Training-induced changes in bipedal stance. by Cristina Dolciotti (16317330)

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Relation between training-related changes in unipedal and bipedal stance. by Cristina Dolciotti (16317330)

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Time course of Path Length, LFS and Velocity during postural training. by Cristina Dolciotti (16317330)

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Time course of 95% Area, X and Y Amplitude Sway during postural training. by Cristina Dolciotti (16317330)

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Correlations between unipedal and bipedal stance parameters recorded at the beginning of the training and of the control session. by Cristina Dolciotti (16317330)

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Relation of the changes in Y Sway Amplitude and LFS induced by postural training with those in 95% Area. by Cristina Dolciotti (16317330)

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Between-group differences in 95% Area, Y Sway Amplitude and LFS during postural training. by Cristina Dolciotti (16317330)

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Consolidation of training-induced changes in unipedal stance: 95% Area, Y Sway Amplitude and LFS. by Cristina Dolciotti (16317330)

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Consolidation of training-induced changes in unipedal stance: Path Length, X Sway Amplitude and Velocity. by Cristina Dolciotti (16317330)

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Mean ± SD values of unipedal stance parameters evaluated at the different time points of the postural training session. by Cristina Dolciotti (16317330)

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Percent Decrease in FGM between Oldest (45-49 years) and Youngest (15-19 years) Cohorts of Women over the years in Egypt. by Shatha Elnakib (8901764)

Mean ± SD of the different parameters relative to bipedal stance on soft support with the eyes open recorded in the Chewing and Hand Grip groups. by Cristina Dolciotti (16317330)

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Flow diagram. by Cristina Dolciotti (16317330)

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Total task duration boxplots. Horizontal black dashed lines mark the target task duration (3 + 3 = 6) s and (1 + 1 = 2) s. by Jonas Kirsch (20642910)

Image 1_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.pdf by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Table 1_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.docx by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Image 5_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.pdf by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Image 4_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.pdf by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Image 2_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.pdf by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Image 3_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.pdf by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”