Publications
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Francisella tularensis subsp. novicida (U112), Escherichia coli (P4), and Pseudomonas aeruginosa (PAO1)
Drug Discovery, Preclinical Studies
Human GD2 TRAC-CAR T cells
Mitochondrial Programming & Dysfunction, Cell therapy CQA/QC Assessment & Monitoring, Immunometabolism
MA-10 mouse Leydig tumor cells
Reproductive Biology, Mitochondrial Programming & Dysfunction
Patient-derived primary skin fibroblasts & healthy-donor control fibroblasts
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling
HBE (16HBE14o⁻ human bronchial epithelial) cells and FRT (Fisher rat thyroid) epithelial cells, expressing mutations
Mitochondrial Programming & Dysfunction, Drug Discovery, Obesity, Diabetes & Aging, Preclinical Studies
Amphidinium carterae (strain CCMP 1314) and Symbiodinium natans (strain CCMP 2548)
Mitochondrial Programming & Dysfunction
HBE (human bronchial epithelial cells) & FRT (Fischer rat thyroid epithelial cells)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Drug Discovery, Obesity, Diabetes & Aging
Chlorella vulgaris (strain CCALA 269) & Scenedesmus sp. (strain CCALA 1074)
human HepaRG cells
Mitochondrial Programming & Dysfunction, Preclinical Studies, Obesity, Diabetes & Aging
A549 human lung cancer cells
Mitochondrial Programming & Dysfunction, Preclinical Studies, Cancer, Cell & Tissue Modeling
OCI-AML3 cells (human AML cell line)
Cancer, Mitochondrial Programming & Dysfunction
Bioprinted rat islets of Langerhans, Scenedesmus sp. microalgae, and the islet/microalgae co-culture
Hypoxia and Normoxia Assessment & Monitoring, Obesity, Diabetes & Aging
Primary mouse bone marrow–derived macrophages (BMDMs)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Immunometabolism
Hek293
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Obesity, Diabetes & Aging
Patient-derived ovarian cancer cells (ascites-derived, carcinosarcoma derived and tumor tissue derived)
Drug Discovery, Cancer, Preclinical Studies, Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling
HeLa cells (human cervix carcinoma) & HeLa IF1 knockout (IF1 KO)
Drug Discovery, Cancer
Prevotella melaninogenica ATCC 25845
Hypoxia and Normoxia Assessment & Monitoring
Primary corticol neurons (mice)
Mitochondrial Programming & Dysfunction, Neurobiology, Cell & Tissue Modeling, Preclinical Studies
human neuroblastoma cells (SH-SY5Y)
Neurobiology, Cell & Tissue Modeling, Mitochondrial Programming & Dysfunction, Preclinical Studies
Patient-derived cortical organoids
Neurobiology, Preclinical Studies, Cell & Tissue Modeling, Mitochondrial Programming & Dysfunction
Murine KPC pancreatic cancer cells
Mitochondrial Programming & Dysfunction, Preclinical Studies, Cancer
Primary human adipocytes (subcutaneous & visceral)
Mitochondrial Programming & Dysfunction, Drug Discovery, Preclinical Studies, Obesity, Diabetes & Aging
SH-SY5Y neuroblastoma cells
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Preclinical Studies, Neurobiology
MEFs (mouse embryonic fibroblasts) & U2OS cells (human osteosarcoma line)
Mitochondrial Programming & Dysfunction, Drug Discovery, Cell & Tissue Modeling, Neurobiology
3T3-L1 preadipocytes & mouse embryonic fibroblasts
Mitochondrial Programming & Dysfunction, Obesity, Diabetes & Aging, Preclinical Studies
hPSC-derived human heart organoids (hHOs) & hPSC-derived human heart–macrophage assembloids (hHMAs)
Mitochondrial Programming & Dysfunction, Drug Discovery, Preclinical Studies, Cardiac, Immunometabolism
TPC1 (human papillary thyroid carcinoma) & MDA-T41 (human anaplastic/poorly differentiated thyroid carcinoma)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Cancer
Normal Human Dermal Fibroblasts (NHDFs)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Obesity, Diabetes & Aging
Primary Hepatocytes (Mouse)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Obesity, Diabetes & Aging
Human iPSC-derived brain microvascular endothelial cells (iBMECs)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Preclinical Studies, Neurobiology
WT-1 murine brown preadipocytes
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Obesity, Diabetes & Aging, Drug Discovery
Human pluripotent stem (hPS) cell-derived cardiomyocytes within multicellular cardiac organoids
