Real-time hyperspectral fluorescence imaging of pancreatic β-cell dynamics with the image mapping spectrometer (IMS)

Elliott, Amicia D.; Gao, Liang; Ustione, Alessandro; Bedard, Noah; Kester, Robert T.; Piston, David W.; Tkaczyk, Tomasz S.

doi:10.1242/jcs.108258

Cited by 50 publications

(41 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The earlier mappers used in IMS were fabricated using a raster-fly cutting technique on a four-axis Nanotech Ultra Precision milling machine [24]. Here we used a ruling technique which has been shown recently to exhibit several advantages over raster-fly cutting [30]. The raster-fly cutting process is significantly slower than ruling, and it creates a large inconsistency in facet widths.…”

Section: Mapper Fabrication Methodsmentioning

confidence: 99%

Snapshot 3D optical coherence tomography system using image mapping spectrometry

et al. 2013

View full text Add to dashboard Cite

Abstract:A snapshot 3-Dimensional Optical Coherence Tomography system was developed using Image Mapping Spectrometry. This system can give depth information (Z) at different spatial positions (XY) within one camera integration time to potentially reduce motion artifact and enhance throughput. The current (x,y,λ ) datacube of (85×356×117) provides a 3D visualization of sample with 400 μm depth and 13.4 μm in transverse resolution. Axial resolution of 16.0 μm can also be achieved in this proof-of-concept system. We present an analysis of the theoretical constraints which will guide development of future systems with increased imaging depth and improved axial and lateral resolutions.

show abstract

Section: Mapper Fabrication Methodsmentioning

confidence: 99%

Snapshot 3D optical coherence tomography system using image mapping spectrometry

et al. 2013

View full text Add to dashboard Cite

show abstract

“…With a large-format CCD, a current state-of-the-art IMS can measure a 350 × 350 × 48 ( x,y ,λ) datacube [45] within a single camera snapshot. The IMS has been demonstrated in combination with a variety of imaging modalities, such as microscopy [16, 24, 46–48], endoscopy [45], fundus photography [49], and macroscopy [50, 51], and has been employed for imaging both in the visible [45, 46] and infra-red spectral ranges [51]. …”

Section: Snapshot Multidimensional Imaging Implementations and Appmentioning

confidence: 99%

A review of snapshot multidimensional optical imaging: Measuring photon tags in parallel

2016

Self Cite

View full text Add to dashboard Cite

Multidimensional optical imaging has seen remarkable growth in the past decade. Rather than measuring only the two-dimensional spatial distribution of light, as in conventional photography, multidimensional optical imaging captures light in up to nine dimensions, providing unprecedented information about incident photons’ spatial coordinates, emittance angles, wavelength, time, and polarization. Multidimensional optical imaging can be accomplished either by scanning or parallel acquisition. Compared with scanning-based imagers, parallel acquisition—also dubbed snapshot imaging—has a prominent advantage in maximizing optical throughput, particularly when measuring a datacube of high dimensions. Here, we first categorize snapshot multidimensional imagers based on their acquisition and image reconstruction strategies, then highlight the snapshot advantage in the context of optical throughput, and finally we discuss their state-of-the-art implementations and applications.

show abstract

“…These spectral imagers can be designed to be advantageous over existing scanning spectrometers due to longer pixel dwell times, permitting their use in dim applications, and higher speeds, which eliminate motion artifacts for dynamic scenes [18]. The advantages of these spectral imagers have seen their increased use in microscopy applications over the last few years [19,20] and in vivo tissue imaging [21][22][23][24][25]. Each pixel's exposure time to the collected light is the same as the time used to acquire the datacube, which increases irradiance per pixel in comparison to scanning techniques with the same datacube acquisition time or frame rate.…”

Section: Introductionmentioning

confidence: 99%

Lenslet array tunable snapshot imaging spectrometer (LATIS) for hyperspectral fluorescence microscopy

Dwight¹,

Tkaczyk²

2017

Biomed. Opt. Express

Self Cite

View full text Add to dashboard Cite

Snapshot hyperspectral imaging augments pixel dwell time and acquisition speeds over existing scanning systems, making it a powerful tool for fluorescence microscopy. While most snapshot systems contain fixed datacube parameters (x,y,λ), our novel snapshot system, called the lenslet array tunable snapshot imaging spectrometer (LATIS), demonstrates tuning its average spectral resolution from 22.66 nm (80x80x22) to 13.94 nm (88x88x46) over 485 to 660 nm. We also describe a fixed LATIS with a datacube of 200x200x27 for larger fieldof-view (FOV) imaging. We report <1 sec exposure times and high resolution fluorescence imaging with minimal artifacts. Tracking Using a High-Speed Hyperspectral Line-Scanning Microscope," PLoS One 8(5), e64320 (2013). 14. P. M. Kasili and T. Vo-Dinh, "Hyperspectral imaging system using acousto-optic tunable filter for flow cytometry applications," Cytometry A 69(8), 835-841 (2006).

show abstract

Real-time hyperspectral fluorescence imaging of pancreatic β-cell dynamics with the image mapping spectrometer (IMS)

Cited by 50 publications

References 26 publications

Snapshot 3D optical coherence tomography system using image mapping spectrometry

Snapshot 3D optical coherence tomography system using image mapping spectrometry

A review of snapshot multidimensional optical imaging: Measuring photon tags in parallel

Lenslet array tunable snapshot imaging spectrometer (LATIS) for hyperspectral fluorescence microscopy

Contact Info

Product

Resources

About