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May 25th, 2016 May 26th, 2016 May 27th, 2016 May 28th, 2016 June 3th, 2016 July 7th, 2016 July 22th, 2016 Octo 7th, 2016
Aim: Preparing cellulose solutions to be spread on the support, perform different concentration tests. The cellulose being an integral part of the patch, we need to determine different solubility levels in order to constitute the correct mix for forming a solid support. Manipulation: • cellulose solution in water and ethanol • cellulose used = carboxymethyl-cellulose (CMC) • Total volume = 40 ml solutions -> 40 g precisely (final weight) Cellulose solutions in water :
Solution | % weight referred | m (cellulose) referred (g) | m final 5 (g) | m water added |
---|---|---|---|---|
(1) |
1.25 | 0.5 | 0.548 | 40.162 |
(2) |
2 | 0.8 | 0.818 | 39.541 |
(3) |
3 | 1.2 | 1.216 | 40.401 |
(4) |
5 | 2 | 2.052 | 38.305 |
(5) |
10 | 4 | 4.029 | 36.192 |
(6) |
15 | 6 | 6.099 | 35.179 |
(7) |
20 | 8 | / | / |
Aim: Determine the solid support on which the spreading of the cellulose solution is optimal in view of evaporation of the solvent. The cellulose based patch needs to be created out of the dissolved cellulose solutions; in order to do that the solvent needs to be evaporated by spreading the mix over a solid support. Principle: Spreading on media, qualitative evaluation of substrate wetting, and evaporation. Manipulation: Spread with a flat spatula and qualitative assessment of the dampening (flexibility of the constituted solid surface).
Aim: Produce a patch with pure cellulose powder to avoid the problem of too low concentration. After the difficulties with the water/EtOH_Cellulose mixtures, we decided to use pure cellulose in a compressed form. Principle: Compress the powder to assess the surface produced by such method. The shape of the patch is given by a mold used in the pressor compartment. The powder is first compressed into a rectangular mold 1 mm thick at 200 bar and at room temperature. The result is quite satisfactory: a friable solid is obtained. To harden the materiel obtained, the same experiment is conducted by adding a few drops of water on top. After compression, the powder was solidified in part and a few grainy bits remained. It is therefore necessary to mix water and the powder before compressing. A water-cellulose mixture is then prepared: 3.42 g of cellulose and 3 g of water. It gives a mixture of 53% cellulose. It has a paste like texture. The compression plates have been heated beyond our control. We proceeded with cutting the shapes are by lack of time. The only powder is compressed into a mold in the form of 0.5 mm thick test piece. plate temperature is 90 °C. The result is the same, a brittle solid. The mixture at 53 °C cellulose is then compressed at 80 °C in the same mold. A flexible and resistant film is obtained. It is a bit transparent. The patches obtained are then immersed in water in order to simulate for the reaction of the patch to the incorporation of proteins and to the silification. We observed that after 1 minute 45 s, the patch from the cellulose-water mixture softens but doesn't disaggregate. It can be recovered in a solid form. After 2 min, the patch from the cellulose only (without water) powder curves but remains strong. The patches are then allowed to dry in the open area. Conclusion: This method is suitable for manufacturing. It remains to determine how to incorporate protein and silica.
Aim: Improve cellulose patch and drying results. We have pursued the testing of the patches for mechanical properties and for resistance to water in order to mimic the conditions that would be faced in the presence of protein solutions. Results of drying after immersion patches of May 27, 2016: Both patches have hardened to give a patch that holds itself (good mechanical properties). One obtains a similar result to a higher concentration of water patch. → We keep the mechanical strength after immersion and drying. This result is similar to the texture we are looking for our patch.
Aim: Produce patches with the cellulose powder by testing other cellulose concentrations, and other temperatures. We would like to explore other conditions for formong the patches, thereore we plan other experiments including other ratios of water:cellulose, pressures and temperatures. Principle: Compress the powder (with water optionally) with a press for discharging air in the cellulose powder, or for expelling excess water. The shape of the patch is given by a mold. Manipulation: • Preparation of a 75% paste, composed of 4.5 g of cellulose + 1.5 g of water → Paste A • Preparation of another pulp 75%, 4.5 g cellulose + 1.5 g of water → Paste B • Preparation of a pulp 65%, 3.9 g cellulose + 2.1 g of water → Paste C • Compression of the Paste A to 200 bar at room temperature (2 min). We obtained an opaque patch, some areas have dried, there is a good mechanical strength, not too brittle. • Compression of the Paste B to 200 bars at 70 ° C (2 min). We obtained a patch with interesting properties: it has intermediate mechanical properties, smooth, more rigid than that at 65% and 53%; however, it is somewhat brittle. • Compression of the Paste C to 200 bars at 70 ° C (2 min). A translucent patch is obtained, flexible, almost identical to Paste B. Conclusion: The pulp at 75% cellulose seems to have given the most interesting result for its mechanical properties and its apparent homogeneity before and after immersion / drying. The temperature of 70 °C seems well suited to the specifications of the patch.
