Molecular imaging of tumors with nanobodies and antibodies: Timing and dosage are crucial factors for improved in vivo detection

Peter Bannas; Alexander Lenz; Valentin Kunick; Lennart Well; William Fumey; Björn Rissiek; Friedrich Haag; Joanna Schmid; Kerstin Schütze; Anna Eichhoff; Martin Trepel; Gerhard Adam; Harald Ittrich; Friedrich Koch-Nolte

doi:10.1002/cmmi.1637

Molecular imaging of tumors with nanobodies and antibodies: Timing and dosage are crucial factors for improved in vivo detection

Standard

Molecular imaging of tumors with nanobodies and antibodies: Timing and dosage are crucial factors for improved in vivo detection. / Bannas, Peter ; Lenz, Alexander; Kunick, Valentin; Well, Lennart; Fumey, William; Rissiek, Björn ; Haag, Friedrich; Schmid, Joanna; Schütze, Kerstin; Eichhoff, Anna; Trepel, Martin; Adam, Gerhard; Ittrich, Harald; Koch-Nolte, Friedrich.

in: CONTRAST MEDIA MOL I, Jahrgang 10, Nr. 5, 27.04.2015, S. 367-378.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Bannas, P , Lenz, A, Kunick, V, Well, L, Fumey, W, Rissiek, B , Haag, F, Schmid, J, Schütze, K, Eichhoff, A, Trepel, M, Adam, G, Ittrich, H & Koch-Nolte, F 2015, 'Molecular imaging of tumors with nanobodies and antibodies: Timing and dosage are crucial factors for improved in vivo detection', CONTRAST MEDIA MOL I, Jg. 10, Nr. 5, S. 367-378. https://doi.org/10.1002/cmmi.1637

APA

Bannas, P., Lenz, A., Kunick, V., Well, L., Fumey, W., Rissiek, B., Haag, F., Schmid, J., Schütze, K., Eichhoff, A., Trepel, M., Adam, G., Ittrich, H., & Koch-Nolte, F. (2015). Molecular imaging of tumors with nanobodies and antibodies: Timing and dosage are crucial factors for improved in vivo detection. CONTRAST MEDIA MOL I, 10(5), 367-378. https://doi.org/10.1002/cmmi.1637

Vancouver

Bannas P , Lenz A, Kunick V, Well L, Fumey W, Rissiek B et al. Molecular imaging of tumors with nanobodies and antibodies: Timing and dosage are crucial factors for improved in vivo detection. CONTRAST MEDIA MOL I. 2015 Apr 27;10(5):367-378. https://doi.org/10.1002/cmmi.1637

Bibtex

@article{216ff57c6c9e4cbea599b4c60c875458,

title = "Molecular imaging of tumors with nanobodies and antibodies: Timing and dosage are crucial factors for improved in vivo detection",

abstract = "The utility of nanobodies and conventional antibodies for in vivo imaging is well known, but optimum dosing and timing schedules for one versus the other have not been established. We aimed to improve specific tumor imaging in vivo with nanobodies and conventional antibodies using near-infrared fluorescence (NIRF) imaging. We used ARTC2 expressed on lymphoma cells as a model target antigen. ARTC2-specific nanobody s+16a and conventional antibody Nika102 were labeled with NIRF-dye AF680. In vivo NIRF-imaging of ARTC2-positive and ARTC2-negative xenografts was performed over 24 h post-injection of 5, 10, 25, or 50 µg of each conjugate. Specific target-binding and tissue-penetration were verified by NIRF imaging ex vivo, flow cytometry and fluorescence microscopy. NIRF-imaging of s+16a(680) in vivo revealed a six times faster tumor accumulation than of Nika102(680) . Using 50 µg of s+16a(680) increased the specific signals of ARTC2-positive tumors without increasing background signals, allowing a tumor-to-background (T/B) ratio of 12.4 ± 4.2 within 6 h post-injection. Fifty micrograms of Nika102(680) increased specific signals of ARTC2-positive tumors but also of ARTC2-negative tumors and background, thereby limiting the T/B ratio to 6.1 ± 2.0. Ten micrograms of Nika102(680) only slightly reduced specific tumor signals but dramatically reduced background signals. Ex vivo analyses confirmed a faster and deeper tumor penetration with s+16a(680) . Using nanobody s+16a allowed same-day imaging with a high T/B ratio, whereas antibody Nika102 gave optimal imaging results only 24 h post injection. Nanobody s+16a required a high dose, whereas antibody Nika102 had the best T/B-ratio at a low dose. Therefore, timing and dosage should be addressed when comparing nanobodies and conventional antibodies for molecular imaging purposes. Copyright {\textcopyright} 2015 John Wiley & Sons, Ltd.",

author = "Peter Bannas and Alexander Lenz and Valentin Kunick and Lennart Well and William Fumey and Bj{\"o}rn Rissiek and Friedrich Haag and Joanna Schmid and Kerstin Sch{\"u}tze and Anna Eichhoff and Martin Trepel and Gerhard Adam and Harald Ittrich and Friedrich Koch-Nolte",

note = "Copyright {\textcopyright} 2015 John Wiley & Sons, Ltd.",

year = "2015",

month = apr,

day = "27",

doi = "10.1002/cmmi.1637",

language = "English",

volume = "10",

pages = "367--378",

journal = "CONTRAST MEDIA MOL I",

issn = "1555-4309",

publisher = "John Wiley and Sons Ltd",

number = "5",

}

RIS

TY - JOUR

T1 - Molecular imaging of tumors with nanobodies and antibodies: Timing and dosage are crucial factors for improved in vivo detection

