Study Cell Proliferation With
Quantitative Live Cell Imaging

cells quantitative cell imaging

Reuse cells

to save your time and money

multiple assay quantitative cell imaging

Multiple assays

from one single cell sample

Results quantitative cell imaging

Accurate results

with direct cell count

Why Quantitative Cell Imaging Over MTT Assay?

M4 sketch

Live Cell Imaging

  • Label-free
  • Direct cell count
  • No preparation needed
  • Real-time assay
  • Single-cell resolution
  • Quantitative

MTT assay

  • Cytotoxic
  • Indirect metabolism activity
  • Reagent preparation needed
  • Endpoint assay
  • Only population-level data
  • Qualitative
The HoloMonitor live cell imager viewed from the front

Meet HoloMonitor®

Our Live Cell Imaging Microscope

  • Label-free and high automation
  • More biological relevant and less labor-intensive
  • Real-time monitoring directly from the incubator
  • Robust system with standard cell culture vessels

Use your cells for more than proliferation

HoloMonitor’s cell-friendly nature makes it an ideal tool for viewing and analyzing live cell cultures. All HoloMonitor live cell assays are label-free, reducing the risk of unwanted toxicity and allowing cell samples to be reused. Hence, HoloMonitor saves your time and money. But foremost, save hard-to-get cells.

Stanford University logo

The HoloMonitor M4 is a beneficial device for live-cell imaging, providing a lot of data. The good thing is that you can analyze your experiment using one software assay, and later, you can rerun the recorded data in another assay, which allows you to get the maximum from your experiment. I like it and would recommend it to all people doing a cytotoxicity assessment based on cell proliferation and optical thickness of the adherent unstained cells.

Sasa Vasilijic, PhD
Stanford University

Get multiple results from just one sample

Achieve better cell proliferation data

Unlike the MTT assay, which only gives end-point data, HoloMonitor measures kinetic cellular characteristics at multiple time points in real-time. Hence, you can simultaneously compare the temporal effects of multiple treatments and/or conditions. Moreover, you can re-analyze your results with other HoloMonitor assays to generate more data without setting up new experiments.

Proliferation data with quantitative imaging

  • Real-time growth curves with or without normalization:
    • Cell count (cells/cm2)
    • Confluence (%)
  • Multiwell cell images and time-lapse videos
cell-proliferation-by-cell-count
cell-proliferation-by-confluence
cell-proliferation-with-normalization-by-cell-count
cell-proliferation-with-normolization-by-confluence
White cells on yellow background. Four panels showing a cell divide into two.

Get accurate data with digital holography

HoloMonitor uses digital holographic microscopy to collect publication-quality images without any labels. In addition, you receive accurate quantitative data. This way, you can study over 30 cell morphology parameters from a single sample and quantify cell behavior changes on both single-cell and population levels.

Bring Quantitative Imaging To Your Incubator

Label-free time-lapse video of cells proliferating over time imaged by HoloMonitor.

Publications with cell proliferation studies

Get inspired by other research fellows and learn how HoloMonitor quantitative live cell imaging can benefit your cell proliferation study

Four-day time-lapse quantitative phase imaging of cytokinesis failure in primary melanocytes transduced with MIR211-5p.

BRAFV600E induces reversible mitotic arrest in human melanocytes via microRNA-mediated suppression of AURKB

Authors: McNeal et al. Journal: eLife (2021)

In this study, to investigate why the same mutation has such different consequences in moles and melanomas, the authors using HoloMonitor studied cell proliferation, cell dry mass, cell death and cell growth rate. The experiments showed by increasing the levels of two microRNAs in melanocytes induces mitotic failure, genome duplication, and proliferation arrest. BRAFV600E induces a similar proliferation arrest in primary human melanocytes that is both reversible and conditional depending on the differentiation state of the melanocyte. Read more…

Targeted Delivery of Combination Therapeutics Using Monoclonal Antibody 2C5-Modified Immunoliposomes for Cancer Therapy

Authors: R. Narayanaswamy et al. Journal: Pharmaceutical Research (2021)

In this study, the authors have used monoclonal antibody-modified immunoliposomes for the targeted delivery of paclitaxel and salinomycin for cancer therapy. By using HoloMonitor M4, the authors measured the cell morphology, proliferation and cell division change between treatments, the results confirmed the efficacy of the antibody-targeted liposomal preparation in the therapy of cancer by giving significantly better cellular division arrest profiles and cell death. Read more…

Targeted Delivery of Combination Therapeutics Using Monoclonal Antibody 2C5-Modified Immunoliposomes for Cancer Therapy

Authors: Radhika Narayanaswamy et al.

Journal: Pharmaceutical Research (2021)

Research Areas: Drug research

Cell Lines: MDA-MD-231

Keywords: HoloMonitor M4, cell Proliferation and cell Morphology, cancer therapy

Learn more …

Cytoplasmic localization of prostate-specific membrane antigen inhibitors may confer advantages for targeted cancer therapies

Authors: essica Matthias et al.

Journal: Cancer Research (2021)

Research Areas: Cytotoxicity

Cell Lines: LNCaP and 22Rv1

Keywords: HoloMonitor M4, Cell Proliferation

Learn more …

Improved Autophagic Flux in Escapers from Doxorubicin-Induced Senescence/Polyploidy of Breast Cancer Cells

Authors: Agnieszka Bojko et al.

Journal: International Journal of Molecular Sciences (2020)

Research Areas: Cancer research

Cell Lines: MDA-MD-231

Keywords: HoloMonitor M4, Cell proliferation, autophagy, autophagic index, cancer, DNA damage, SQSTM1/p62, polyploidy, senescence, senescence escape, TFEB, Rubicon

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Defining COMMD4 as an anti-cancer therapeutic target and prognostic factor in non-small cell lung cancer

Authors: Amila Suraweera et al.

Journal: British Journal of Cancer (2020)

Research Areas: Cancer research

Cell Lines: HBEC3-KT, H460, H1975, CRL5889

Keywords: HoloMonitor M4, Cell proliferation, Non-small cell lung cancers, COMMD4

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Exosomes derived from mesenchymal stem cells repair a Parkinson’s disease model by inducing autophagy

Authors: Hong-Xu Chen et al.

Journal: Cell Death and Disease (2020)

Research Areas: Stem cell research

Cell Lines: hucMSC

Keywords: HoloMonitor M4, cell proliferation, mesenchymal stem cells, stem cell therapy

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Synthesis of a dihalogenated pyridinyl silicon rhodamine for mitochondrial imaging by a halogen dance rearrangement

Authors: Jessica Matthias et al.

Journal: Beilstein J. Org. Chem (2019)

Research Areas: Materials of Science

Cell Lines: U2OS

Keywords: HoloMonitor M4, cell proliferation, halogen-dance reaction, mitochondrial probe, near-infrared (NIR) dyes, one-pot reaction, silicon rhodamines, Flourofore synthesis

Learn more …