Tetramethyl 2,2'-[1,4-phenylenebis[imino(1-acetyl-2-oxoethane-1,2-diyl)azo]]bisterephthalate

BIOWIN (v4.10) Program Results:

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SMILES : CC(=O)C(N=Nc1c(ccc(c1)C(=O)OC)C(=O)OC)C(=O)Nc2ccc(cc2)NC(=O)C(N=Nc3c(

ccc(c3)C(=O)OC)C(=O)OC)C(=O)C

MOL FOR: C34 H32 N6 O12

MOL WT : 716.67

--------------------------- BIOWIN v4.10 Results ----------------------------

Biowin1 (Linear Model Prediction)   : Biodegrades Fast

Biowin2 (Non-Linear Model Prediction): Does Not Biodegrade Fast

Biowin3 (Ultimate Biodegradation Timeframe): Recalcitrant

Biowin4 (Primary Biodegradation Timeframe): Days

Biowin5 (MITI Linear Model Prediction)   : Does Not Biodegrade Fast

Biowin6 (MITI Non-Linear Model Prediction): Does Not Biodegrade Fast

Biowin7 (Anaerobic Model Prediction): Does Not Biodegrade Fast

Ready Biodegradability Prediction: NO

A probability greater than or equal to 0.5 indicates --> biodegrades fast

A probability less than 0.5 indicates --> does not biodegrade fast

Result classification: 5.00 -> hours 4.00 -> days 3.00 -> weeks

(primary & ultimate) 2.00 -> months 1.00 -> longer

A probability greater than or equal to 0.5 indicates --> readily degradable

A probability less than 0.5 indicates --> not readily degradable

At any of the time points mentioned in the TG-318, the influence of Ca is critical. Regardless of pH, the pigment is unstable in 10 mM Ca, representing high water hardness.

After 6h, the samples showed high dispersion stability in 0 mM Ca and on a lower level intermediate stability in 1 mM and 10 mM Ca.

After 24 hours the stability in 0 mM Ca became intermediate. For the samples in 1 and 10 mM Ca the stability was low.

To rationalize the observed dispersion stability, we finally checked the particle size distribution directly in the environmental medium. We applied the NanoDefine method of Analytical Ultracentrifugation. The centrifugation parameters are given in the methods section.

As required by TG318, paragraph 31, the tested nanomaterial was pre-wetted in ultrapure water and left in the form of wet-paste for 24 h. The TG318 requires this step “to insure the proper interaction of nanomaterial surface with ultrapure water.” We visually observed incomplete wetting, and so any ensuing measurement would have been incorrect. In accord with the NanoGenoTox dispersion protocol, a drop of ethanol was added, successfully transferred the powder into a paste, which was then further diluted as specified in the TG318

The observed size distributions confirm the moderate agglomeration at 1 mM Ca, pH7, with NOM. If the particles would have been significantly dissolved, no size distribution would be observable at all by this method, which relies on the detection of the movement of particles during centrifugal separation.

Additionally, the centrifugation methods include a determination of the remaining absorption after centrifugation, fully consistent with the conventional determination of the dissolved fraction after centrifugation as recommended by the TG-318. The remaining absorption was measured at ca. 0.02. This is a fraction of 1% of the initial absorption, but actually is close to the LOD of the built-in UV/Vis detector. Considering the LOD, between 0% and 2% of the sample may have been dissolved.

All evidence combined, the results after centrifugation confirm that at least 98% of the observed dispersion stability has to be attributed to the particles, not to dissolution.