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serum-free α-minimum essential medium 15-010-cv  (Corning Life Sciences)

 
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    Corning Life Sciences serum-free α-minimum essential medium 15-010-cv
    Characterization of ATmf bio‐inks. A) Sequential steps outlining the preparation of the ATmf bio‐ink. B–E) Mechanical analysis of the ATmf bio‐ink based on the ATmf concentration (%v/v): shear sweep analysis (B), dynamic frequency sweep (C), loss tangent (tan 𝛿), and (D), and compressive modulus (E) (n = 5). F,G) Results of 2D printability tests of the ATmf bio‐ink: <t>printable</t> <t>minimum</t> line width (F) and pore fidelity (G) (n = 5) measured after printing 2D line patterns and rectangular pores, respectively. H) Thickness measurements of multilayered structures printed with ATmf bio‐inks (n = 5). Multilayered structures are printed with varying ATmf contents to analyze 3D printability, and their thicknesses are measured. Error bars indicate standard deviations. (*p < 0.05; **p < 0.01; ***p < 0.001).
    Serum Free α Minimum Essential Medium 15 010 Cv, supplied by Corning Life Sciences, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/serum-free α-minimum essential medium 15-010-cv/product/Corning Life Sciences
    Average 90 stars, based on 1 article reviews
    serum-free α-minimum essential medium 15-010-cv - by Bioz Stars, 2026-03
    90/100 stars

    Images

    1) Product Images from "Clinically Relevant and Precisely Printable Live Adipose Tissue–Based Bio‐Ink for Volumetric Soft Tissue Reconstruction"

    Article Title: Clinically Relevant and Precisely Printable Live Adipose Tissue–Based Bio‐Ink for Volumetric Soft Tissue Reconstruction

    Journal: Advanced Healthcare Materials

    doi: 10.1002/adhm.202402680

    Characterization of ATmf bio‐inks. A) Sequential steps outlining the preparation of the ATmf bio‐ink. B–E) Mechanical analysis of the ATmf bio‐ink based on the ATmf concentration (%v/v): shear sweep analysis (B), dynamic frequency sweep (C), loss tangent (tan 𝛿), and (D), and compressive modulus (E) (n = 5). F,G) Results of 2D printability tests of the ATmf bio‐ink: printable minimum line width (F) and pore fidelity (G) (n = 5) measured after printing 2D line patterns and rectangular pores, respectively. H) Thickness measurements of multilayered structures printed with ATmf bio‐inks (n = 5). Multilayered structures are printed with varying ATmf contents to analyze 3D printability, and their thicknesses are measured. Error bars indicate standard deviations. (*p < 0.05; **p < 0.01; ***p < 0.001).
    Figure Legend Snippet: Characterization of ATmf bio‐inks. A) Sequential steps outlining the preparation of the ATmf bio‐ink. B–E) Mechanical analysis of the ATmf bio‐ink based on the ATmf concentration (%v/v): shear sweep analysis (B), dynamic frequency sweep (C), loss tangent (tan 𝛿), and (D), and compressive modulus (E) (n = 5). F,G) Results of 2D printability tests of the ATmf bio‐ink: printable minimum line width (F) and pore fidelity (G) (n = 5) measured after printing 2D line patterns and rectangular pores, respectively. H) Thickness measurements of multilayered structures printed with ATmf bio‐inks (n = 5). Multilayered structures are printed with varying ATmf contents to analyze 3D printability, and their thicknesses are measured. Error bars indicate standard deviations. (*p < 0.05; **p < 0.01; ***p < 0.001).

