Tomocube HT-X1

Holotomography is a label free technique that utilizes low-intensity light to acquire the refractive index of cells from multiple angles. The high-resolution images obtained through this technology enable real-time observation of not only the morphology of living cells but also the shapes of subcellular organelles, such as the nucleus, nucleolus, mitochondria, and lipid droplets.

Tomocube’s second-generation Holotomography system, the Tomocube HT-X1, employs low-coherence light sources, ensuring lower toxicity and noise-free high-resolution image acquisition compared to laser-based methods. The integrated stage-top incubator provides a stable cultivation environment, enabling prolonged monitoring of sensitive cells like stem cells or organoids.

Description

Key Features:

  • Label-free 3D live cell imaging of monolayered cells and 3D organoids
  • Correlative fluorescence imaging to jointly obtain biomolecular specificity information
  • Long-term timelapse with built-in incubator that provides a stable cell culture environment
  • Multi-well plate compatibility for high-throughput experiments
  • Quantitative measurements analysis of cells and subcellular components

User Benefits:

  • High Resolution 3D Imaging
    HT-X1 uses an LED illumination module integrated with a Digital Micro-mirror Device (DMD). When HT-X1 captures a 3D image, the illumination module is rapidly cycling through a set of optimized illumination patterns programmed in the DMD to encode specific spatial features of the specimen. By synthesizing these images acquired from multiple angles, HT can overcome the optical resolution limit, achieving higher synthetic NA compared to the physical NA value of objective lens. Therefore, HT-X1 imaging provides high-content, high-resolution 3D imaging at exceptional stability.
  • Label-free Cellular Dynamics Observation
    The Holotomography approach in live cell imaging does not require fixation or labeling, which reduces unwanted artificial intervention and the need for long exposure to light. By minimizing the risks of phototoxicity and photobleaching, the specimen remains at its nature state for observation. With a rapid capture speed of 1 second per frame, HT enables real-time monitoring of dynamic cellular processes with exceptional temporal resolution. Additionally, its integrated stage-top feature facilitates long-term observations, empowering researchers to explore cellular phenomena over extended periods with stability and precision.
  • Multi-well Plate Compatibility
    Especially designed to maximize user flexibility, the HT-X1 employs a unique adaptive illumination module that is tailored for multi-well plates. The combination of high NA, a long working distance condenser, DMD, and a motorized illumination unit delivers an efficient illumination pattern for a diverse range of vessel types, from 35-mm dishes to 96-well plates. With the HT-X1, researchers will have more freedom to design their experiments on different sample types using any imaging vessel of their choice.
  • Intuitive Software
    TomoStudio X works in concert with the HT-X1 platform to visualize and analyze RI tomograms. This intuitive, easy-to-use software empowers users with complete system control, allowing them to handle even the most complex experiments through simple mouse clicks. Researchers can easily set up complex time-lapse sequences, perform large-area tile imaging and stitching tasks, and image multiple points with ease using this software

Technical Specifications:

Instrument

  • Size

565(W) x 732 (D) x 921 (H) mm

  • Weight

90 kg

  • Power

100-240V,50/60 Hz, 5-3A, 400 W

  • Objective lens

40x NA 0.95 air, working distance 180 µm

  • Condenser lens

NA 0.72

  • Image sensor

2.8 Mega pixels CMOS

  • Field-of-view

Max.218 µm x 165 µm

  • Compatible labware

Dish/Plate/Slide with #1.5 bottom thickness

 

Holotomography optics

  • Light source

450 nm LED

  • Maximum z-axis imaging range

146 µm

  • Lateral resolution

156 nm

  • Axial resolution

1069 nm

 

Fluorescence optics

  • Light source

LEDs

  • Excitation filters

378/52, 474/27, 554,23, 635/18 nm

  • Emission filters

432/36, 515/30, 595/31, 698/70 nm

 

Environmental controller

  • Model STXG-WSKMXA22B (Tokai HIT)
  • Dimensions 151 (W) x 263 (D) x 196 (H) mm
  • Weight 3.8 kg
  • Temperature setting range Sample temperature: 37 °C

Top heater: 10 °C – 65 °C

Bath heater: 10 °C – 50 °C

Stage heater: 10 °C – 50 °C

Lens heater: 10 °C – 45 °C

  • Rise time

10 min to reach 50 °C

  • Temperature accuracy Within 0.3 °C
  • Humidity control

Heated humidification by the heating bath unit

Recommended water volume: 32 mL

  • CO₂ concentration range 5% – 20%

Control method: PID control

Accuracy: ±0.1%

  • Gas type

100% CO₂

  • Gas pressure

Input: 0.1 MPa – 0.15 MPa

Output: 160 mL per min

  • Power source

100 – 240 V AC ±10%, 50/60 Hz

  • Maximum power consumption

110 W

  1. Live cell imaging

Live cell imaging is a crucial tool in cell biology, offering direct insights into how cells function in real time. HT enhances this capability significantly, allowing researchers to explore cellular complexities with exceptional clarity and precision.

