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71. Electric Field Assisted Assembly of Perpendicular Oriented Nanorod Superlattices

Author

Ryan, Kevin M., Mastroianni, Alex, Stancil, Kimani A., Liu, Haitao, and Alivisatos, Paul A.

Subjects
Materials science
Abstract

We observe the assembly of CdS nanorod superlattices by the combination of a DC electric field and solvent evaporation. In each electric field (1 V/um) assisted assembly, CdS nanorods (5 x 30 nm) suspended initially in toluene were observed to align perpendicularly to the substrate. Azimuthal alignment along the nanorod crystal faces and the presence of stacking faults indicate that both 2D and 3D assemblies were formed by a process of controlled super crystal growth.

Published
2006

73. GREENLION Project: Advanced Manufacturing Processes for Low Cost Greener Li-Ion Batteries

Author

de Meatza, Iratxe, Miguel, Oscar, Cendoya, Iosu, Kim, Guk-Tae, Löffler, Nicholas, Laszczynski, Nina, Passerini, Stefano, Schweizer, Peter M., Castiglione, Franca, Mele, Andrea, Appetecchi, Giovanni Battista, Moreno, Margherita, Brandon, Michael, Kennedy, Tadhg, Mullane, Emma, Ryan, Kevin M., Cantero, Igor, Olive, Maxime, Meyer, Gereon, Series editor, Briec, Emma, editor, and Müller, Beate, editor

Published
2015
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74. Mannose impairs tumour growth and enhances chemotherapy

Author

Gonzalez, Pablo Sierra, O’Prey, James, Cardaci, Simone, Barthet, Valentin J. A., Sakamaki, Jun-ichi, Beaumatin, Florian, Roseweir, Antonia, Gay, David M., Mackay, Gillian, Malviya, Gaurav, Kania, Elżbieta, Ritchie, Shona, Baudot, Alice D., Zunino, Barbara, Mrowinska, Agata, Nixon, Colin, Ennis, Darren, Hoyle, Aoisha, Millan, David, McNeish, Iain A., Sansom, Owen J., Edwards, Joanne, and Ryan, Kevin M.

Published
2018
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75. Molecular mechanisms of cell death: recommendations of the Nomenclature Committee on Cell Death 2018