    Techniques Used: Concentration Assay, Shear



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    Characterization of ATmf bio‐inks. A) Sequential steps outlining the preparation of the ATmf bio‐ink. B–E) Mechanical analysis of the ATmf bio‐ink based on the ATmf concentration (%v/v): shear sweep analysis (B), dynamic frequency sweep (C), loss tangent (tan 𝛿), and (D), and compressive modulus (E) (n = 5). F,G) Results of 2D printability tests of the ATmf bio‐ink: <t>printable</t> <t>minimum</t> line width (F) and pore fidelity (G) (n = 5) measured after printing 2D line patterns and rectangular pores, respectively. H) Thickness measurements of multilayered structures printed with ATmf bio‐inks (n = 5). Multilayered structures are printed with varying ATmf contents to analyze 3D printability, and their thicknesses are measured. Error bars indicate standard deviations. (*p < 0.05; **p < 0.01; ***p < 0.001).
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    Characterization of ATmf bio‐inks. A) Sequential steps outlining the preparation of the ATmf bio‐ink. B–E) Mechanical analysis of the ATmf bio‐ink based on the ATmf concentration (%v/v): shear sweep analysis (B), dynamic frequency sweep (C), loss tangent (tan 𝛿), and (D), and compressive modulus (E) (n = 5). F,G) Results of 2D printability tests of the ATmf bio‐ink: <t>printable</t> <t>minimum</t> line width (F) and pore fidelity (G) (n = 5) measured after printing 2D line patterns and rectangular pores, respectively. H) Thickness measurements of multilayered structures printed with ATmf bio‐inks (n = 5). Multilayered structures are printed with varying ATmf contents to analyze 3D printability, and their thicknesses are measured. Error bars indicate standard deviations. (*p < 0.05; **p < 0.01; ***p < 0.001).
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    Characterization of ATmf bio‐inks. A) Sequential steps outlining the preparation of the ATmf bio‐ink. B–E) Mechanical analysis of the ATmf bio‐ink based on the ATmf concentration (%v/v): shear sweep analysis (B), dynamic frequency sweep (C), loss tangent (tan 𝛿), and (D), and compressive modulus (E) (n = 5). F,G) Results of 2D printability tests of the ATmf bio‐ink: <t>printable</t> <t>minimum</t> line width (F) and pore fidelity (G) (n = 5) measured after printing 2D line patterns and rectangular pores, respectively. H) Thickness measurements of multilayered structures printed with ATmf bio‐inks (n = 5). Multilayered structures are printed with varying ATmf contents to analyze 3D printability, and their thicknesses are measured. Error bars indicate standard deviations. (*p < 0.05; **p < 0.01; ***p < 0.001).
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    Characterization of ATmf bio‐inks. A) Sequential steps outlining the preparation of the ATmf bio‐ink. B–E) Mechanical analysis of the ATmf bio‐ink based on the ATmf concentration (%v/v): shear sweep analysis (B), dynamic frequency sweep (C), loss tangent (tan 𝛿), and (D), and compressive modulus (E) (n = 5). F,G) Results of 2D printability tests of the ATmf bio‐ink: printable minimum line width (F) and pore fidelity (G) (n = 5) measured after printing 2D line patterns and rectangular pores, respectively. H) Thickness measurements of multilayered structures printed with ATmf bio‐inks (n = 5). Multilayered structures are printed with varying ATmf contents to analyze 3D printability, and their thicknesses are measured. Error bars indicate standard deviations. (*p < 0.05; **p < 0.01; ***p < 0.001).

    Journal: Advanced Healthcare Materials

    Article Title: Clinically Relevant and Precisely Printable Live Adipose Tissue–Based Bio‐Ink for Volumetric Soft Tissue Reconstruction

    doi: 10.1002/adhm.202402680

    Figure Lengend Snippet: Characterization of ATmf bio‐inks. A) Sequential steps outlining the preparation of the ATmf bio‐ink. B–E) Mechanical analysis of the ATmf bio‐ink based on the ATmf concentration (%v/v): shear sweep analysis (B), dynamic frequency sweep (C), loss tangent (tan 𝛿), and (D), and compressive modulus (E) (n = 5). F,G) Results of 2D printability tests of the ATmf bio‐ink: printable minimum line width (F) and pore fidelity (G) (n = 5) measured after printing 2D line patterns and rectangular pores, respectively. H) Thickness measurements of multilayered structures printed with ATmf bio‐inks (n = 5). Multilayered structures are printed with varying ATmf contents to analyze 3D printability, and their thicknesses are measured. Error bars indicate standard deviations. (*p < 0.05; **p < 0.01; ***p < 0.001).

    Article Snippet: To prepare the ATmf bio‐ink, a fibrinogen/gelatin mixture was prepared through the following steps: 3 mg mL− 1 of hyaluronic acid (935166, Millipore Sigma, MA, USA) was dissolved in serum‐free α‐minimum essential medium (MEM, 15‐010‐CV, Corning, NY, USA) overnight by gentle rotation at 37 °C in an oven.

    Techniques: Concentration Assay, Shear