Table_5_Overpressure Exposure From .50-Caliber Rifle Training Is Associated With Increased Amyloid Beta Peptides in Serum.DOCX by Bharani Thangavelu (7224311)

“…Repeated OP may increase risk of neurological disease or psychological disorder diagnoses. A means to detect early phase effects that may be relevant to brain trauma remain elusive. …”

Table_1_Overpressure Exposure From .50-Caliber Rifle Training Is Associated With Increased Amyloid Beta Peptides in Serum.XLSX by Bharani Thangavelu (7224311)

“…Repeated OP may increase risk of neurological disease or psychological disorder diagnoses. A means to detect early phase effects that may be relevant to brain trauma remain elusive. …”

Table_4_Overpressure Exposure From .50-Caliber Rifle Training Is Associated With Increased Amyloid Beta Peptides in Serum.XLSX by Bharani Thangavelu (7224311)

“…Repeated OP may increase risk of neurological disease or psychological disorder diagnoses. A means to detect early phase effects that may be relevant to brain trauma remain elusive. …”

Image_1_Overpressure Exposure From .50-Caliber Rifle Training Is Associated With Increased Amyloid Beta Peptides in Serum.JPEG by Bharani Thangavelu (7224311)

“…Repeated OP may increase risk of neurological disease or psychological disorder diagnoses. A means to detect early phase effects that may be relevant to brain trauma remain elusive. …”

Table_2_Overpressure Exposure From .50-Caliber Rifle Training Is Associated With Increased Amyloid Beta Peptides in Serum.XLSX by Bharani Thangavelu (7224311)

“…Repeated OP may increase risk of neurological disease or psychological disorder diagnoses. A means to detect early phase effects that may be relevant to brain trauma remain elusive. …”

Table_3_Overpressure Exposure From .50-Caliber Rifle Training Is Associated With Increased Amyloid Beta Peptides in Serum.DOCX by Bharani Thangavelu (7224311)

“…Repeated OP may increase risk of neurological disease or psychological disorder diagnoses. A means to detect early phase effects that may be relevant to brain trauma remain elusive. …”

Table_1_Cyanophage Propagation in the Freshwater Cyanobacterium Phormidium Is Constrained by Phosphorus Limitation and Enhanced by Elevated pCO2.docx by Kai Cheng (539804)

SIRT1 is involved in the attenuation of H₂O₂-induced senescence by resveratrol. by Yasuo Ido (172159)

Caspase-3 western blot. by Marc-Alexander Oestreich (13961375)

Contains all data used in the study. by Dalia Zaafar (6693017)

Fig 4 - by Dalia Zaafar (6693017)

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”