Author

Galluzzi, Lorenzo, Vitale, Ilio, Aaronson, Stuart A., Abrams, John M., Adam, Dieter, Agostinis, Patrizia, Alnemri, Emad S., Altucci, Lucia, Amelio, Ivano, Andrews, David W., Annicchiarico-Petruzzelli, Margherita, Antonov, Alexey V., Arama, Eli, Baehrecke, Eric H., Barlev, Nickolai A., Bazan, Nicolas G., Bernassola, Francesca, Bertrand, Mathieu J. M., Bianchi, Katiuscia, Blagosklonny, Mikhail V., Blomgren, Klas, Borner, Christoph, Boya, Patricia, Brenner, Catherine, Campanella, Michelangelo, Candi, Eleonora, Carmona-Gutierrez, Didac, Cecconi, Francesco, Chan, Francis K.-M., Chandel, Navdeep S., Cheng, Emily H., Chipuk, Jerry E., Cidlowski, John A., Ciechanover, Aaron, Cohen, Gerald M., Conrad, Marcus, Cubillos-Ruiz, Juan R., Czabotar, Peter E., D’Angiolella, Vincenzo, Dawson, Ted M., Dawson, Valina L., De Laurenzi, Vincenzo, De Maria, Ruggero, Debatin, Klaus-Michael, DeBerardinis, Ralph J., Deshmukh, Mohanish, Di Daniele, Nicola, Di Virgilio, Francesco, Dixit, Vishva M., Dixon, Scott J., Duckett, Colin S., Dynlacht, Brian D., El-Deiry, Wafik S., Elrod, John W., Fimia, Gian Maria, Fulda, Simone, García-Sáez, Ana J., Garg, Abhishek D., Garrido, Carmen, Gavathiotis, Evripidis, Golstein, Pierre, Gottlieb, Eyal, Green, Douglas R., Greene, Lloyd A., Gronemeyer, Hinrich, Gross, Atan, Hajnoczky, Gyorgy, Hardwick, J. Marie, Harris, Isaac S., Hengartner, Michael O., Hetz, Claudio, Ichijo, Hidenori, Jäättelä, Marja, Joseph, Bertrand, Jost, Philipp J., Juin, Philippe P., Kaiser, William J., Karin, Michael, Kaufmann, Thomas, Kepp, Oliver, Kimchi, Adi, Kitsis, Richard N., Klionsky, Daniel J., Knight, Richard A., Kumar, Sharad, Lee, Sam W., Lemasters, John J., Levine, Beth, Linkermann, Andreas, Lipton, Stuart A., Lockshin, Richard A., López-Otín, Carlos, Lowe, Scott W., Luedde, Tom, Lugli, Enrico, MacFarlane, Marion, Madeo, Frank, Malewicz, Michal, Malorni, Walter, Manic, Gwenola, Marine, Jean-Christophe, Martin, Seamus J., Martinou, Jean-Claude, Medema, Jan Paul, Mehlen, Patrick, Meier, Pascal, Melino, Sonia, Miao, Edward A., Molkentin, Jeffery D., Moll, Ute M., Muñoz-Pinedo, Cristina, Nagata, Shigekazu, Nuñez, Gabriel, Oberst, Andrew, Oren, Moshe, Overholtzer, Michael, Pagano, Michele, Panaretakis, Theocharis, Pasparakis, Manolis, Penninger, Josef M., Pereira, David M., Pervaiz, Shazib, Peter, Marcus E., Piacentini, Mauro, Pinton, Paolo, Prehn, Jochen H.M., Puthalakath, Hamsa, Rabinovich, Gabriel A., Rehm, Markus, Rizzuto, Rosario, Rodrigues, Cecilia M.P., Rubinsztein, David C., Rudel, Thomas, Ryan, Kevin M., Sayan, Emre, Scorrano, Luca, Shao, Feng, Shi, Yufang, Silke, John, Simon, Hans-Uwe, Sistigu, Antonella, Stockwell, Brent R., Strasser, Andreas, Szabadkai, Gyorgy, Tait, Stephen W.G., Tang, Daolin, Tavernarakis, Nektarios, Thorburn, Andrew, Tsujimoto, Yoshihide, Turk, Boris, Vanden Berghe, Tom, Vandenabeele, Peter, Vander Heiden, Matthew G., Villunger, Andreas, Virgin, Herbert W., Vousden, Karen H., Vucic, Domagoj, Wagner, Erwin F., Walczak, Henning, Wallach, David, Wang, Ying, Wells, James A., Wood, Will, Yuan, Junying, Zakeri, Zahra, Zhivotovsky, Boris, Zitvogel, Laurence, Melino, Gerry, and Kroemer, Guido

Published
2018
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78. Supplementary Table S1 from Senescence Sensitivity of Breast Cancer Cells Is Defined by Positive Feedback Loop between CIP2A and E2F1

Author

Laine, Anni, primary, Sihto, Harri, primary, Come, Christophe, primary, Rosenfeldt, Mathias T., primary, Zwolinska, Aleksandra, primary, Niemelä, Minna, primary, Khanna, Anchit, primary, Chan, Edward K., primary, Kähäri, Veli-Matti, primary, Kellokumpu-Lehtinen, Pirkko-Liisa, primary, Sansom, Owen J., primary, Evan, Gerard I., primary, Junttila, Melissa R., primary, Ryan, Kevin M., primary, Marine, Jean-Christophe, primary, Joensuu, Heikki, primary, and Westermarck, Jukka, primary

Published
2023
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79. Supplementary Methods from Senescence Sensitivity of Breast Cancer Cells Is Defined by Positive Feedback Loop between CIP2A and E2F1

