Hyaluronic Acid Functionalization with Jeffamine® M2005: A Comparison of the Thermo-Responsiveness Properties of the Hydrogel Obtained through Two Different Synthesis Routes
<p>(<b>a</b>) FTIR spectrum of HA<sub>38</sub> (<b>top</b>), HA<sub>38</sub>-g<sub>(EDC)</sub>-M2005-3.6% (<b>middle</b>), and M2005 (<b>bottom</b>) and (<b>b</b>) HA<sub>140</sub> (<b>top</b>), HA<sub>140</sub>-g<sub>(EDC)</sub>-M2005-3.9% (<b>middle</b>), and HA<sub>140</sub>-g<sub>(T3P)</sub>-M2005-8.3% (<b>bottom</b>).</p> "> Figure 2
<p><sup>1</sup>H NMR spectrum of HA<sub>1200</sub>-g<sub>(EDC)</sub>-M2005-4.5% in D<sub>2</sub>O.</p> "> Figure 3
<p><sup>1</sup>H NMR spectrum of (<b>a</b>) HA<sub>38</sub>-<span class="html-italic">g</span><sub>(T3P)</sub>-M2005-8.3% and (<b>b</b>) HA<sub>140</sub>-<span class="html-italic">g</span><sub>(T3P)</sub>-M2005-8.3% in D<sub>2</sub>O.</p> "> Figure 4
<p>(<b>a</b>) Molar mass distribution of HA<sub>38</sub> (blue), HA<sub>38</sub>-<span class="html-italic">g</span><sub>(EDC)</sub>-M2005-3.6% (red), and HA<sub>38</sub>-<span class="html-italic">g</span><sub>(T3P)</sub>-M2005-8.3% (green) (<b>b</b>) Molar mass distribution of HA<sub>140</sub> (blue), HA<sub>140</sub> after reticulation with T3P<sup>®</sup> (red), and HA<sub>140</sub>-<span class="html-italic">g</span><sub>(T3P)</sub>-M2005-8.3% (green); full lines: DRI; dotted lines: LS; full circles: molar mass distribution.</p> "> Figure 5
<p>Rheological profile of (<b>a</b>) HA<sub>1200</sub>-<span class="html-italic">g</span><sub>(EDC)</sub>-M2005-4.5% at 1 wt% in water and (<b>b</b>) HA<sub>1200</sub>-<span class="html-italic">g</span><sub>(EDC)</sub>-M2005-2.7% at 1 wt% in water. Heating ramp: G′ (blue square), G″ (red rhombus), η* (green triangle) vs temperature; measurement in oscillation mode (parameters: shear stress: 0.1 Pa; frequency: 1 Hz; rate: 0.5 °C.min<sup>−1</sup>).</p> "> Figure 6
<p>Rheological profile of (<b>a</b>) HA<sub>38</sub>-<span class="html-italic">g</span><sub>(T3P)</sub>-M2005-8.3% at 11 wt% in water (<b>b</b>) HA<sub>38</sub>-<span class="html-italic">g</span><sub>(T3P)</sub>-M2005-8.3% at 3 wt% in water (<b>c</b>) HA<sub>140</sub>-<span class="html-italic">g</span><sub>(T3P)</sub>-M2005-8.3% at 6 wt% in water and (<b>d</b>) HA<sub>140</sub>-<span class="html-italic">g</span><sub>(T3P)</sub>-M2005-5.5% at 6 wt% in water. Heating ramp: G′ (square), G″ (rhombus), η* (triangle) vs. temperature; measurement in oscillation mode (parameters shear stress: 0.02 Pa (<b>a</b>,<b>b</b>), 0.1 Pa (<b>c</b>) or 0.5 Pa (<b>d</b>); frequency: 1 Hz; heating rate: 0.5 °C.min<sup>−1</sup>).</p> "> Scheme 1
<p>Mechanism of the grafting of M2005 to HA (water route).</p> "> Scheme 2
<p>Proposed mechanism of the grafting on M2005 to HA (organic solvent route). (<b>a</b>) Conversion of Na-HA to its TBA salt through two steps: (1) acidification with a DOWEX cationic ion exchange resin overnight (the resin is then filtered off the solution) and (2) neutralization of the resulting hyaluronic acid with TBAOH. (<b>b</b>) Activation of TBA-HA with T3P<sup>®</sup> followed with nucleophilic substitution with M2005, resulting in HA-g-M2005.</p> ">