Mitochondrial Programming & Dysfunction, Organ-on-a-chip & Tissue Engineering, Cell & Tissue Modeling, Drug Discovery, Preclinical Studies, Cardiac
Human head and neck squamous cell carcinoma cells (UM-SCC-1A)
Mitochondrial Programming & Dysfunction, Drug Discovery, Preclinical Studies, Cancer
C. elegans
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Preclinical Studies, Obesity, Diabetes & Aging
U-87MG (human glioblastoma line)
Preclinical Studies, Cell & Tissue Modeling, Cancer, Neurobiology, Mitochondrial Programming & Dysfunction
hiPSC-derived NPCs (human neuronal progenitor cells)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Preclinical Studies, Neurobiology, Stem Cells / iPSCs
HepG2
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Obesity, Diabetes & Aging
murine KPC pancreatic ductal adenocarcinoma (PDAC) cells - 7940B
Preclinical Studies, Cancer, Drug Discovery, Mitochondrial Programming & Dysfunction
IMR-90 Human Lung Fibroblasts
Obesity, Diabetes & Aging, Cancer, Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Drug Discovery
patient-derived brain tumor stem cells (BTSCs)
Cancer, Stem Cells / iPSCs, Drug Discovery, Cell & Tissue Modeling, Mitochondrial Programming & Dysfunction
human ovarian stromal cells
Mitochondrial Programming & Dysfunction, Drug Discovery, Obesity, Diabetes & Aging, Reproductive Biology
primary cortical neurons (mouse)
Mitochondrial Programming & Dysfunction, Drug Discovery, Preclinical Studies, Obesity, Diabetes & Aging, Neurobiology
Klinefelter Syndrome patient-derived iPSCs (KS1, KS2) and HS980 iPSCs
Reproductive Biology, Cell & Tissue Modeling, Preclinical Studies, Mitochondrial Programming & Dysfunction
C. elegans
Cell & Tissue Modeling, Cancer, Mitochondrial Programming & Dysfunction, Obesity, Diabetes & Aging
Patient-Derived BTSCs Brain Tumour Stem Cells (BTSC)
Cancer, Stem Cells / iPSCs, Drug Discovery, Preclinical Studies, Mitochondrial Programming & Dysfunction
SH-SY5Y neuroblastoma cells and CTR1 knockout (KO) clones
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Neurobiology
CD8+ T cells (mouse, activated effector-like phenotype)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Drug Discovery, Immunometabolism, Preclinical Studies
C2C12 myoblasts (mouse skeletal muscle cells)
Muscle Biology & Regeneration, Mitochondrial Programming & Dysfunction, Preclinical Studies, Cell & Tissue Modeling
mouse hippocampal neuronal cells (HT22)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Neurobiology, Preclinical Studies
human AML cell line (MV-4-11 cells)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Drug Discovery, Cancer
human lung carcinogenic cell line (A549), human hepatic epithelial cell line (HepG2) and human monocytic cell line (U937)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Immunometabolism, Preclinical Studies, Drug Discovery
VM-M3 tumor cell line
Cancer, Hypoxia and Normoxia Assessment & Monitoring, Cell & Tissue Modeling
umbilical cord mesenchymal stem cells (UC-MSCs) and primary cortical neurons
Hypoxia and Normoxia Assessment & Monitoring, Mitochondrial Programming & Dysfunction, Neurobiology, Preclinical Studies, Stem Cells / iPSCs
human dermal fibroblasts (HDFs)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Cancer, Drug Discovery
human epithelial ovarian cancer (EOC) cell lines (OV1369-R2 and OV1946) and human retinal pigment epithelial cell line (ARPE-19)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Drug Discovery, Cancer
human squamous cell carcinoma (A431) cells and human non-malignant keratinocytes (HaCaT cells)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Cancer
human hepatoma cell line (HepG2)
Mitochondrial Programming & Dysfunction, Cancer
C. elegans and rat PC12 cells
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Neurobiology
C2C12 myoblasts, primary mouse myoblasts, Muscle stem cells (MuSCs)
Mitochondrial Programming & Dysfunction, Muscle Biology & Regeneration, Cell & Tissue Modeling, Stem Cells / iPSCs
Human prostate epithelial cells (RWPE-1)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Cancer
Human cardiomyocyte cell line (AC16) and hiPSC-CMs
Mitochondrial Programming & Dysfunction, Preclinical Studies, Cardiac, Cell & Tissue Modeling