Author

Laine, Anni, primary, Sihto, Harri, primary, Come, Christophe, primary, Rosenfeldt, Mathias T., primary, Zwolinska, Aleksandra, primary, Niemelä, Minna, primary, Khanna, Anchit, primary, Chan, Edward K., primary, Kähäri, Veli-Matti, primary, Kellokumpu-Lehtinen, Pirkko-Liisa, primary, Sansom, Owen J., primary, Evan, Gerard I., primary, Junttila, Melissa R., primary, Ryan, Kevin M., primary, Marine, Jean-Christophe, primary, Joensuu, Heikki, primary, and Westermarck, Jukka, primary

Published
2023
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80. Data from Senescence Sensitivity of Breast Cancer Cells Is Defined by Positive Feedback Loop between CIP2A and E2F1

Author

Laine, Anni, primary, Sihto, Harri, primary, Come, Christophe, primary, Rosenfeldt, Mathias T., primary, Zwolinska, Aleksandra, primary, Niemelä, Minna, primary, Khanna, Anchit, primary, Chan, Edward K., primary, Kähäri, Veli-Matti, primary, Kellokumpu-Lehtinen, Pirkko-Liisa, primary, Sansom, Owen J., primary, Evan, Gerard I., primary, Junttila, Melissa R., primary, Ryan, Kevin M., primary, Marine, Jean-Christophe, primary, Joensuu, Heikki, primary, and Westermarck, Jukka, primary

Published
2023
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81. Supplementary Figure 3 from Senescence Sensitivity of Breast Cancer Cells Is Defined by Positive Feedback Loop between CIP2A and E2F1

Author

Laine, Anni, primary, Sihto, Harri, primary, Come, Christophe, primary, Rosenfeldt, Mathias T., primary, Zwolinska, Aleksandra, primary, Niemelä, Minna, primary, Khanna, Anchit, primary, Chan, Edward K., primary, Kähäri, Veli-Matti, primary, Kellokumpu-Lehtinen, Pirkko-Liisa, primary, Sansom, Owen J., primary, Evan, Gerard I., primary, Junttila, Melissa R., primary, Ryan, Kevin M., primary, Marine, Jean-Christophe, primary, Joensuu, Heikki, primary, and Westermarck, Jukka, primary

Published
2023
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82. Supplementary Figure 4 from Senescence Sensitivity of Breast Cancer Cells Is Defined by Positive Feedback Loop between CIP2A and E2F1

Author

Laine, Anni, primary, Sihto, Harri, primary, Come, Christophe, primary, Rosenfeldt, Mathias T., primary, Zwolinska, Aleksandra, primary, Niemelä, Minna, primary, Khanna, Anchit, primary, Chan, Edward K., primary, Kähäri, Veli-Matti, primary, Kellokumpu-Lehtinen, Pirkko-Liisa, primary, Sansom, Owen J., primary, Evan, Gerard I., primary, Junttila, Melissa R., primary, Ryan, Kevin M., primary, Marine, Jean-Christophe, primary, Joensuu, Heikki, primary, and Westermarck, Jukka, primary

Published
2023
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83. Supplementary Figure 2 from Senescence Sensitivity of Breast Cancer Cells Is Defined by Positive Feedback Loop between CIP2A and E2F1

Author

Laine, Anni, primary, Sihto, Harri, primary, Come, Christophe, primary, Rosenfeldt, Mathias T., primary, Zwolinska, Aleksandra, primary, Niemelä, Minna, primary, Khanna, Anchit, primary, Chan, Edward K., primary, Kähäri, Veli-Matti, primary, Kellokumpu-Lehtinen, Pirkko-Liisa, primary, Sansom, Owen J., primary, Evan, Gerard I., primary, Junttila, Melissa R., primary, Ryan, Kevin M., primary, Marine, Jean-Christophe, primary, Joensuu, Heikki, primary, and Westermarck, Jukka, primary

Published
2023
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84. Supplementary Figure 1 from Senescence Sensitivity of Breast Cancer Cells Is Defined by Positive Feedback Loop between CIP2A and E2F1