AU - Bannas, Peter

AU - Lenz, Alexander

AU - Kunick, Valentin

AU - Well, Lennart

AU - Fumey, William

AU - Rissiek, Björn

AU - Haag, Friedrich

AU - Schmid, Joanna

AU - Schütze, Kerstin

AU - Eichhoff, Anna

AU - Trepel, Martin

AU - Adam, Gerhard

AU - Ittrich, Harald

AU - Koch-Nolte, Friedrich

PY - 2015/4/27

Y1 - 2015/4/27

N2 - The utility of nanobodies and conventional antibodies for in vivo imaging is well known, but optimum dosing and timing schedules for one versus the other have not been established. We aimed to improve specific tumor imaging in vivo with nanobodies and conventional antibodies using near-infrared fluorescence (NIRF) imaging. We used ARTC2 expressed on lymphoma cells as a model target antigen. ARTC2-specific nanobody s+16a and conventional antibody Nika102 were labeled with NIRF-dye AF680. In vivo NIRF-imaging of ARTC2-positive and ARTC2-negative xenografts was performed over 24 h post-injection of 5, 10, 25, or 50 µg of each conjugate. Specific target-binding and tissue-penetration were verified by NIRF imaging ex vivo, flow cytometry and fluorescence microscopy. NIRF-imaging of s+16a(680) in vivo revealed a six times faster tumor accumulation than of Nika102(680) . Using 50 µg of s+16a(680) increased the specific signals of ARTC2-positive tumors without increasing background signals, allowing a tumor-to-background (T/B) ratio of 12.4 ± 4.2 within 6 h post-injection. Fifty micrograms of Nika102(680) increased specific signals of ARTC2-positive tumors but also of ARTC2-negative tumors and background, thereby limiting the T/B ratio to 6.1 ± 2.0. Ten micrograms of Nika102(680) only slightly reduced specific tumor signals but dramatically reduced background signals. Ex vivo analyses confirmed a faster and deeper tumor penetration with s+16a(680) . Using nanobody s+16a allowed same-day imaging with a high T/B ratio, whereas antibody Nika102 gave optimal imaging results only 24 h post injection. Nanobody s+16a required a high dose, whereas antibody Nika102 had the best T/B-ratio at a low dose. Therefore, timing and dosage should be addressed when comparing nanobodies and conventional antibodies for molecular imaging purposes. Copyright © 2015 John Wiley & Sons, Ltd.

AB - The utility of nanobodies and conventional antibodies for in vivo imaging is well known, but optimum dosing and timing schedules for one versus the other have not been established. We aimed to improve specific tumor imaging in vivo with nanobodies and conventional antibodies using near-infrared fluorescence (NIRF) imaging. We used ARTC2 expressed on lymphoma cells as a model target antigen. ARTC2-specific nanobody s+16a and conventional antibody Nika102 were labeled with NIRF-dye AF680. In vivo NIRF-imaging of ARTC2-positive and ARTC2-negative xenografts was performed over 24 h post-injection of 5, 10, 25, or 50 µg of each conjugate. Specific target-binding and tissue-penetration were verified by NIRF imaging ex vivo, flow cytometry and fluorescence microscopy. NIRF-imaging of s+16a(680) in vivo revealed a six times faster tumor accumulation than of Nika102(680) . Using 50 µg of s+16a(680) increased the specific signals of ARTC2-positive tumors without increasing background signals, allowing a tumor-to-background (T/B) ratio of 12.4 ± 4.2 within 6 h post-injection. Fifty micrograms of Nika102(680) increased specific signals of ARTC2-positive tumors but also of ARTC2-negative tumors and background, thereby limiting the T/B ratio to 6.1 ± 2.0. Ten micrograms of Nika102(680) only slightly reduced specific tumor signals but dramatically reduced background signals. Ex vivo analyses confirmed a faster and deeper tumor penetration with s+16a(680) . Using nanobody s+16a allowed same-day imaging with a high T/B ratio, whereas antibody Nika102 gave optimal imaging results only 24 h post injection. Nanobody s+16a required a high dose, whereas antibody Nika102 had the best T/B-ratio at a low dose. Therefore, timing and dosage should be addressed when comparing nanobodies and conventional antibodies for molecular imaging purposes. Copyright © 2015 John Wiley & Sons, Ltd.

U2 - 10.1002/cmmi.1637

DO - 10.1002/cmmi.1637

M3 - SCORING: Journal article

C2 - 25925493

VL - 10

SP - 367

EP - 378

JO - CONTRAST MEDIA MOL I

JF - CONTRAST MEDIA MOL I

SN - 1555-4309

IS - 5

ER -