Human immortalized keratinocyte cell line (HaCaT)
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling
Human embryonic stem cell line (HES3) and iPSC's PB005.1 and PB006.6
Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Drug Discovery, Cardiac, Stem Cells / iPSCs
pancreatic murine Islets of Langerhans
Cell & Tissue Modeling, Obesity, Diabetes & Aging, Preclinical Studies, Hypoxia and Normoxia Assessment & Monitoring
iPSC-RPE cells
Retinal Biology & Eye Disease, Neurobiology, Cell & Tissue Modeling, Mitochondrial Programming & Dysfunction, Hypoxia and Normoxia Assessment & Monitoring
Human lung cancer cells NCI-H441 and NCI-H2228
Cancer, Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling
Human induced pluripotent stem cells (hIPSCs) and pLKO HeLa cells
Mitochondrial Programming & Dysfunction, Obesity, Diabetes & Aging, Neurobiology, Cell & Tissue Modeling
HepG2 and primary human dermal fibroblasts (NHDF)
Mitochondrial Programming & Dysfunction, Cancer, Cell & Tissue Modeling
Immortalized human bronchial epithelial cells (HBEC3-KT)
Mitochondrial Programming & Dysfunction, Obesity, Diabetes & Aging
Klinefelter Syndrome cell lines KS1,2 and HS980
Mitochondrial Programming & Dysfunction, Stem Cells / iPSCs
Human breast cancer cell lines MCF7 and SKBR3
Cancer, Mitochondrial Programming & Dysfunction
2D and 3D Breast Cancer Cell Lines (HCC1428, MCF7, CAMA1)
Cancer, Cell & Tissue Modeling, Preclinical Studies, Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling, Neurobiology
Slc7a11sut/sut Primary Muscle Cells
Muscle Biology & Regeneration, Cell & Tissue Modeling
3T3-L1 adipocytes
Cell & Tissue Modeling, Hypoxia and Normoxia Assessment & Monitoring, Obesity, Diabetes & Aging
7940B Cells
Drug Discovery, Cancer, Cell & Tissue Modeling
Multiple Adherent Cancer Cell Lines (normal and tumor)
Cancer, Cell & Tissue Modeling
Human 22qDS iPSC-derived BBB cells
Neurobiology, Stem Cells / iPSCs, Cell & Tissue Modeling
The Epithelial Ovarian Cancer Cell Line TOV112D and ARPE-19. Patient Derived
Cancer, Drug Discovery
H1&H9 Human Embryonic Stem Cell lines/ Human Islets/Pancreatic islets
Stem Cells / iPSCs, Obesity, Diabetes & Aging, Cell therapy CQA/QC Assessment & Monitoring, Preclinical Studies, Mitochondrial Programming & Dysfunction
SH-SY5Y Neuroblastoma cells
Neurobiology
Melanoma Cells
Cancer, Mitochondrial Programming & Dysfunction
Human induced Pluripotent Stem Cell?derived RPE cultures (iPSC-RPE)
Retinal Biology & Eye Disease, Stem Cells / iPSCs, Cell & Tissue Modeling, Hypoxia and Normoxia Assessment & Monitoring, Preclinical Studies, PD/MFG, Mitochondrial Programming & Dysfunction
Aenorhabditis Elegans (C. Elegans)
Obesity, Diabetes & Aging, Hypoxia and Normoxia Assessment & Monitoring, Cell & Tissue Modeling
Primary Neurons
Mitochondrial Programming & Dysfunction, Neurobiology, Obesity, Diabetes & Aging
LUHMES Cell Lines Lund Human Mesencephalic
Neurobiology, Mitochondrial Programming & Dysfunction
HepG2 (ATCC HB-8065™) and LX2 (SCC064) Human Epithelial Cell Lines
Cancer
Acute Myeloid Leukemia Cell Line
Cancer, Drug Discovery, Preclinical Studies
Human induced Pluripotent Stem Cell Cardiomyocytes (hiPS-CMs)
Cardiac, Stem Cells / iPSCs, Cell therapy CQA/QC Assessment & Monitoring, PD/MFG, Mitochondrial Programming & Dysfunction, Cell & Tissue Modeling
Human Coronary Artery cells HCAEC and HCASMC
Cardiac, Hypoxia and Normoxia Assessment & Monitoring, Cell & Tissue Modeling
Primary Human Retinal Pigment Epithelial Cells (H-RPE)
Retinal Biology & Eye Disease
CAOV3, HEYA8 and OVCAR8 w/ heterozygous UQCR11 deletion
Cancer, Mitochondrial Programming & Dysfunction, Drug Discovery
28 Human Non-Small Cell Lung Cancer (NSCLC) lines
Cancer, Hypoxia and Normoxia Assessment & Monitoring, Drug Discovery, Cell & Tissue Modeling
Cardiac, Stem Cells / iPSCs, Mitochondrial Programming & Dysfunction
Stem Cells / iPSCs, Muscle Biology & Regeneration, Cell therapy CQA/QC Assessment & Monitoring, Drug Discovery, Mitochondrial Programming & Dysfunction
How-To Videos
Device Support
Hub Setup
Device Support
Resipher Setup
Lucid Lab
Experiments Overview
Lucid Lab
Creating Experiments
Lucid Lab
Viewing Plots
Lucid Lab
Editing Plots
Frequently Asked Questions
Device Technology
How does
Resipher
measure oxygen concentration?