Abstract
:1. Introduction
2. Results and Discussion
2.1. Synthesis of HA-g(EDC)-M2005 in Water
2.2. Synthesis of HA-g(T3P)-M2005 in Polar Aprotic Solvent
2.3. Physicochemical Properties of HA-g-M2005
2.3.1. Conformational Properties Extracted from SEC/MALS
Reaction with EDC/NHS in Water
Reaction with T3P® in DMF
Rheological Properties and Temperature Induced Hydrogel Formation
Rheological Properties of HA-g(EDC)-M2005
Rheological Properties of HA-g(T3P)-M2005
3. Conclusions
4. Materials and Methods
4.1. Materials
4.2. Synthesis of HA-g-M2005
4.2.1. Synthesis in Water with EDC/NHS
4.2.2. Synthesis of HA-g-M2005 in Organic Solvent
- Conversion of sodium hyaluronate to tetrabutylammonium hyaluronate: 5 g of HA were dissolved overnight in 830 mL at room temperature. Then the cation exchange resin (H+) (45 g) was introduced in the solution, which was left to stir overnight. The resin was subsequently filtered off the solution through a sintered glass filter, whose porosity was adjusted depending on the viscosity of the HA solution. The obtained filtered hyaluronic acid solution was then neutralized with TBAOH for getting tetrabutylammonium hyaluronate TBA-HA as follows: Tetrabutylammonium hydroxide (TBAOH) 54–56 wt% in water was diluted fivefold with water prior to the reaction. It was subsequently added drop-wise to the previously prepared hyaluronic acid solution until the pH reached 8. The solution was then freeze-dried and the resulting solid kept in a freezer until further use.
- M2005 grafting on TBA-HA in DMF with T3P®: The grafting on reaction was adapted from Schleeh et al. [25], with an example given as follows: 2.5 g TBA-HA (4.03 mmol, from batch HA38) were dissolved in 30 mL anhydrous DMF at room temperature in a three-neck flask which was thereafter put under nitrogen. Then, 4.7 mL of T3P® (50 wt% in DMF) were added to the mixture, which was left to stir for one hour at room temperature. Meanwhile, 15.96 g M2005 were dissolved in 15 mL anhydrous DMF. After TBA-HA was activated by T3P® for one hour, 568 µL of TEA were added to the solution, immediately followed with the M2005 solution (the flask was rinsed with 2.5 mL DMF). The final TBA-HA concentration was 50 g.L−1, which was respectively adjusted to 10 g.L−1 for HA140 and to 6 g.L−1 for HA1200 by increasing the amount of DMF used to dissolve TBA-HA. The reaction was left overnight at room temperature. The day after, 25 mL of a 2.5 M solution of NaCl were added drop-wise to the reaction vessel, which was subsequently left to stir for 30min before being poured in 250 mL acetone to precipitate the modified hyaluronic acid. The material was then recovered through filtration, dissolved in 350 mL 0.1 M phosphate buffer (pH: 7.5) and then dialyzed against water until the resulting conductivity of water was found to be as close as Milli-Q as possible, indicating removal of the impurities; this was followed eventually by freeze-drying of the material. In order to completely remove the unreacted M2005, the material was washed several times in acetone until no more variation of the 1H NMR peaks corresponding to M2005 was observed.
