2018
U. Sharma, D. Concagh, L. Core, Y. Kuang, C. You, Q. Pham, G. Zugates, R. Busold, S. Webber, J. Merlo, R. Langer, G. M. Whitesides, and M. Palasis. 2018. “
The development of bioresorbable composite polymeric implants with high mechanical strength.” Nature Materials, 17, Pp. 96-103.
PDF Supplemental1297
U. Sharma, D. Concagh, L. Core, Y. Kuang, C. You, Q. Pham, G. Zugates, R. Busold, S. Webber, J. Merlo, R. Langer, G. M. Whitesides, and M. Palasis. 2018. “
The development of bioresorbable composite polymeric implants with high mechanical strength.” Nature Materials, 17, Pp. 96-103.
PDF Supplemental1297
U. Sharma, D. Concagh, L. Core, Y. Kuang, C. You, Q. Pham, G. Zugates, R. Busold, S. Webber, J. Merlo, R. Langer, G. M. Whitesides, and M. Palasis. 2018. “
The development of bioresorbable composite polymeric implants with high mechanical strength.” Nature Materials, 17, Pp. 96-103.
PDF Supplemental1297
U. Sharma, D. Concagh, L. Core, Y. Kuang, C. You, Q. Pham, G. Zugates, R. Busold, S. Webber, J. Merlo, R. Langer, G. M. Whitesides, and M. Palasis. 2018. “
The development of bioresorbable composite polymeric implants with high mechanical strength.” Nature Materials, 17, Pp. 96-103.
PDF Supplemental1297
U. Sharma, D. Concagh, L. Core, Y. Kuang, C. You, Q. Pham, G. Zugates, R. Busold, S. Webber, J. Merlo, R. Langer, G. M. Whitesides, and M. Palasis. 2018. “
The development of bioresorbable composite polymeric implants with high mechanical strength.” Nature Materials, 17, Pp. 96-103.
PDF Supplemental1297
U. Sharma, D. Concagh, L. Core, Y. Kuang, C. You, Q. Pham, G. Zugates, R. Busold, S. Webber, J. Merlo, R. Langer, G. M. Whitesides, and M. Palasis. 2018. “
The development of bioresorbable composite polymeric implants with high mechanical strength.” Nature Materials, 17, Pp. 96-103.
PDF Supplemental1297
U. Sharma, D. Concagh, L. Core, Y. Kuang, C. You, Q. Pham, G. Zugates, R. Busold, S. Webber, J. Merlo, R. Langer, G. M. Whitesides, and M. Palasis. 2018. “
The development of bioresorbable composite polymeric implants with high mechanical strength.” Nature Materials, 17, Pp. 96-103.
PDF Supplemental1297
U. Sharma, D. Concagh, L. Core, Y. Kuang, C. You, Q. Pham, G. Zugates, R. Busold, S. Webber, J. Merlo, R. Langer, G. M. Whitesides, and M. Palasis. 2018. “
The development of bioresorbable composite polymeric implants with high mechanical strength.” Nature Materials, 17, Pp. 96-103.
PDF Supplemental1297
U. Sharma, D. Concagh, L. Core, Y. Kuang, C. You, Q. Pham, G. Zugates, R. Busold, S. Webber, J. Merlo, R. Langer, G. M. Whitesides, and M. Palasis. 2018. “
The development of bioresorbable composite polymeric implants with high mechanical strength.” Nature Materials, 17, Pp. 96-103.
PDF Supplemental1297
M-N. Tsaloglou, A. Nemiroski, G. Camci-Unal, D. C. Christodouleas, L. P. Murray, J. T. Connelly, and G. M. Whitesides. 2018. “
Handheld Isothermal Amplification and Electrochemical Detection of DNA in Resource-Limited Settings.” Analytical Biochemistry, 543, Pp. 116-121.
PDF Supplemental1315
M-N. Tsaloglou, A. Nemiroski, G. Camci-Unal, D. C. Christodouleas, L. P. Murray, J. T. Connelly, and G. M. Whitesides. 2018. “
Handheld Isothermal Amplification and Electrochemical Detection of DNA in Resource-Limited Settings.” Analytical Biochemistry, 543, Pp. 116-121.
PDF Supplemental1315
M-N. Tsaloglou, A. Nemiroski, G. Camci-Unal, D. C. Christodouleas, L. P. Murray, J. T. Connelly, and G. M. Whitesides. 2018. “
Handheld Isothermal Amplification and Electrochemical Detection of DNA in Resource-Limited Settings.” Analytical Biochemistry, 543, Pp. 116-121.
PDF Supplemental1315
M-N. Tsaloglou, A. Nemiroski, G. Camci-Unal, D. C. Christodouleas, L. P. Murray, J. T. Connelly, and G. M. Whitesides. 2018. “
Handheld Isothermal Amplification and Electrochemical Detection of DNA in Resource-Limited Settings.” Analytical Biochemistry, 543, Pp. 116-121.
PDF Supplemental1315
M-N. Tsaloglou, A. Nemiroski, G. Camci-Unal, D. C. Christodouleas, L. P. Murray, J. T. Connelly, and G. M. Whitesides. 2018. “
Handheld Isothermal Amplification and Electrochemical Detection of DNA in Resource-Limited Settings.” Analytical Biochemistry, 543, Pp. 116-121.
PDF Supplemental1315
M-N. Tsaloglou, A. Nemiroski, G. Camci-Unal, D. C. Christodouleas, L. P. Murray, J. T. Connelly, and G. M. Whitesides. 2018. “
Handheld Isothermal Amplification and Electrochemical Detection of DNA in Resource-Limited Settings.” Analytical Biochemistry, 543, Pp. 116-121.
PDF Supplemental1315
M-N. Tsaloglou, A. Nemiroski, G. Camci-Unal, D. C. Christodouleas, L. P. Murray, J. T. Connelly, and G. M. Whitesides. 2018. “
Handheld Isothermal Amplification and Electrochemical Detection of DNA in Resource-Limited Settings.” Analytical Biochemistry, 543, Pp. 116-121.
PDF Supplemental1315
S. Ge, Y. Wang, N. Deshler, D.J. Preston, and G. M. Whitesides. 2018. “
High-Throughput Density Measurement Using Magnetic Levitation.” J. Amer. Chem. Soc., 140, 24, Pp. 7510-7518.
PDF Supplemental1309
S. Ge, Y. Wang, N. Deshler, D.J. Preston, and G. M. Whitesides. 2018. “
High-Throughput Density Measurement Using Magnetic Levitation.” J. Amer. Chem. Soc., 140, 24, Pp. 7510-7518.
PDF Supplemental1309
S. Ge, Y. Wang, N. Deshler, D.J. Preston, and G. M. Whitesides. 2018. “
High-Throughput Density Measurement Using Magnetic Levitation.” J. Amer. Chem. Soc., 140, 24, Pp. 7510-7518.
PDF Supplemental1309
S. Ge, Y. Wang, N. Deshler, D.J. Preston, and G. M. Whitesides. 2018. “
High-Throughput Density Measurement Using Magnetic Levitation.” J. Amer. Chem. Soc., 140, 24, Pp. 7510-7518.
PDF Supplemental1309