Well-watered (WW) <i>I</i>. <i>pes-caprae</i> plants after drought stress (DS) for 13 days (T1, T2 and T3) and re-watering (RW) following DS for 14 days (only shows T2 plants after... by Jie He (132999)

Influence of Interfacial Gas Enrichment on Controlled Coalescence of Oil Droplets in Water in Microfluidics by Jianlong Wang (438075)

“…When the amount of dissolved gases (oxygen) in oil decreases (from 7.89 to 4.59 mg/L), the average drainage time of coalescence significantly increases (from 19 to 50 ms). …”

Genetic analysis of CRISPR-Cas9 mediated re-sensitization of <i>K. michiganensis</i> (KM). by Thaysa Leite Tagliaferri (6371453)

“…A significant reduction was observed in the re-sensitized cells KM^S likely due to a decrease in <i><i>bla</i></i>_KPC gene copy number, as seen in 3C. 3E. …”

Supramolecular DNA Photonic Hydrogels for On-Demand Control of Coloration with High Spatial and Temporal Resolution by Yixiao Dong (2174902)

“…Dynamically generating color patterns requires control of nanoparticle organization within a polymer network on-demand, which is challenging. We solve this problem by creating a DNA hydrogel system that shows a 50 000-fold decrease in modulus upon heating by ∼10 °C. …”

Supramolecular DNA Photonic Hydrogels for On-Demand Control of Coloration with High Spatial and Temporal Resolution by Yixiao Dong (2174902)

“…Dynamically generating color patterns requires control of nanoparticle organization within a polymer network on-demand, which is challenging. We solve this problem by creating a DNA hydrogel system that shows a 50 000-fold decrease in modulus upon heating by ∼10 °C. …”

Supramolecular DNA Photonic Hydrogels for On-Demand Control of Coloration with High Spatial and Temporal Resolution by Yixiao Dong (2174902)

“…Dynamically generating color patterns requires control of nanoparticle organization within a polymer network on-demand, which is challenging. We solve this problem by creating a DNA hydrogel system that shows a 50 000-fold decrease in modulus upon heating by ∼10 °C. …”

Supramolecular DNA Photonic Hydrogels for On-Demand Control of Coloration with High Spatial and Temporal Resolution by Yixiao Dong (2174902)

“…Dynamically generating color patterns requires control of nanoparticle organization within a polymer network on-demand, which is challenging. We solve this problem by creating a DNA hydrogel system that shows a 50 000-fold decrease in modulus upon heating by ∼10 °C. …”

Supramolecular DNA Photonic Hydrogels for On-Demand Control of Coloration with High Spatial and Temporal Resolution by Yixiao Dong (2174902)

“…Dynamically generating color patterns requires control of nanoparticle organization within a polymer network on-demand, which is challenging. We solve this problem by creating a DNA hydrogel system that shows a 50 000-fold decrease in modulus upon heating by ∼10 °C. …”

Supramolecular DNA Photonic Hydrogels for On-Demand Control of Coloration with High Spatial and Temporal Resolution by Yixiao Dong (2174902)

“…Dynamically generating color patterns requires control of nanoparticle organization within a polymer network on-demand, which is challenging. We solve this problem by creating a DNA hydrogel system that shows a 50 000-fold decrease in modulus upon heating by ∼10 °C. …”

Table_1_Lactic Acid Fermentation to Re-cycle Apple By-Products for Wheat Bread Fortification.pdf by Vincenzo Cantatore (7824908)

Image_1_Lactic Acid Fermentation to Re-cycle Apple By-Products for Wheat Bread Fortification.pdf by Vincenzo Cantatore (7824908)

Image_2_Lactic Acid Fermentation to Re-cycle Apple By-Products for Wheat Bread Fortification.pdf by Vincenzo Cantatore (7824908)

Table_3_Lactic Acid Fermentation to Re-cycle Apple By-Products for Wheat Bread Fortification.pdf by Vincenzo Cantatore (7824908)

Table_2_Lactic Acid Fermentation to Re-cycle Apple By-Products for Wheat Bread Fortification.pdf by Vincenzo Cantatore (7824908)

Image_3_Lactic Acid Fermentation to Re-cycle Apple By-Products for Wheat Bread Fortification.pdf by Vincenzo Cantatore (7824908)

Data deposition RE: Awinda et al. 2021. Am J Physiol—Heart Circ Physiol. by Bertrand Tanner (19826652)

“…<i>Am J Physiol—Heart Circ Physiol</i>. 320:H881-H890. doi: 10.1152/ajpheart.00345.2020.</p><p dir="ltr">From PubMed, with associated links:</p><ul><li>PMID: 33337957</li><li>PMCID: <a href="http://www.ncbi.nlm.nih.gov/pmc/articles/pmc8082789/" rel="noopener" target="_blank">PMC8082789</a></li><li>DOI: <a href="https://doi.org/10.1152/ajpheart.00345.2020" rel="noopener" target="_blank">10.1152/ajpheart.00345.2020</a></li></ul><p><br></p><h3>Data Files:</h3><ul><li>Isometric force data, with 3-parameter Hill Fits. …”

Test and re-test Ct values vary over time but remain highly correlated, except for January. by Jennifer K. Frediani (8366139)

If a bird calls, will we detect it? Factors that can influence the detectability of calls on automated recording units in field conditions by Abby Thomas (9288104)

Are we restoring functional fens? – The outcomes of restoration projects in fens re-analysed with plant functional traits by Agata Klimkowska (6631481)

In house finch Harderian glands, we identified ˜90% fewer differentially expressed genes when comparing non-infected controls to MG-infected birds from populations that are more to... by Amberleigh E. Henschen (3257235)