4.3. Characterisation Methods
4.3.1. Infrared Spectroscopy
4.3.2. 1NMR Spectroscopy
4.3.3. SEC/MALS/DRI/Viscometer
4.3.4. Rheology
Supplementary Materials
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Sample | nM2005/nHA | nT3P/n TBA-HA | nTEA/nTBA-HA | DS |
---|---|---|---|---|
HA38-g(EDC)-M2005-3.6% | 1 | - | - | 3.6 % a |
HA38-g(T3P)-M2005-8.3% | 2 | 2 | 1 | 8.3 % b |
HA140-g(EDC)-M2005-3.9% | 1 | - | - | 3.9 % a |
HA140-g(T3P)-M2005-5.5% | 2 | 0.3 | 0.3 | 5.5 % b |
HA140-g(T3P)-M2005-8.3% | 2 | 2 | 1 | 8.3 % b |
HA1200-g(EDC)-M2005-2.7% | 1 | - | - | 2.7 % a |
HA1200-g(T3P)-M2005-3.7% | 2 | 0.3 | 0.3 | 3.7 % b |
HA1200-g(EDC)-M2005-4.5% | 5 | - | - | 4.5 % a |
Sample | Mn (g.mol−1) | Mw (g.mol−1) | Đ | DPn | Mass Recovery | [η]w (mL.g−1) | Rhw (nm) | Rgw (nm) | a (Mark Houwink) |
---|---|---|---|---|---|---|---|---|---|
HA38 | 38,000 | 64,000 | 1.68 | 95 | 68% | 150 | 11 | - a | 0.76 |
HA38-g(EDC)-M2005-3.6% | 38,000 | 63,000 | 1.64 | 80 | 61% | 120 | 10 | - a | 0.72 |
HA38-g(T3P)-M2005-8.3% | 60,000 | 250,000 | 4.18 | 106 | 35% | 140 | 14 | 37 | 0.79 |
HA140 | 140,000 | 210,000 | 1.50 | 349 | 63% | 410 | 23 | 44 | 0.71 |
HA140 (T3P) b | 190,000 | 550,000 | 2.89 | 473 | 41% | 450 | 30 | 68 | 0.72 |
HA140-g(EDC)-M2005-3.9% | 140,000 | 190,000 | 1.39 | 294 | 77% | 390 | 22 | 39 | 0.62 |
HA140-g(T3P)-M2005-5.5% | 180,000 | 430,000 | 2.39 | 354 | 47% | 320 | 25 | 46 | 0.76 |
HA140-g(T3P)-M2005-8.3% | 200,000 | 540,000 | 2.76 | 355 | 21% | 290 | 26 | 48 | 0.77 |
HA1200 | 1,200,000 | 1,500,000 | 1.25 | 2990 | 65% | 1700 | 73 | 147 | - |
HA1200-g(EDC)-M2005-2.7% | 430,000 | 500,000 | 1.15 | 947 | 78% | 1300 | 46 | 102 | - |
HA1200-g(T3P)-M2005-3.7% | - | - | - | - | 0% | - | - | - | - |
HA1200-g(EDC)-M2005-4.5% | 540,000 | 710,000 | 1.32 | 1105 | 49% | 840 | 44 | 84 | - |
Sample | C (wt%) | Ttrans (°C) | G′ (Pa) (25°C) | G′ (Pa) (60°C) | |
---|---|---|---|---|---|
HA38-g(EDC)-M2005-3.6% | 11 | >60 °C | 0.1 Pa | 78.4 Pa | 784 |
HA38-g(T3P)-M2005-8.3% | 11 | <25 °C | 25 Pa | 230 Pa | 9.2 |
HA38-g(T3P)-M2005-8.3% | 3 | 33.7 °C | 0.2 Pa | 12.6 Pa | 63 |
HA140-g(EDC)-M2005-3.9% | 6 | 51.6 °C | 1 Pa | 296 Pa | 296 |
HA140-g(T3P)-M2005-5.5% | 6 | - | 176 Pa | 810 Pa | 4.6 |
HA140-g(T3P)-M2005-8.3% | 6 | - | 435 Pa | 3200 Pa | 7.4 |
HA1200-g(EDC)-M2005-2.7% | 1 | 43.7 °C | 0.5 Pa | 14.8 Pa | 30 |
HA1200-g(EDC)-M2005-4.5% | 1 | 41.5 °C | 0.026 Pa | 23 Pa | 885 |
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Madau, M.; Le Cerf, D.; Dulong, V.; Picton, L. Hyaluronic Acid Functionalization with Jeffamine® M2005: A Comparison of the Thermo-Responsiveness Properties of the Hydrogel Obtained through Two Different Synthesis Routes. Gels 2021, 7, 88. https://doi.org/10.3390/gels7030088
Madau M, Le Cerf D, Dulong V, Picton L. Hyaluronic Acid Functionalization with Jeffamine® M2005: A Comparison of the Thermo-Responsiveness Properties of the Hydrogel Obtained through Two Different Synthesis Routes. Gels. 2021; 7(3):88. https://doi.org/10.3390/gels7030088
Chicago/Turabian StyleMadau, Mathieu, Didier Le Cerf, Virginie Dulong, and Luc Picton. 2021. "Hyaluronic Acid Functionalization with Jeffamine® M2005: A Comparison of the Thermo-Responsiveness Properties of the Hydrogel Obtained through Two Different Synthesis Routes" Gels 7, no. 3: 88. https://doi.org/10.3390/gels7030088
APA StyleMadau, M., Le Cerf, D., Dulong, V., & Picton, L. (2021). Hyaluronic Acid Functionalization with Jeffamine® M2005: A Comparison of the Thermo-Responsiveness Properties of the Hydrogel Obtained through Two Different Synthesis Routes. Gels, 7(3), 88. https://doi.org/10.3390/gels7030088