Author

Laine, Anni, primary, Sihto, Harri, primary, Come, Christophe, primary, Rosenfeldt, Mathias T., primary, Zwolinska, Aleksandra, primary, Niemelä, Minna, primary, Khanna, Anchit, primary, Chan, Edward K., primary, Kähäri, Veli-Matti, primary, Kellokumpu-Lehtinen, Pirkko-Liisa, primary, Sansom, Owen J., primary, Evan, Gerard I., primary, Junttila, Melissa R., primary, Ryan, Kevin M., primary, Marine, Jean-Christophe, primary, Joensuu, Heikki, primary, and Westermarck, Jukka, primary

Published
2023
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85. Supplementary Figure 5 from Senescence Sensitivity of Breast Cancer Cells Is Defined by Positive Feedback Loop between CIP2A and E2F1

Author

Laine, Anni, primary, Sihto, Harri, primary, Come, Christophe, primary, Rosenfeldt, Mathias T., primary, Zwolinska, Aleksandra, primary, Niemelä, Minna, primary, Khanna, Anchit, primary, Chan, Edward K., primary, Kähäri, Veli-Matti, primary, Kellokumpu-Lehtinen, Pirkko-Liisa, primary, Sansom, Owen J., primary, Evan, Gerard I., primary, Junttila, Melissa R., primary, Ryan, Kevin M., primary, Marine, Jean-Christophe, primary, Joensuu, Heikki, primary, and Westermarck, Jukka, primary

Published
2023
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86. 2023 roadmap for potassium-ion batteries

Author

Xu, Yang, primary, Titirici, Magda, additional, Chen, Jingwei, additional, Cora, Furio, additional, Cullen, Patrick L, additional, Edge, Jacqueline Sophie, additional, Fan, Kun, additional, Fan, Ling, additional, Feng, Jingyu, additional, Hosaka, Tomooki, additional, Hu, Junyang, additional, Huang, Weiwei, additional, Hyde, Timothy I, additional, Imtiaz, Sumair, additional, Kang, Feiyu, additional, Kennedy, Tadhg, additional, Kim, Eun Jeong, additional, Komaba, Shinichi, additional, Lander, Laura, additional, Le Pham, Phuong Nam, additional, Liu, Pengcheng, additional, Lu, Bingan, additional, Meng, Fanlu, additional, Mitlin, David, additional, Monconduit, Laure, additional, Palgrave, Robert G, additional, Qin, Lei, additional, Ryan, Kevin M, additional, Sankar, Gopinathan, additional, Scanlon, David O, additional, Shi, Tianyi, additional, Stievano, Lorenzo, additional, Tinker, Henry R, additional, Wang, Chengliang, additional, Wang, Hang, additional, Wang, Huanlei, additional, Wu, Yiying, additional, Zhai, Dengyun, additional, Zhang, Qichun, additional, Zhou, Min, additional, and Zou, Jincheng, additional

Published
2023
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88. Engineering polymorphs in colloidal metal dichalcogenides: Precursor mediated phase control, molecular insights into crystallisation kinetics and promising electrochemical activity disulphides

Author

Kapuria, Nilotpal, Patil, Niraj Nitish, Sankaran, Abinaya, Laffir, Fathima, Geaney, Hugh, Magner, Edmond, Scanlon, Micheál D., Ryan, Kevin M., and Singh, Shalini

Abstract

Controlling the crystal phase in layered transition metal dichalcogenides (TMD) is critical for their diverse, flexible applications. However, due to the thermodynamic stability of 2H over other polymorphs, fine synthesis control over polymorphism in TMD is challenging, restricting the entire range of characteristics associated with other polymorphs. Herein, we present a solution-based crystal phase engineering approach for layered transition metal disulphide nanosheets by modulating the reactivity of the molecular precursors. By tuning precursor-ligand chemistry, 2H, 1T' and polytypic MoS2 and WS2 are synthesised. The flexibility to selectively modify the reactivity of S and metal precursors allowed control over the proportion of specific phases in synthesised nanosheets. The formation of 1T’ is facilitated by the highly reactive metal and S source, whereas less reactive sources lead to the formation of thermodynamically stable 2H. The electrocatalytic properties of the synthesised TMDs were examined for the oxygen reduction reaction. The polytypic MoS2 comprising of mix of 2H-1T’ displayed a most positive potential of 0.82 V (vs RHE). The comprehensive mechanistic interpretation of the chemical transformations provided in this study will be instrumental in designing scalable solution-based pathways for phase engineering in layered transition metal dichalcogenides. Furthermore, this synthesis approach has the potential to be extended to various TMDs compositions, enabling exquisite control over polymorphism in TMDs.

