The Historic Development and Incorporation of Four Assisted Reproductive Technologies Shaping Today′s IVF Industry

Schiewe, M.C.

doi:10.4172/2375-4508.1000173

Cited by 6 publications

(6 citation statements)

References 96 publications

(106 reference statements)

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“…While a device system may be perfected, or not, within a laboratory, when samples are transferred for warming to another laboratory, reduced outcomes may occur. This interlaboratory variation poses potential liability issues to both programs [45,46]. Even when both programs are competent in their procedures, the relationships between cooling and warming thermodynamics as discussed above can have applied consequences.…”

Section: Quality Control Considerations In Vitrification Systemsmentioning

confidence: 99%

“…Little to no progress has been made over the past 5 years to correct or understand why overall blastocyst development may be reduced between cryopreserved batches. The inefficiencies of oocyte cryopreservation go beyond the device system used or technical variation and undoubtedly rest on improving our understanding of the membrane integrity and cytoplasmic sensitivity of this large single cell [45,70,71]. There remains a need to understand more about cytosolic factors at the level of gene regulation and energetics of vitrified-warmed oocytes that could be responsible for decreasing their developmental potential [72][73][74].…”

Section: Experimental Aspects Of Today's Clinical Vitrificationmentioning

confidence: 99%

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Vitrification: Fundamental Principles and Its Application for Cryopreservation of Human Reproductive Cells

Schiewe¹,

Mullen²

2018

Cryopreservation Biotechnology in Biomedical and Biological Sciences

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The fundamental understanding of cryobiology through experimentation in the 1960s, 1970s, and 1980s has led to the development of today's vitrification technology. Although human embryo and oocyte vitrification was slow to evolve, it has become an invaluable technology in the field of reproductive medicine. The aim of this chapter is to discuss some of the underlying basic principles behind forming a metastable glass phase during rapid cooling in liquid nitrogen (LN 2) and the prevention of recrystallization events upon warming. We then highlight how this understanding has led to its highly effective and reliable usage in clinical IVF. Furthermore, we describe how quality control factors (e.g., ease of use, repeatability, reliability, labeling security, and cryostorage safety) can vary between vitrification device systems, potentially influencing clinical outcomes and creating possible liability issues. An open-minded approach to continued experimentation is a necessity, especially pertaining to oocyte freeze preservation, if we are to optimize the vitrification of reproductive cells and tissue in the future.

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Section: Quality Control Considerations In Vitrification Systemsmentioning

confidence: 99%

Section: Experimental Aspects Of Today's Clinical Vitrificationmentioning

confidence: 99%

Vitrification: Fundamental Principles and Its Application for Cryopreservation of Human Reproductive Cells

Schiewe¹,

Mullen²

2018

Cryopreservation Biotechnology in Biomedical and Biological Sciences

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“…In addition, it has been developed without commercial influence and marketing pressure, thus providing the added benefit of substantial cost-savings. In today's IVF industry, which is increasingly reliant of biopsying and vitrifying every fair to excellent quality blastocyst to optimize pregnancy success [58], costs are an increasingly important factor to consider. This is especially true when one realizes that 50-75% of the genetically tested blastocysts will be aneuploidy and destine to be discarded after shortterm storage.…”

Section: The Microsecure-vtf (μS-vtf): a Quality Control Solutionmentioning

confidence: 99%

Quality Control Factors Influencing the Successful and Reliable Implementation of Oocyte and Embryo Vitrification

