Optimization of cryoprotectant loading into murine and human oocytes

Karlsson, Jens O.M.; Szurek, Edyta; Higgins, Adam Z.; Lee, Sang Ryong; Eroğlu, Ali

doi:10.1016/j.cryobiol.2013.11.002

Cited by 48 publications

(25 citation statements)

References 75 publications

(122 reference statements)

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“…Therefore, a surfactant or chemical additive that is capable of reducing the surface tension without cytotoxicity is required for stable evolution of spherical droplets as well as for long‐term cell viability. We selected dimethyl sulfoxide (DMSO) as a biocompatible surface tension modifier as this reagent is commonly used as a cryoprotectant additive (CPA) and as an agent to induce differentiation of cultured cells . Various concentrations of DMSO (0, 5, and 10 vol%) were added to the bioink that was then jetted using the same jetting conditions to determine the optimal DMSO concentration.…”

Section: Resultsmentioning

confidence: 99%

Insertion of Vertically Aligned Nanowires into Living Cells by Inkjet Printing of Cells

Lee

Won

et al. 2016

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Effective insertion of vertically aligned nanowires (NWs) into cells is critical for bioelectrical and biochemical devices, biological delivery systems, and photosynthetic bioenergy harvesting. However, accurate insertion of NWs into living cells using scalable processes has not yet been achieved. Here, NWs are inserted into living Chlamydomonas reinhardtii cells (Chlamy cells) via inkjet printing of the Chlamy cells, representing a low-cost and large-scale method for inserting NWs into living cells. Jetting conditions and printable bioink composed of living Chlamy cells are optimized to achieve stable jetting and precise ink deposition of bioink for indentation of NWs into Chlamy cells. Fluorescence confocal microscopy is used to verify the viability of Chlamy cells after inkjet printing. Simple mechanical considerations of the cell membrane and droplet kinetics are developed to control the jetting force to allow penetration of the NWs into cells. The results suggest that inkjet printing is an effective, controllable tool for stable insertion of NWs into cells with economic and scale-related advantages.

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Section: Resultsmentioning

confidence: 99%

Insertion of Vertically Aligned Nanowires into Living Cells by Inkjet Printing of Cells

Lee

Won

et al. 2016

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“…While not complete in their description of the processes, the predictions of these models have been extremely useful in guiding experimental design, demonstrating feasibility of approaches, etc. [11,12,20,36,44,[48][49][50]69,78,84,122]. Many advances in computational complexity, transport and solution theories [10,28,32,57,97], as well as experimental parameter identification techniques [24][25][26]58,116,117] have been made along the way, facilitating more accurate models and better predictions of intracellular ice formation.…”

Section: Discussionmentioning

confidence: 98%

Foundations of modeling in cryobiology—I: Concentration, Gibbs energy, and chemical potential relationships

Anderson¹,

Benson²,

Kearsley³

2014

Cryobiology

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“…Each step can induce damage to cells. Osmotic shock occurring during loading and unloading of CPA is one of the major causes of cell damage during the cryopreservation process [63, 64]. A microfluidic approach to minimize osmotic shock to cells during cryopreservation has been introduced by Song and colleagues [11].…”

Section: The Use Of Microfluidic Technologies For Cell Preservation Pmentioning

confidence: 99%

Synergistic Development of Biochips and Cell Preservation Methodologies: a Tale of Converging Technologies

Wang

Elliott

2017

Curr Stem Cell Rep

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Purpose of the review Over the past several decades, cryopreservation has been widely used to preserve cells during long term storage, but advances in stem cell therapies, regenerative medicine, and miniaturized cell-based diagnostics and sensors are providing new targets of opportunity for advancing preservation methodologies. The advent of microfluidics-based devices is an interesting case in which the technology has been used to improve preservation processing, but as the devices have evolved to also include cells, tissues, and simulated organs as part of the architecture, the biochip itself is a desirable target for preservation. In this review, we will focus on the synergistic co-development of preservation methods and biochip technologies, while identifying where the challenges and opportunities lie in developing methods to place on-chip biologics on the shelf, ready for use. Recent findings Emerging studies are demonstrating that the cost of some biochips have been reduced to the extent that they will have high utility in point-of-care settings, especially in low resource environments where diagnostic capabilities are limited. Ice-free low temperature vitrification and anhydrous vitrification technologies will likely emerge as the preferred strategy for long-term preservation of bio-chips. Summary The development of preservation methodologies for partially or fully assembled biochips would enable the widespread distribution of these technologies and enhance their application.

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Optimization of cryoprotectant loading into murine and human oocytes

Cited by 48 publications

References 75 publications

Insertion of Vertically Aligned Nanowires into Living Cells by Inkjet Printing of Cells

Insertion of Vertically Aligned Nanowires into Living Cells by Inkjet Printing of Cells

Foundations of modeling in cryobiology—I: Concentration, Gibbs energy, and chemical potential relationships

Synergistic Development of Biochips and Cell Preservation Methodologies: a Tale of Converging Technologies

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