Published
2023

89. Regulation of myeloid differentiation by c-myc and its antagonists

Author

Ryan, Kevin M.

Subjects
610, Cancer, Tumours, Leukaemias
Abstract

The enforced expression of c-myc is able to block the differentiation of myeloid cells. More recently, it has been shown that the correct functioning of c-Myc is not only dependent on the abundance of its dimerization partner, Max, but also on the levels of two other proteins which complex with Max, Mad and Mxil. Analysis was made of the levels of their mRNAs, relative to those of c-myc mRNA, during the induced differentiation of myeloid leukaemic HL60 and U937 cells. This revealed that, the abundance of mxil and max mRNA were largely maintained at levels comparable to those observed in untreated cells, but the levels of max mRNA were found to be markedly reduced at the very late stages of differentiation in HL60 cells induced by TPA. In contrast, the levels of mad mRNA were rapidly increased following differentiation induction by TPA. However, it was found that differentiation to granulocytes or monocytes/macrophages could also be achieved without a concomitant increase in the abundance of mad mRNA. To further investigate the role of Mad during the differentiation of myeloid cells E-box DNA-binding was analysed. While Myc:Max complexes were lost rapidly following differentiation induction, no Mad-containing complexes were detected during differentiation to monocytes/macrophages, and those which were detected during granulocytic differentiation were only evident at the very late stages. The subsequent analysis of these Mad-containing complexes revealed that they were also unlikely to be able to antagonise c-Myc function as they did not contain Max. In light of these findings, it was decided not to study these factors further, but to focus on the role played by c-myc in the control of differentiation per se. Although the mechanism by which c-Myc affects this process remains unknown, it is considered that it might result indirectly as an outcome of the continued cell-cycle progression invoked by c-Myc in cells which must growth arrest in order to differentiate. However, it is equally possible that a differentiation blockage occurs through a mechanism independent of c-Myc's involvement in cell-cycle progression. An analysis was therefore made of a differentiation-defective variant of the U937 cell line which, following treatment with TPA, does not differentiate, but rapidly ceases to proliferate, arresting at the G0/G1 phase of the cell cycle. Analysis during growth arrest revealed that, although this line down-regulated the expression of the Myc target gene, ornithine decarboxylase, it continued to express high levels of c-Myc protein, which retained the ability to bind its target sequence, CACGTG. Consequently, it was hypothesised that the continued expression of c-Myc in these cells may be responsible for their inability to differentiate in response to treatment with TPA. In agreement with this, down-regulation of the levels of c-Myc by antisense oligonucleotides directed against c-myc mRNA resulted in these cells acquiring characteristics of a terminally differentiated cell. As Mad, Max and Mxil have all been shown to antagonize c-Myc function, an analysis was also made for mutations in the genes for these proteins. Both HL60 and HeLa cells were found to be hemizygous for max. Sequencing of the remaining allele in these cell lines revealed three nucleotide changes, when compared to the published sequence. However, these changes did not result in any amino acid change. The relevance of all these findings to the regulation of myeloid differentiation, and in particular to the involvement of c-Myc in these processes, is discussed.

Published
1996

90. Resolving Multielement Semiconductor Nanocrystals at the Atomic Level: Complete Deciphering of Domains and Order in Complex CuαZnβSnγSeδ(CZTSe) Tetrapods

Author

Ren, Huan, Sun, Yuanwei, Hoffmann, Frank, Vandichel, Matthias, Adegoke, Temilade E., Liu, Ning, McCarthy, Conor, Gao, Peng, and Ryan, Kevin M.

