ran, EE Taylor, T Smith, B Singh, TS Ho, A Urisman, S Chand, EA Pena, AL Burlingame, CJ Woolf, M Fainzilber, AW English, JL Twiss
    Nat Commun, 2018-08-22;9(1):3358.  2018-08-22
  25. Stemness-Attenuating miR-503-3p as a Paracrine Factor to Regulate Growth of Cancer Stem Cells
    Authors: M Seo, SM Kim, EY Woo, KC Han, EJ Park, S Ko, EW Choi, M Jang
    Stem Cells Int, 2018-04-04;2018(0):4851949.  2018-04-04
  26. Development of a central nervous system axonal myelination assay for high throughput screening.
    Authors: Lariosa-Willingham K, Rosler E, Tung J, Dugas J, Collins T, Leonoudakis D
    BMC Neurosci, 2016-04-22;17(0):16.  2016-04-22

FAQs

  1. What advantages does the N21-MAX Media Supplement (Catalog # AR008) have over other neuronal stem cell supplements?

    • We have performed comparison testing in-house and have found that in long term cultures (21 days), we observe better synapse marker expression.

      Additionally, one major formulation difference is that our N21 contains holo-transferrin while other supplements typically contain apo-transferrin. It is reported in the literature that holo-transferrin is preferred for neuronal cell culture. We have also tested several BSA sources to determine which is optimal for neuronal cultures.

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Reviews for N21-MAX Media Supplement (50X)

Average Rating: 4.3 (Based on 6 Reviews)

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N21-MAX Media Supplement (50X)
By Lucia Lisi on 05/19/2021
N21-MAX Media Supplement (50X) AR008
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By Anonymous on 12/20/2018
N21-MAX Media Supplement (50X) AR008
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By Leslie Priddy on 04/04/2018
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By Anonymous on 10/30/2017
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