Ariadna Corral

Assessment of the cryoprotectant concentration inside a bulky organ for cryopreservation using X-ray computed tomography

Cryoprotection of bulky organs is crucial for their storage and for subsequent transplantation. In this work we demonstrate the capability of the X-ray computed tomography (CT) as a non-invasive method to measure the cryoprotectant (cpa) concentration inside a tissue or an organ, specifically for the case of dymethil sulfoxide (Me2SO). It is remarkable that the use of Me2SO has been leader in techniques of cells and tissues cryopreservation. Although CT technologies are mainly based in density differences, and many cpas are alcohols with densities similar to water, the use of very low energies as acceleration voltage (∼70 kV) and the sulfur atom in the molecule of Me2SO makes possible the visualization of this cpa inside tissues. As result we obtain a CT signal proportional to the Me2SO concentration with a spatial resolution up to 50 μm in the case of our device.

Ovarian tissue cryopreservation by stepped vitrification and monitored by X-ray computed tomography

Ovarian tissue cryopreservation is, in most cases, the only fertility preservation option available for female patients soon to undergo gonadotoxic treatment. To date, cryopreservation of ovarian tissue has been carried out by both traditional slow freezing method and vitrification, but even with the best techniques, there is still a considerable loss of follicle viability. In this report, we investigated a stepped cryopreservation procedure which combines features of slow cooling and vitrification (hereafter called stepped vitrification). Bovine ovarian tissue was used as a tissue model. Stepwise increments of the Me2SO concentration coupled with stepwise drops-in temperature in a device specifically designed for this purpose and X-ray computed tomography were combined to investigate loading times at each step, by monitoring the attenuation of the radiation proportional to Me2SO permeation. Viability analysis was performed in warmed tissues by immunohistochemistry. Although further viability tests should be conducted after transplantation, preliminary results are very promising. Four protocols were explored. Two of them showed a poor permeation of the vitrification solution (P1 and P2). The other two (P3 and P4), with higher permeation, were studied in deeper detail. Out of these two protocols, P4, with a longer permeation time at -40 °C, showed the same histological integrity after warming as fresh controls.

Integrated anion-exchange cartridge for [18F]F-preconcentration in a PDMS radiopharmacy chip

Microfluidic techniques have demonstrated an important impact on radiochemical reactions for Positron Emission Tomography (PET), due to smaller reaction times and precursor quantities.

An optimized controlled rate slow cooling protocol for bovine ovarian tissue cryopreservation by means of X-ray computed tomography

Cryopreservation and subsequent transplantation of ovarian tissue is the only option to preserve fertility in certain patients facing gonadotoxic treatment. So far, cryopreservation of ovarian tissue has been carried out mostly by a controlled rate slow cooling process, typically known as slow freezing. Even though there are still some concerns about the iatrogenic damage on the follicle population, this technique has been used in the more than 100 live births reported to date. It is well known that the control of the cryoprotectant loading in the tissue is crucial to in a cryopreservation procedure. We have used the technology of X-ray computed tomography to assess the concentration and distribution of dimethyl sulfoxide (one of the cryoprotectants most used in fertility preservation) inside pieces of bovine ovarian tissue after its cryopreservation. The low voltage used in our device (75 kV) and the high electronic density of this cryoprotectant makes the X-ray attenuation proportional to its concentration. By assessing and comparing the permeation and homogeneity of the cryoprotectant inside ovarian tissue fragments subjected to a controlled rate slow cooling process, we have characterized the effect of variations in the main parameters involved in the process, with the goal of achieving an optimized protocol with higher permeation of the cryoprotectant in the tissue. The most promissory results were obtained by increasing the initial concentration of dimethyl sulfoxide in the vehicle solution from 10 to 20%v/v.

Evaluation of a new freezing protocol containing 20% dimethyl sulphoxide concentration to cryopreserve human ovarian tissue

RESEARCH QUESTION Could a modification in the ovarian tissue freezing protocol improve follicle survival after cryopreservation and xenotransplantation? DESIGN Ovarian tissue was used from 13 adult patients, frozen either with our original protocol, or a modified version involving a higher concentration of dimethyl sulphoxide (DMSO), larger volume of cryopreservation solution and lower seeding temperature. After thawing, the ovarian fragments were xenotransplanted to six mice with severe combined immunodeficiency (SCID) for 3 weeks. RESULTS The proportion of primordial follicles decreased, and the proportion of growing follicles increased significantly (all P < 0.01) after cryopreservation and xenografting compared with fresh controls for both protocols. Follicle density, development, ultrastructure and function were similar between treatments. CONCLUSIONS This study showed that, although the higher DMSO concentration did not improve survival of preantral follicles, it did not seem to induce any major toxicity in the follicle population either.

Room temperature synthesis of water-dispersible Ln 3+ :CeF 3 (Ln=Nd, Tb) nanoparticles with different morphology as bimodal probes for fluorescence and CT imaging

The singular properties of lanthanide-based inorganic nanoparticles (NPs) has raised the attention of the scientific community in biotechnological applications. In particular, those systems with two or more functionalities are especially interesting. In this work, an effective and commercially attractive procedure has been developed that renders uniform, water-dispersible Ln3+:CeF3 (Ln = Tb, Nd) NPs with different shapes and size. The method consists of the homogeneous precipitation, in a mixture of polyol and water, of cations and anions using precursors that allow the controlled release of the latter. The advantages of the reported method are related to the absence of surfactants, dispersing agents or corrosive precursors as well as to the room temperature of the process. The obtained Tb:CeF3 NPs produce an intense emission after excitation through the Ce-Tb energy transfer band located in the UV spectral region, thus being potentially useful as phosphors for in-vitro imaging purposes. On the other hand, the synthesized Nd:CeF3 NPs are good candidates for in-vivo imaging because their excitation and emission wavelengths lie in the biological windows. Finally, the excellent X-ray attenuation efficacy of the Nd:CeF3 NPs is shown, which confers double functionality to this material as both luminescence bioprobe and contrast agent for X-ray computed-tomography.