Abstract

Semiconductor nanocrystals (NCs) with high elemental and structural complexity can be engineered to tailor for electronic, photovoltaic, thermoelectric, and battery applications etc. However, this greater complexity causes ambiguity in the atomic structure understanding. This in turn hinders the mechanistic studies of nucleation and growth, the theoretical calculations of functional properties, and the capability to extend functional design across complementary semiconductor nanocrystals. Herein, we successfully deciphered the atomic arrangements of 4 different nanocrystal domains in CuαZnβSnγSeδ(CZTSe) nanocrystals using crucial zone axis analysis on multiple crystals in different orientations. The results show that the essence of crystallographic progression from binary to multielemental semiconductors is actually the change of theoretical periodicity. This transition is caused by decreased symmetry in the crystal instead of previously assumed crystal deformation. We further reveal that these highly complex crystalline entities have highly ordered element arrangements as opposed to the previous understanding that their elemental orderings are random.

Published
2024
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91. Binder-free germanium nanoparticle decorated multi-wall carbon nanotube anodes prepared viatwo-step electrophoretic deposition for high capacity Li-ion batteriesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3nh00501a

Author

Pham, Xuan-Manh, Abdul Ahad, Syed, Patil, Niraj Nitish, Geaney, Hugh, Singh, Shalini, and Ryan, Kevin M.

Abstract

Germanium (Ge) has a high theoretical specific capacity (1384 mA h g−1) and fast lithium-ion diffusivity, which makes it an attractive anode material for lithium-ion batteries (LIBs). However, large volume changes during lithiation can lead to poor capacity retention and rate capability. Here, electrophoretic deposition (EPD) is used as a facile strategy to prepare Ge nanoparticle carbon-nanotube (Ge/CNT) electrodes. The Ge and CNT mass ratio in the Ge/CNT nanocomposites can be controlled by varying the deposition time, voltage, and concentration of the Ge NP dispersion in the EPD process. The optimized Ge/CNT nanocomposite exhibited long-term cyclic stability, with a capacity of 819 mA h g−1after 1000 cycles at C/5 and a reversible capacity of 686 mA h g−1after 350 cycles (with a minuscule capacity loss of 0.07% per cycle) at 1C. The Ge/CNT nanocomposite electrodes delivered dramatically improved cycling stability compared to control Ge nanoparticles. This can be attributed to the synergistic effects of implanting Ge into a 3D interconnected CNT network which acts as a buffer layer to accommodate the volume expansion of Ge NPs during lithiation/delithiation, limiting cracking and/or crumbling, to retain the integrity of the Ge/CNT nanocomposite electrodes.

Published
2024
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93. Supplementary Table 3 from MDH1 and MPP7 Regulate Autophagy in Pancreatic Ductal Adenocarcinoma

Author

New, Maria, primary, Van Acker, Tim, primary, Sakamaki, Jun-Ichi, primary, Jiang, Ming, primary, Saunders, Rebecca E., primary, Long, Jaclyn, primary, Wang, Victoria M.-Y., primary, Behrens, Axel, primary, Cerveira, Joana, primary, Sudhakar, Padhmanand, primary, Korcsmaros, Tamas, primary, Jefferies, Harold B.J., primary, Ryan, Kevin M., primary, Howell, Michael, primary, and Tooze, Sharon A., primary

Published
2023
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94. Supplementary Table 2 from MDH1 and MPP7 Regulate Autophagy in Pancreatic Ductal Adenocarcinoma

Author

New, Maria, primary, Van Acker, Tim, primary, Sakamaki, Jun-Ichi, primary, Jiang, Ming, primary, Saunders, Rebecca E., primary, Long, Jaclyn, primary, Wang, Victoria M.-Y., primary, Behrens, Axel, primary, Cerveira, Joana, primary, Sudhakar, Padhmanand, primary, Korcsmaros, Tamas, primary, Jefferies, Harold B.J., primary, Ryan, Kevin M., primary, Howell, Michael, primary, and Tooze, Sharon A., primary

Published
2023
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95. Supplementary Figure 2 from MDH1 and MPP7 Regulate Autophagy in Pancreatic Ductal Adenocarcinoma

