Cryopreservation procedure does not modify human carotid homografts mechanical properties: an isobaric and dynamic analysis

The viscoelastic and inertial properties of the arterial wall are responsible for the arterial functional role in the cardiovascular system. Cryopreservation is widely used to preserve blood vessels for vascular reconstruction but it is controversially suspected to affect the dynamic behaviour of these allografts. The aim of this work was to assess the cryopreservation's effects on human arteries mechanical properties. Common carotid artery (CCA) segments harvested from donors were divided into two groups: Fresh (n = 18), tested for 24–48 h after harvesting, and Cryopreserved (n = 18) for an average time of 30 days in gas-nitrogen phase, and finally defrosted. Each segment was tested in a circulation mock, and its pressure and diameter were registered at similar pump frequency, pulse and mean pressure levels, including those of normotensive and hipertensive conditions. A compliance transfer function (diameter/pressure) derived from a mathematical adaptive modelling was designed for the on line assessment of the arterial wall dynamics and its frequency response. Assessment of arterial wall dynamics was made by measuring its viscous (η), inertial (M) and elastic (E) properties, and creep and stress relaxation time constant (τC and τSR, respectively). The frequency response characterization allowed to evaluate the arterial wall filter or buffer function. Results showed that non-significant differences exist between wall dynamics and buffer function of fresh and cryopreserved segments of human CCA. In conclusion, our cryopreservation method maintains arterial wall functional properties, close to their fresh values.

[1]  Alain Simon,et al.  Endothelium-dependent arterial wall tone elasticity modulated by blood viscosity. , 2002, American journal of physiology. Heart and circulatory physiology.

[2]  B L Langille,et al.  Determinants of mechanical properties in the developing ovine thoracic aorta. , 1999, The American journal of physiology.

[3]  G. Fahy,et al.  Cryoprotectant toxicity and cryoprotectant toxicity reduction: in search of molecular mechanisms. , 1990, Cryobiology.

[4]  A. Seifalian,et al.  Compliance properties of conduits used in vascular reconstruction , 2000, The British journal of surgery.

[5]  E. Bos,et al.  Cracks in cryopreserved aortic allografts and rapid thawing. , 1995, The Annals of thoracic surgery.

[6]  D. Pegg,et al.  Fractures in cryopreserved elastic arteries. , 1997, Cryobiology.

[7]  Daniel Bia Santana,et al.  Pulmonary artery smooth muscle activation attenuates arterial dysfunction during acute pulmonary hypertension. , 2005, Journal of applied physiology.

[8]  M. Toner,et al.  Long-term storage of tissues by cryopreservation: critical issues. , 1996, Biomaterials.

[9]  R. Dawber,et al.  The response of keloid scars to cryosurgery. , 1982, Plastic and reconstructive surgery.

[10]  M. Adham,et al.  Cryopreserved arterial homografts: Preliminary study , 1993, Annals of vascular surgery.

[11]  Z. Krasiński,et al.  The mechanical properties of fresh and cryopreserved arterial homografts. , 2000, European journal of vascular and endovascular surgery : the official journal of the European Society for Vascular Surgery.

[12]  R. Mallo,et al.  Functional assessment of cryopreserved human aortas for pharmaceutical research , 2004, Cell and Tissue Banking.

[13]  Lysle H. Peterson,et al.  Mechanical Properties of Arteries in Vivo , 1960 .

[14]  R. Dawber Cold kills! , 1988, Clinical and experimental dermatology.

[15]  J. van Marle,et al.  Function of cryopreserved arterial allografts under immunosuppressive protection with cyclosporine A. , 1996, Journal of vascular surgery.

[16]  J P Shepherd,et al.  Wound healing and scarring after cryosurgery. , 1984, Cryobiology.

[17]  L. Gamero,et al.  Identification of Arterial Wall Dynamics in Conscious Dogs , 2001, Experimental physiology.

[18]  H. Akaike Fitting autoregressive models for prediction , 1969 .

[19]  G. Sanz,et al.  Changes in the cooling rate and medium improve the vascular function in cryopreserved porcine femoral arteries. , 2000, Journal of vascular surgery.

[20]  Giuseppe Pontrelli,et al.  Numerical modelling of the pressure wave propagation in the arterial flow , 2003 .

[21]  J Baulieux,et al.  Mechanical characteristics of fresh and frozen human descending thoracic aorta. , 1996, The Journal of surgical research.

[22]  Damián Craiem,et al.  Respuesta en frecuencia de la pared arterial: ¿inocente o culpable de las discrepancias entre filtrado sistémico y pulmonar? , 2003 .

[23]  A Noordergraaf,et al.  Arterial viscoelasticity: a generalized model. Effect on input impedance and wave travel in the systematic tree. , 1970, Journal of biomechanics.

[24]  Ricardo LuisArmentano,et al.  Arterial Wall Mechanics in Conscious Dogs , 1995 .

[25]  R. Armentano,et al.  Smooth muscle role on pulmonary arterial function during acute pulmonary hypertension in sheep. , 2004, Acta physiologica Scandinavica.

[26]  W. Blondel,et al.  Rheological properties of fresh and cryopreserved human arteries tested in vitro , 2000 .

[27]  I. Álvarez,et al.  Progress of National Multi-tissue Bank in Uruguay in the International Atomic Energy Agency (IAEA) Tissue Banking Programme , 2004, Cell and Tissue Banking.

[28]  C. Hunt,et al.  Fractures in cryopreserved arteries. , 1994, Cryobiology.

[29]  Lennart Ljung,et al.  System Identification: Theory for the User , 1987 .

[30]  R Armentano,et al.  Effects of hypertension on viscoelasticity of carotid and femoral arteries in humans. , 1995, Hypertension.

[31]  A. Seifalian,et al.  In vivo femoropopliteal arterial wall compliance in subjects with and without lower limb vascular disease. , 1999, Journal of vascular surgery.

[32]  G. Pascual,et al.  Gradual thawing improves the preservation of cryopreserved arteries. , 2001, Cryobiology.

[33]  Damián Craiem,et al.  El músculo liso vascular de las grandes arterias: ¿sitio de control local de la función de amortiguamiento arterial? , 2003 .

[34]  R. Armentano,et al.  [The vascular smooth muscle of great arteries: local control site of arterial buffering function?]. , 2003, Revista espanola de cardiologia.

[35]  G. Pascual,et al.  The use of ischaemic vessels as prostheses or tissue engineering scaffolds after cryopreservation. , 2002, European journal of vascular and endovascular surgery : the official journal of the European Society for Vascular Surgery.

[36]  G. Fahy,et al.  Some emerging principles underlying the physical properties, biological actions, and utility of vitrification solutions. , 1987, Cryobiology.

[37]  Alexander M Seifalian,et al.  Improving the clinical patency of prosthetic vascular and coronary bypass grafts: the role of seeding and tissue engineering. , 2002, Artificial organs.

[38]  J. Stoltz,et al.  Early rupture and degeneration of cryopreserved arterial allografts. , 1997, Journal of vascular surgery.