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Applying principles of Cryobiology in Biobanking

Applying principles of Cryobiology in Biobanking. Barry J Fuller Professor in Surgical Sciences & Low Temperature Medicine Division of Surgery & Interventional Sciences, UCL Medical School DI for Royal Free Hospital HTA Tissue Storage Licences UNESCO Chair in Cryobiology.

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Applying principles of Cryobiology in Biobanking

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  1. Applying principles of Cryobiology in Biobanking Barry J Fuller Professor in Surgical Sciences & Low Temperature Medicine Division of Surgery & Interventional Sciences, UCL Medical School DI for Royal Free Hospital HTA Tissue Storage Licences UNESCO Chair in Cryobiology Disclosure : The works described have been carried out as academic collaborations and grant-funded studies; I have no commercial interests in the technologies

  2. A combination of cold temperatures and phase change in water Cryobiology a term first used in 1960’s - (Cryos = Cold) • History of applied cryobiology • Current understanding of the technologies – Slow Cooling or Vitrification, Warming • Implications for different Biobanking applications

  3. Direct observation – microscopy - played a significant part in the history of cryobiology Freezing is a dehydration stress – and all of the (bio)chemistry that implies Red onion epidermis cooled (14a) and frozen at -10oC. Note the cell shrinkage and pigment concentration

  4. History – Pivotal moments in Modern Cryobiology 1. The application of glycerol to allow revival if sperm after deep freezing to -79oC, 1949. 2. The successful recovery of blood cells (Meryman, Rowe, Huggins), and mammalian embryos form -196oC using Glycerol or DMSO – over next 30 years 3. Equalled by development of sophisticated cryomicroscopy (1970’s ) which allowed direct observation of freezing to deep cryogenic temperatures

  5. History - Water into Ice and its’ consequences - Excluding solutes and cells – the need for Cryoprotection Cells at -8oC shrinking in the hypertonic solution in between ice crystals Lovelock suggested that salt dehydration was a major factor in freezing injury By adding neutral solutes can achieve colligative effects and reduce salt concentrations – the reason why Polge had succeeded – this spurred the search for cryoprotectants (CPA) LOVELOCK JE, BISHOP MW. Nature. 1959 May 16;183(4672):1394-5. Prevention of freezing damage to living cells by dimethyl sulphoxide.

  6. Dimethyl sulphoxide propylene glycol ethylene glycol glycerol CPA- Essential Antifreezes for Life ‘Water-modifying’ agents -some CPA are cell permeating or ‘Intracellular’, comprising small polyols like glycerol or others such as DMSO. Usually have a H-bonding sites for water and high oil / water partition (since they need to getinside the cells) and stabilisebiomolecules Others are polymers and sugarswhich perturb water / ice transitions OUTSIDEthe cells – and can be used to start optimal cryogenic dehydration ‘2nd-ary’ CPA – in the external medium

  7. History & current CPA addition and removal results in osmotic stress before / after freezing. Concepts of Cumulative CPA-related Injury – the safe boundaries Addition Removal 150% 125% Cell volume changes 100% Zone of Tolerance 75% 50% CPA exposure protocols need to be optimised

  8. There is essential control of cooling profile to allow optimal cryogenic cell dehydration(Slow cooling) down to the stable cryogenic temperatures – the concept of the ‘glassy state’ (This can be measured by physical means as Tg) If cooling is Too Fast – something else happens – intracellular ice! Mazur’s two factor hypothesis – cool too slow – over-long osmotic stress; Cool too fast – residual mobile intracellular water forms lethal ice So…. Successfully frozen cells and tissues are… Not Frozen!

  9. Cryopreservation by Slow Cooling – Locking up the water – Ice is the Desiccant +37oC +20oC Ice formation - need for cryoprotection +0oC Locking up the water – Zone of freeze dehydration -25oC -50oC Matrix solidification Zone of instability (ice, salt hydrates, proteins) -100oC Glass transition range Optimised cryogenic dehydration True long term cryogenic stability -190oC Our ‘convenient friend’ Liquid N2

  10. The other way to go – Vitrification This also depends on the Glass Transition range which can be physically determined Bill Rall & Greg Fahy Ice-free cryopreservation of mouse embryos at -196 degrees C by vitrification.* Nature. 1985 Feb 14-20;313(6003):573-5. Very difficult to avoid any tiny ice nuclei forming somewhere High concentrations of CPA, polyols, sugars (>40% w/w) plus fast cooling to prevent ice nucleating before reaching ‘glassy’ state at ultra-low temperatures * LUYET BJ, GEHENIO Thermoelectric recording of ice formation and of vitrification during ultra-rapid cooling of protoplasm. PM.Fed Proc. 1947;6(1 Pt 2):157.

  11. History & current Schematic of Vitrification profile Now CPA is the Desiccant CPA preload – 10%w/v +25oC VF mix – 40% CPA + sugars +0oC Practically -this is not an equilibrium state Therefore small volumes and extremely rapid cooling and warming used to ‘out-race’ the start of ice crystal nucleation -25oC -50oC Small containers with rapid heat transfer -100oC Glass transition temperature Optimised cryogenic dehydration ‘Almost glassy’ -190oC 5 min Time

  12. Tissue Cryopreservation – the Same Biophysical Events with Additional Diffusion Barriers And where the Ice crystals form Ice forming externally and in interstitial spaces producing cell dehydration CPA diffusion In / Out Heart valve leaflet cryopreserved with DMSO. Freeze substitution EM at -90o C Showing Interstitial Ice In: K Brockbank et al. Methods in Cryopreservation and Freeze-Drying, Methods in Molecular Biology, 2015.