The sensing probes are coated with an oxygen-sensitive material. When optically excited, this material fluoresces and emits light depending on the amount of oxygen present. The
Resipher
processes the emitted light signal into an oxygen concentration measurement.
What wavelength of light do you use?
The LEDs of the
Resipher
device emit blue light with a wavelength range of 435-485 nm.
Is the sensing method invasive?
No,
Resipher
accommodates normal cell growth workflow, i.e. same seeding density, media, treatment, etc. No special assay is required for an experiment using
Resipher
. After the experiment, you can collect and utilize the cells in the well plate.
Can I monitor my
Resipher
when I am not in the lab?
Yes, the
Resipher
streams your data in real-time for you to access from anywhere!
How are
Resipher
and the Hub connected?
Resipher
is connected to the Hub via a USB-C cable. This wired connection design ensures there is no power interruption to the
Resipher
during the experiment. The USB-C cable can be inserted through a port at the back of an incubator (if available).
How long does it take for
Resipher
to start showing oxygen consumption rate measurements?
Oxygen concentration (O2C) readings are available immediately after the experiment begins; oxygen consumption rate (OCR) is shown 30-60 minutes after the beginning of each experiment. This time period allows oxygen gradients to form in each well.
Is there a minimum amount of time needed for
Resipher
to stabilize prior to gathering data?
Since oxygen measurement is temperature-dependent, expect reliable data to be available 30-60 minutes after the initial setup. The goal is to allow time for the incubator to equilibrate back to its normal environment, i.e. 37 C, 5% CO2, etc. This initial wait period also allows oxygen gradients to form in each well.
Technology
Can the
Resipher
system be used in a hypoxic workstation?
Resipher
works best at an oxygen level of 0-20%. If your application requires a higher oxygen level, we will be happy to discuss further.
How long is a typical
Resipher
experiment?
Our customers usually run experiments with a duration of 3-7 days. The optimal duration ranges from 1 day to 14 days. There are also experiments as short as 12 hours and as long as 21 days.
How long does it typically take to set up a new experiment in the Lucid Lab software?
It takes less than 10 minutes to set up an experiment in our software.
Is there a minimum amount of cells that can be seeded per well?
You can seed the cells like you normally do.
Resipher
allows you to follow your typical cell growth workflow.
Does the
Resipher
work with non-adherent cells?
Non-adherent cells that settle to the bottom of the wells also work well with
Resipher
.
Does the
Resipher
require a specific type of media or fluid in the wells?
No,
Resipher
accommodates normal cell growth workflow, i.e. same seeding density, media, treatment, etc. No special assay is required for an experiment using
Resipher
.
How does adding a treatment work?
Simply separate the
Resipher
device from the sensing lid; transfer the well plate and sensing lid into a biosafety cabinet and treat the cells as normal in a sterile environment. Once treated, place the sensing lid back onto the well plate, transfer it back into the incubator and reconnect the lid with the
Resipher
device.
Can you use
Resipher
on any type of 96 well plate?
The
Resipher
was originally designed to accommodate Falcon and Nunc 96 well plates with the following catalog numbers. In addition, we have validated a lot of other 96 well plate types, please reach out to our team to share your desired plate model and we will help you identify the correct probe lengths to accommodate your cell model system.

Nunc (167008) & Falcon (353072)
Data Analysis
Is it possible to export the data to use with other software or for graphing purposes?
Yes - our current software allows users to download data in JSON or CSV formats.
General
How can I purchase new sensing lids?
You can purchase lids here.