As a label-free imaging technique, HT preserves the natural state and behavior of cells and their subcellular organelles. This non-invasive approach enables the study of various cellular processes over extended periods, including cell division, migration, cell interaction, signaling pathways, and cellular responses to drug-induced or environmentally induced changes.

The HT-X1 platform includes a stage-top incubator that ensures optimal culture conditions for long-term time-lapse imaging, maintaining cell health and viability throughout extended studies. This allows researchers to observe cellular processes over time without compromising the integrity of their observations. By reducing the need for time-consuming sample preparation and minimizing artifacts, HT streamlines the imaging process and enhances result accuracy.

  1. Lipid droplet biogenesis

Lipid droplets (LDs) are essential subcellular organelles involved in lipid storage, energy metabolism, and various cellular processes. Despite their significance, the mechanisms underlying LD biogenesis and functions remain incompletely understood, necessitating advanced research tools for further investigation.

In LD research, HT offers a significant advantage by measuring the intrinsic RI value, which is higher for LDs compared to other cellular organelles, allowing for precise compartmentalization without the need for commonly used dyes like Nile Red or BODIPY. HT’s high-contrast, label-free imaging capabilities overcome the challenges of conventional methods, including low molecular specificity, photobleaching, and phototoxicity during prolonged imaging of live cells.

In a study published in ACS Nano, researchers analyzed the suppression of LD production over time in foam cells—key players in arteriosclerosis—when subjected to drug treatments (Park et al., 2020). The study involved examining various morphological and biophysical parameters, including the number, volume, and dry mass of LDs. Machine learning techniques were utilized to evaluate therapeutic effects at the single-cell level. With the ability to track individual LDs in three dimensions within living cells, HT shows potential for real-time therapeutic drug screening, including targeted nanodrugs, in lipid-containing cells.

Another study highlighted the potential of the HT-X1 platform by extensively observing a 42-day process wherein human knee chondrocytes underwent reverse differentiation to form dedifferentiated adipocytes (DFAT) and subsequently re-differentiated into mature adipocytes (Jeong et al., 2024). This application of HT allows for detailed and dynamic investigations into lipid droplet dynamics and related cellular processes.

  1. Cell-in-cell structures

Cell-in-cell (CIC) structures create a unique cellular arrangement where a whole cell is found in the cytoplasm of another. Unlike apoptotic cells that are engulfed through phagocytosis, the internalized cells in CIC structures remain viable for extended periods and often exhibit dynamic activities before determining their fate. Considerable evidence suggests that CIC structures play a significant role in both pathological and physiological conditions, with their most frequent occurrence being in cancer tissues.

HT is particularly well-suited for research elucidating the mechanisms and consequences of CIC formation. The capacity of HT to monitor the long-term cellular dynamics in real time, without the need for multiple cell-specific markers, makes it an invaluable tool for investigate diverse cell interactions in their native state.

In a recent study published in iScience, the CIC phenomenon, where NK cells entered cancer cells, was identified using HT imaging (Choe et al., 2022). Utilizing label-free observation of this CIC structure, the study focused on heterotypic cell segmentation, facilitating a further analysis of its contribution to drug resistance. Continuous monitoring of the time-lapse process of cancer cell death added temporal insights. Incorporating correlative fluorescence imaging aided in distinguishing different cell types, enhancing the understanding of dynamics within cell-in-cell structures.

Results show that CIC-forming cancer cells showed lower response to NK cytotoxicity, higher proliferative ability, and higher resistance to anticancer drugs than non-CIC cancer cells. It suggests the use of heterotypic CICs as a functional biomarker to predict NK susceptibility and drug resistance in solid cancer cell lines.

  1. Cell migration

Cell migration is vital for biological processes such as embryonic development, wound healing, and immune responses, and it also play a significant role in pathological conditions like cardiovascular diseases and cancer metastasis. Understanding cell migration in both 2D surfaces and complex 3D matrices can offer insights into these conditions and improve treatments.

Live cell timelapse imaging is commonly used in migration assays to explore dynamic processes like wound healing and cancer cell metastasis. HT is a key tool in this research, allowing real-time, non-invasive tracking of cell migration.

In wound healing, for example, fibroblasts and endothelial cells migrate to injury sites to promote tissue repair. The accompanying video showcases wound healing assay, a standard in vitro technique for probing collective cell migration. An artificial cell-free area was created in a confluent monolayer of NIH-3T3 embryonic fibroblast. Through tile and timelapse imaging at 10-min intervals over 36 hours, HT captured the entire closure process in high resolution for detailed analysis.

Another case study features migrasomes—extracellular vesicles formed in migrating cells and are gaining renewed attention in cellular biology. In a recent study, HT imaging was employed to observe that TNF alpha increased the formation of migrasomes (Gagat et al. 2021). HT played a crucial role in correlating the 3D morphology with localization in correlative fluorescence imaging, enabling stereoscopic observation of migrasomes.

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