  13. Tissue Cryopreservation – Ovarian Tissue as exampleHistorical & Current Perspectives Goals – to preserve the ability of follicles (oocyte + supporting cells) to grow and acquire mature characteristics (Must maintain cell-cell communications and signaling) • Mill Hill Group (1950-60); Green et al, 1956. J Endocrin 13 330 • Rat ovarian autografts after freezing in 15% glycerol in saline, 1h exposure, slow cooling, pieces, sub-cut, days 2-30.Oestrous cycling returned. The Modern Era - Donnez J et al. (2004) Lancet 364, 1405-1410 • Slow Cooling with 1.5M DMSO (1) −8°C at −2°C/min; (2) seeded manually (3) cooled to −40°C at −0·3°C/min; (4) cooled to −150°C at −30°C/min, and (5) transferred to liquid nitrogen (−196°C). Tissue cryopreserved for 6 years Some current research – using an electrical stirling cryo-cooler – Theatres compliant avoiding Liq N2

  14. Tissue Cryopreservation - ‘Fusion’ Biobanking (e.g. Recovering viable lymphocytes from frozen tumour) David Gilham & Clinical and Experimental Immunotherapy Group Institute of Cancer Sciences University of Manchester Selection / Ex vivo Expansion Isolate tumour Formulation Infusion Disaggregate tumour >5 fold expansion of cells recovered after tumour cryo Cryo-banking options Fresh 8/11 (73%) PBS/HSA/DMSO: Coolcell 6/8 (75%) EF600 4/5 (80%) Cryostor10 Coolcell 5/7 (71%) EF600 4/5 (80%) Theatre compliant cryo-cooler for immediate cryo-processing Freezing disaggregated tumour has no obvious impact upon success rate of TIL culture initiation Preliminary experiments involving cryopreserving intact tumour prior to disaggregation has had widely variable results

  15. Tissue Cryopreservation - only important if you need living cells? Not quite…………………… For tissues, Preservation of Biomatrix by Optimised Cryogenic Dehydration can be equally important, irrespective of cell viability Cryopreserved -90oC Vitrified -90oC For heart valve leaflets, better structure (less oedema and inflammation) followed Vitrification which preserved biomatrix AND destroyed resident cells – reducing Allograft reaction (more Cryo-Processing opportunities)

  16. The Challenges of Warming Water becomes mobile above Tg’ – and Ice Re-crystallises Generally, faster is better….to avoid Intracellular Ice during warming…..easy for cell suspensions. But for large volumes, and intact tissues, Cryo-Materials Sciences become important Differential temperature gradients during rapid warming, coupled with expansion or contraction, causes mechanical stress, especially around the glass transition range One way to avoid thermo-mechanical stress is to use differential warming; slow to -80oC, then fast to optimise cell survival

  17. Translational Biobanking At the level of individual analytes, the same consequences follow progressive ice formation and increase in salts in the unfrozen fraction Changes e.g. in protein folding may be small, reversible, and not relevant to Biobanking as generally considered. But for sensitive proteins or therapeutic biobanking, there may often be explanations for ‘the protein doesn’t freeze well’. And it is possible to protect against freezing injury – if you have to - with – sugars, polyols Often also called ‘excipients’

  18. Translational Biobanking For Practical Biobanking Understanding the biophysical events during cryogenic storage can help to plan protocols with a wider application Addition of protectants, water replacement molecules, may have a role – depending on what outcomes you require Glycine betaine is a Quat Ammonium salt found as an osmolyte in plants, crustaceans exposed to salt stress…………

  19. Another way to get Vitrification – in large tissues - ‘slide’ down and up the liquidus curve – incrementally increase CPA and cool step by step - stay to the right of ice formation curve For the next decade - Avoiding Ice in Large Volumes - Liquidus Tracking(?) Directions Equipment to add CPA, mix and cool at the same time Fine balance between lethal high CPA concentrations and too low CPA as cooling proceeds - with lethal ice nuclei formation – but for large complex structures (cartilage, ovarian or testicular tissues) it may be worth the effort. Pegg DE et al; Cryopreservation of articular cartilage. Part 3: the liquidus-tracking method. Cryobiology. 2006 52(3):360-8.

  20. Summary • By applying principles of Cryobiology, Tissue Banking can be a successful key component of many different therapies and diagnostic services • More research is still needed on fundamental cryobiology, long-term outcomes after cryopreservation, on better and safer techniques • The 2nd Age of Cryo – fully understanding biophysical changes in cells transitioning the cryogenic range and any subtle molecular / genetic impacts so far hidden from view

  21. Acknowledgements Reproductive Biobanking : Paul Hardiman, Tom Morewood (UCL); Victoria Keros, (Karolinska); Sharon Paynter (Cardiff) Cryobiology : Clare Selden, Humphrey Hodgson, Isobel Massie, Eva Puschmann, Peter Kilbride, Stephanie Gibbons, Aurelie leLay (UCL) Translational Cryobiology : TSB consortium; University of Manchester, UK Stem Cell Bank, Roslin Cells; John Morris (Asymptote UK) Cryo-technology : Steve Butler, Geoffrey Planer (Planer UK) Planer UK Technology Strategy Board

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