Author

New, Maria, primary, Van Acker, Tim, primary, Sakamaki, Jun-Ichi, primary, Jiang, Ming, primary, Saunders, Rebecca E., primary, Long, Jaclyn, primary, Wang, Victoria M.-Y., primary, Behrens, Axel, primary, Cerveira, Joana, primary, Sudhakar, Padhmanand, primary, Korcsmaros, Tamas, primary, Jefferies, Harold B.J., primary, Ryan, Kevin M., primary, Howell, Michael, primary, and Tooze, Sharon A., primary

Published
2023
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96. Supplementary Figure 3 from MDH1 and MPP7 Regulate Autophagy in Pancreatic Ductal Adenocarcinoma

Author

New, Maria, primary, Van Acker, Tim, primary, Sakamaki, Jun-Ichi, primary, Jiang, Ming, primary, Saunders, Rebecca E., primary, Long, Jaclyn, primary, Wang, Victoria M.-Y., primary, Behrens, Axel, primary, Cerveira, Joana, primary, Sudhakar, Padhmanand, primary, Korcsmaros, Tamas, primary, Jefferies, Harold B.J., primary, Ryan, Kevin M., primary, Howell, Michael, primary, and Tooze, Sharon A., primary

Published
2023
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97. Supplementary Figure 1 from MDH1 and MPP7 Regulate Autophagy in Pancreatic Ductal Adenocarcinoma

Author

New, Maria, primary, Van Acker, Tim, primary, Sakamaki, Jun-Ichi, primary, Jiang, Ming, primary, Saunders, Rebecca E., primary, Long, Jaclyn, primary, Wang, Victoria M.-Y., primary, Behrens, Axel, primary, Cerveira, Joana, primary, Sudhakar, Padhmanand, primary, Korcsmaros, Tamas, primary, Jefferies, Harold B.J., primary, Ryan, Kevin M., primary, Howell, Michael, primary, and Tooze, Sharon A., primary

Published
2023
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98. Data from MDH1 and MPP7 Regulate Autophagy in Pancreatic Ductal Adenocarcinoma

Author

New, Maria, primary, Van Acker, Tim, primary, Sakamaki, Jun-Ichi, primary, Jiang, Ming, primary, Saunders, Rebecca E., primary, Long, Jaclyn, primary, Wang, Victoria M.-Y., primary, Behrens, Axel, primary, Cerveira, Joana, primary, Sudhakar, Padhmanand, primary, Korcsmaros, Tamas, primary, Jefferies, Harold B.J., primary, Ryan, Kevin M., primary, Howell, Michael, primary, and Tooze, Sharon A., primary

Published
2023
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99. Supplementary Table 1 from MDH1 and MPP7 Regulate Autophagy in Pancreatic Ductal Adenocarcinoma

Author

New, Maria, primary, Van Acker, Tim, primary, Sakamaki, Jun-Ichi, primary, Jiang, Ming, primary, Saunders, Rebecca E., primary, Long, Jaclyn, primary, Wang, Victoria M.-Y., primary, Behrens, Axel, primary, Cerveira, Joana, primary, Sudhakar, Padhmanand, primary, Korcsmaros, Tamas, primary, Jefferies, Harold B.J., primary, Ryan, Kevin M., primary, Howell, Michael, primary, and Tooze, Sharon A., primary

Published
2023
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100. Supplementary Table 4 from MDH1 and MPP7 Regulate Autophagy in Pancreatic Ductal Adenocarcinoma

Author

New, Maria, primary, Van Acker, Tim, primary, Sakamaki, Jun-Ichi, primary, Jiang, Ming, primary, Saunders, Rebecca E., primary, Long, Jaclyn, primary, Wang, Victoria M.-Y., primary, Behrens, Axel, primary, Cerveira, Joana, primary, Sudhakar, Padhmanand, primary, Korcsmaros, Tamas, primary, Jefferies, Harold B.J., primary, Ryan, Kevin M., primary, Howell, Michael, primary, and Tooze, Sharon A., primary

Published
2023
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