Schiewe¹

2016

Cryopreservation in Eukaryotes

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Clinical vitriication evolved slowly, with interests and acceptance being commercially driven by the development of unique devices, safer solutions, and the misconception that ultra-rapid cooling in an open system was a necessity to optimizing vitriication success. Furthermore, the dogma surrounding the importance of cooling rates has led to unsafe practices subject to excessive technical variation and risky modiications to create closed-storage devices. The aim of this chapter is to highlight important quality control factors e.g., ease of use, repeatability, reliability, labeling security, and cryostorage safety) into the selection process of which device/solution to use, independent of commercial manipulations. In addition, we provide clinical and experimental evidence in support of warming rates being the most important factor determining vitriication survival. Lastly, we exhibit indisputable support that aseptic, closed vitriication systems, speciically microSecure vitriication μS-VTF), can achieve success with atention to quality control details often lacking in open vitriication devices.Keywords: blastocyst, cryopreservation, device type, oocyte, quality control, vitriication . IntroductionThe early successes of William F. Rall, PhD, and coworkers with mammalian embryo vitriication VTF) were based on extensive experimentation, meticulous solution and strawhandling preparations, and precise straw sealing [ , ]. "lthough there was less overt cellular © 2016 The Author(s). Licensee InTech. This chapter is distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.© 2016 The Author(s). Licensee InTech. This chapter is distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.damage, these early investigations simply proved that vitriication was a potentially efective alternative cryopreservation procedure, but not necessarily more efective than conventional slow-freezing methodologies. The degeneration experienced with visually intact vitriied embryos could have been due to the potential cryotoxicity of high-molarity vitriication solutions e.g., VS a = . M glycerol) [ ]. "n alternative consideration involved the importance of warming rates to prevent recrystallization events that could adversely efect cellular survival of vitriied blastomeres [ ]. In the early to mids, most investigations focused on developing safer, less toxic solutions [ -] to improve vitriication success. It was widely accepted that the combined use of less concentrated permeating cryoprotective agents CP"s) made for safer vitriication solutions [ ]. Indeed, by combining permeating CP"s e.g., dimethyl sulfoxide DMSO), ethylene glycol EG), and glycerol GLYC)), and adding ot...

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“…Under cold room experimental conditions, they successfully vitrified mouse embryos in 1985, 11 as previously reviewed. 12 In Rall's 13 efforts to develop an effective procedure working under room temperature conditions, it was determined that propylene glycol was highly toxic at higher concentrations. However, a third-generation vitrification solution (VS3a, a 6.5 M glycerol solution) produced high survival levels and positive pregnancy outcomes in closed one-step 0.25 mL straws, being comparable to conventional slow freezing of mouse embryos 14 and sheep blastocysts.…”

Section: Insights Into the Pioneering Past Of Vitrificationmentioning

confidence: 99%

“…This is particularly true in conjunction with blastocyst biopsy/preimplantation genetic screening (PGS)-single ET applications, 60,61 where over 99% survival can be typically achieved, 62 along with efficient pregnancy success across all age groups following single euploid ET. With embryo and oocyte vitrification being the most significant procedure applied to the assisted reproductive technology (ART) industry since the development of intracytoplasmic sperm injection (ICSI), 12 it is inconceivable why any IVF program would still be applying conventional slow-freeze (SF) procedures. 63 In this era of ART where many different vitrification devices and commercial solutions exist, as well as programs transitioning their cryoinventories from slow frozen to vitrified oocytes and embryos, it is important to realize that 1.0 M sucrose is an effective "universal" warming solution.…”

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confidence: 99%

Vitrification: the pioneering past to current trends and perspectives of cryopreserving human embryos, gametes and reproductive tissue

Schiewe¹,

Anderson²

2017

BSAM

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After more than 2 decades of development in mammalian models and the clinical focus of a few pioneering laboratories, vitrification of human oocytes and embryos has transformed today's assisted reproductive technology (ART) industry. Our ability to cryopreserve gametes and embryos without fear of the damaging effects of ice formation has instilled great confidence in post-warming specimen viability. In turn, clinical treatment options are progressively eliminating fresh embryo transfer (ET; ie, freeze-all cycles), integrating preimplantation genetic screening and contemplating the use of cryopreserved oocytes as a viable resource. Vitrification's impact on clinical treatments is akin to the advent of sperm injection technology in the 1990s on male factor infertility. An appreciable and quantifiable difference was made, with procedural efficacy and global reliability essentially being guaranteed. Yet, there are challenges in the current trends and perspectives in how this technology is and will be optimized in the future. User variation in vitrification products and procedures warrants stricter adherence to quality control measures to enhance specimen biosafety and patient satisfaction, while reducing potential liability concerns. Furthermore, future progress in our understanding of the chemical and cryophysical processes of vitrification will insure the effective cryostorage of reproductive tissues and gametes at a level attained for embryo cryopreservation today.

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The Historic Development and Incorporation of Four Assisted Reproductive Technologies Shaping Today′s IVF Industry

Cited by 6 publications

References 96 publications

Vitrification: Fundamental Principles and Its Application for Cryopreservation of Human Reproductive Cells

Vitrification: Fundamental Principles and Its Application for Cryopreservation of Human Reproductive Cells

Quality Control Factors Influencing the Successful and Reliable Implementation of Oocyte and Embryo Vitrification

Vitrification: the pioneering past to current trends and perspectives of cryopreserving human embryos, gametes and reproductive tissue

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