Aim: Make new patches bu using Kapton tape (adhesive coating, Dupont) to strengthen them. Test different concentrations, temperatures, and types of cellulose. (+ influence of a protein on compression). We need a solid surface on which to lay our cellulose patching fabrication. After testing paper, cotton, aluminum and plastic, we will test Kapton, which is used as a tape in spacecraft industry. Principle: Compression of microcrystalline cellulose powder with a press to evacuate air. The shape of the patch is given by a mold. Manipulation: • Preparation of two 100% cellulose patches to determine the actual weight of powder required to make a patch (2 types of cellulose: Avicel and Sigmacell- 50 µm crystal MCC) Patch n°: 1) 100% Sigmacell, 200 bars, 2 min, RT, Kapton tape 2) 100% Avicel, 200 bars, 2 min, RT, Kapton tape N.B.: 3 g of powder are required to make a patch (2 g display) • Preparation of two patches (one with a protein and another without) to determine whether a protein has an influence on compression. Solution of protein: 3 mg of BSA (Bovine Serum Albumin) in 1 ml of distilled water. 2 patches: 3) 50% (1 g cellulose + 1 ml BSA solution at 3 mg/ml), Sigmacell, 200 bars, 2 min, RT, adhesive Kapton 4) 50% (1 g cellulose + 1 ml water), Sigmacell, 200 bars, RT, adhesive Kapton, 2 min. → The presence of protein doesn’t change anything anything to the mechanical properties of the patch. We can therefore proceed with the experiment the point when well will need to add our protein to the patch. Aim: We need to start again this experiment since the protein wasn’t in a buffer (Tris, NaCl)→hydrophobic parts aggregate → which may lead to phase separation. We neede to test this environment for the protein, as unlie BSA which behave moderately well in distilled water, we have to anticipate that or protein construct which will be a fusion protein, might require a buffer to keep it in a stable state. Preparation of several patches to test concentration:
w/w % | Cellulose weight (g) | Water weight (g) |
---|---|---|
60 |
1.8 | 1.2 |
70 |
2.1 | 0.9 |
80 |
2.4 | 0.6 |
90 |
2.7 | 0.3 |
Aim: See if it is possible to use Coomasie blue to reveal the presence of the viral protein. Our aim in this experiment is to evaluate the amount of protein retained on the cellulose layer. We will use the capacity of Coomassie blue to stain proteins (lysine, arginine) in order to estimate the amount bound. Principle: Pour Coomasie blue on the patch and wash it with water. Experiment: • The Coomassie blue was poured on the 65% carboxymethyl cellulose (CMC) and then, the patch was washed. • Washing the patch during around 15 seconds was enough to significantly remove the color. • The same experiment is carried out on the patches 12, 11 and 9 Washing the patch during several seconds is not enough to remove the color They are immersed in water for decoloration during 30 min. We need to improve this method of estimation of the amount of protein bound. One other method is to soak the patch in a solution of known protein concentration, followed by the estimation of the amount of protein left after the patch has been removed. We plan to use the Bradford assay, using a standard curve based on BSA fo rthis experiment.
Aim: Prepare various patches with the silicated C2 protein in them, for immuno-assays and traction tests. Materials: • Avicell commercial cellulose • Silicated C2 protein from previous weeks • Scale and a press Protocol: see the patch compression protocol Experiment: We prepared: • a 100% Avicell patch • a 100% CMC patch • a 10mm diameter patch with 66%wt of Avicell: 50mg of silicated C2 protein + 100mg of Avicell • a 10mm diameter patch with 66%wt of CMC: 50mg of silicated C2 protein + 100mg of CMC • ten 3mm diameter patch with 50%wt of Avicell: 50mg of silicated C2 protein + 50mg of Avicell • ten 3mm diameter patch with 66%wt of Avicell: 50mg of silicated C2 protein + 100mg of Avicell