Application of magnetic particle tracking velocimetry to quadrupole magnetic sorting of porcine pancreatic islets

Sajja, Venkata Sunil Kumar; Hanley, Thomas R.; Gapsis, Helen; Guernsey, Byron; Kennedy, David J.; Taylor, Michael J.; Papas, Klearchos K.; Todd, Paul

doi:10.1002/bit.23157

Cited by 9 publications

(7 citation statements)

References 20 publications

(19 reference statements)

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“…In conclusion, a method has been researched for the simultaneous determination of particle count, particle diameter, and magnetophoretic mobility using dark-field videomicroscope velocimetry with image storage, processing, and analysis software using the commercial Hyperflux particletracking velocimeter (30). This study has demonstrated an available capability to analyze magnetic particles and cells that has been heretofore limited to only a handful of laboratories (15,18,24,(31)(32)(33)(34) with one-of-a-kind instruments. With correct operator-based settings, measurements of magnetophoretic mobility and particle count are robust, and diameter can be determined on the basis of calibration.…”

Section: Resultsmentioning

confidence: 99%

“…Noncommercial instrumentation has been applied by specific investigators to the measurement of magnetophoretic mobility of individual particles and magnetically labeled cells by particle tracking velocimetry (17)(18)(19)(20). In certain cases, these measurements are directly applied to the establishment of parameters for the enrichment of magnetically labeled cells in flowing devices (21)(22)(23)(24) or to the quantification of cell surface markers (25,26).…”

Section: Introductionmentioning

confidence: 99%

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Magnetic particle characterization—magnetophoretic mobility and particle size

et al. 2016

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Quantitative characterization of magnetic particles is useful for analysis and separation of labeled cells and magnetic particles. A particle velocimeter is used to directly measure the magnetophoretic mobility, size, and other parameters of magnetic particle suspensions. The instrument provides quantitative video analysis of particles and their motion. The trajectories of magnetic particles in an isodynamic magnetic field are recorded using a high-definition camera/microscope system for image collection. Image analysis software then converts the image data to the parameters of interest. The distribution of magnetophoretic mobility is determined by combining fast image analysis with velocimetry measurements. Particle size distributions have been characterized to provide a better understanding of sample quality. The results have been used in the development and operation of analyzer protocols for counting particle concentrations accurately and measuring magnetic susceptibility and size for simultaneous display for routine application to particle suspensions and magnetically labeled biological cells. V C 2016 International Society for Advancement of Cytometry

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Magnetic particle characterization—magnetophoretic mobility and particle size

et al. 2016

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“…The QMS inlet flow rate (out of the buffer bag) was matched with the flow rate of tissue leaving the digest chamber to maintain a continuous purification process. The mechanism for the QMS process using this system is described in detail by Kennedy et al and others [15, 40, 54]. Briefly, as the tissue flow stream entered the QMS separator column, it is met with a parallel fresh stream of HBSS solution.…”

Section: Methodsmentioning

confidence: 99%

Continuous Quadrupole Magnetic Separation of Islets during Digestion Improves Purified Porcine Islet Viability

Weegman

Sajja

Suszynski

et al. 2016

Journal of Diabetes Research

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Islet transplantation (ITx) is an emerging and promising therapy for patients with uncontrolled type 1 diabetes. The islet isolation and purification processes require exposure to extended cold ischemia, warm-enzymatic digestion, mechanical agitation, and use of damaging chemicals for density gradient separation (DG), all of which reduce viable islet yield. In this paper, we describe initial proof-of-concept studies exploring quadrupole magnetic separation (QMS) of islets as an alternative to DG to reduce exposure to these harsh conditions. Three porcine pancreata were split into two parts, the splenic lobe (SPL) and the combined connecting/duodenal lobes (CDL), for paired digestions and purifications. Islets in the SPL were preferentially labeled using magnetic microparticles (MMPs) that lodge within the islet microvasculature when infused into the pancreas and were continuously separated from the exocrine tissue by QMS during the collection phase of the digestion process. Unlabeled islets from the CDL were purified by conventional DG. Islets purified by QMS exhibited significantly improved viability (measured by oxygen consumption rate per DNA, p < 0.03) and better morphology relative to control islets. Islet purification by QMS can reduce the detrimental effects of prolonged exposure to toxic enzymes and density gradient solutions and substantially improve islet viability after isolation.

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“…A specifically designed cell sorter capable of purifying cells labeled with magnetic nanoparticles is already available . This method has been described in the literature as quadruple magnetic sorting and has been successfully applied to several separation and purification applications for particles up to a size of 350 μm . To enable quadruple magnetic sorting for magnetic separation of encapsulated islets, the device must be adapted to work with a maximum particle size of 600 μm.…”

Section: Discussionmentioning

confidence: 99%

Magnetic separation of encapsulated islet cells labeled with superparamagnetic iron oxide nano particles

Mettler

Trenkler

Feilen

et al. 2013

Xenotransplantation

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Islet cell transplantation is a promising option for the restoration of normal glucose homeostasis in patients with type 1 diabetes. Because graft volume is a crucial issue in islet transplantations for patients with diabetes, we evaluated a new method for increasing functional tissue yield in xenogeneic grafts of encapsulated islets. Islets were labeled with three different superparamagnetic iron oxide nano particles (SPIONs; dextran-coated SPION, siloxane-coated SPION, and heparin-coated SPION). Magnetic separation was performed to separate encapsulated islets from the empty capsules, and cell viability and function were tested. Islets labeled with 1000 μg Fe/ml dextran-coated SPIONs experienced a 69.9% reduction in graft volume, with a 33.2% loss of islet-containing capsules. Islets labeled with 100 μg Fe/ml heparin-coated SPIONs showed a 46.4% reduction in graft volume, with a 4.5% loss of capsules containing islets. No purification could be achieved using siloxane-coated SPIONs due to its toxicity to the primary islets. SPION labeling of islets is useful for transplant purification during islet separation as well as in vivo imaging after transplantation. Furthermore, purification of encapsulated islets can also reduce the volume of the encapsulated islets without impairing their function by removing empty capsules.

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Application of magnetic particle tracking velocimetry to quadrupole magnetic sorting of porcine pancreatic islets

Cited by 9 publications

References 20 publications

Magnetic particle characterization—magnetophoretic mobility and particle size

Magnetic particle characterization—magnetophoretic mobility and particle size

Continuous Quadrupole Magnetic Separation of Islets during Digestion Improves Purified Porcine Islet Viability

Magnetic separation of encapsulated islet cells labeled with superparamagnetic iron oxide nano particles

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