Your search keyword '"Mann, Graham"' showing total 10 results

1. Follow-up assessment of sleep-related symptoms in patients after treatment for cancer: responses to continuous positive airway pressure treatment for co-morbid obstructive sleep apnoea

Author

Subramanian, Harini, Trivedi, Ritu, Fuchsova, Veronika, Elder, Elisabeth, Brand, Alison, Howle, Julie, Mann, Graham J., DeFazio, Anna, Amis, Terence, and Kairaitis, Kristina

Published

2024

2. Cancer Risks Associated With TP53 Pathogenic Variants: Maximum Likelihood Analysis of Extended Pedigrees for Diagnosis of First Cancers Beyond the Li-Fraumeni Syndrome Spectrum

Author

Fortuno, Cristina, Feng, Bing-Jian, Carroll, Courtney, Innella, Giovanni, Kohlmann, Wendy, Lázaro, Conxi, Brunet, Joan, Feliubadaló, Lidia, Iglesias, Silvia, Menéndez, Mireia, Teulé, Alex, Ballinger, Mandy L., Thomas, David M., Campbell, Ainsley, Field, Mike, Harris, Marion, Kirk, Judy, Pachter, Nicholas, Poplawski, Nicola, Susman, Rachel, Tucker, Kathy, Wallis, Mathew, Williams, Rachel, Cops, Elisa, Goldgar, David, James, Paul A., Spurdle, Amanda B., Amor, David, Andrews, Lesley, Antill, Yoland, Balleine, Rosemary, Beesley, Jonathan, Bennett, Ian, Bogwitz, Michael, Bodek, Simon, Botes, Leon, Brennan, Meagan, Brown, Melissa, Buckley, Michael, Burke, Jo, Butow, Phyllis, Caldon, Liz, Campbell, Ian, Cao, Michelle, Chakrabarti, Anannya, Chauhan, Deepa, Chauhan, Manisha, Chenevix-Trench, Georgia, Christian, Alice, Cohen, Paul, Colley, Alison, Crook, Ashley, Cui, James, Courtney, Eliza, Cummings, Margaret, Dawson, Sarah-Jane, deFazio, Anna, Delatycki, Martin, Dickson, Rebecca, Dixon, Joanne, Edkins, Ted, Edwards, Stacey, Farshid, Gelareh, Fellows, Andrew, Fenton, Georgina, Field, Michael, Flanagan, James, Fong, Peter, Forrest, Laura, Fox, Stephen, French, Juliet, Friedlander, Michael, Gaff, Clara, Gattas, Mike, George, Peter, Greening, Sian, Harris, Marion, Hart, Stewart, Hayward, Nick, Hopper, John, Hoskins, Cass, Hunt, Clare, James, Paul, Jenkins, Mark, Kidd, Alexa, Kirk, Judy, Koehler, Jessica, Kollias, James, Lakhani, Sunil, Lawrence, Mitchell, Lee, Jason, Li, Shuai, Lindeman, Geoff, Lippey, Jocelyn, Lipton, Lara, Lobb, Liz, Loi, Sherene, Mann, Graham, Marsh, Deborah, McLachlan, Sue Anne, Meiser, Bettina, Milne, Roger, Nightingale, Sophie, OʼConnell, Shona, OʼSullivan, Sarah, Ortega, David Gallego, Pachter, Nick, Pang, Jia-Min, Pathak, Gargi, Patterson, Briony, Pearn, Amy, Phillips, Kelly, Pieper, Ellen, Ramus, Susan, Rickard, Edwina, Robinson, Bridget, Saleh, Mona, Skandarajah, Anita, Salisbury, Elizabeth, Saunders, Christobel, Saunus, Jodi, Savas, Peter, Scott, Rodney, Scott, Clare, Sexton, Adrienne, Shaw, Joanne, Shelling, Andrew, Srinivasa, Shweta, Simpson, Peter, Southey, Melissa, Spurdle, Amanda, Taylor, Jessica, Taylor, Renea, Thorne, Heather, Trainer, Alison, Tucker, Kathy, Visvader, Jane, Walker, Logan, Williams, Rachael, Winship, Ingrid, Young, Mary Ann, and Zaheed, Milita

Published

2024

3. The Recovery and Re-Calibration of a 13-Month Aerosol Extinction Profiles Dataset from Searchlight Observations from New Mexico, after the 1963 Agung Eruption

Author

Antuña-Marrero, Juan-Carlos, primary, Mann, Graham W., additional, Barnes, John, additional, Calle, Abel, additional, Dhomse, Sandip S., additional, Cachorro, Victoria E., additional, Deshler, Terry, additional, Li, Zhengyao, additional, Sharma, Nimmi, additional, and Elterman, Louis, additional

Published

2024

4. Analysis of the global atmospheric background sulfur budget in a multi-model framework

Author

Brodowsky, Christina V., primary, Sukhodolov, Timofei, additional, Chiodo, Gabriel, additional, Aquila, Valentina, additional, Bekki, Slimane, additional, Dhomse, Sandip S., additional, Höpfner, Michael, additional, Laakso, Anton, additional, Mann, Graham W., additional, Niemeier, Ulrike, additional, Pitari, Giovanni, additional, Quaglia, Ilaria, additional, Rozanov, Eugene, additional, Schmidt, Anja, additional, Sekiya, Takashi, additional, Tilmes, Simone, additional, Timmreck, Claudia, additional, Vattioni, Sandro, additional, Visioni, Daniele, additional, Yu, Pengfei, additional, Zhu, Yunqian, additional, and Peter, Thomas, additional

Published

2024

5. The 2019 Raikoke eruption as a testbed used by the Volcano Response group for rapid assessment of volcanic atmospheric impacts.

Author

Vernier, Jean-Paul, Aubry, Thomas J., Timmreck, Claudia, Schmidt, Anja, Clarisse, Lieven, Prata, Fred, Theys, Nicolas, Prata, Andrew T., Mann, Graham, Choi, Hyundeok, Carn, Simon, Rigby, Richard, Loughlin, Susan C., and Stevenson, John A.

Subjects

VOLCANIC eruptions, STRATOSPHERIC aerosols, VOLCANIC gases, EXPLOSIVE volcanic eruptions, VOLCANOES, LIFE cycles (Biology), RADIATIVE forcing

Abstract

​​​​​​​The 21 June 2019 Raikoke eruption (48° N, 153° E) generated one of the largest amounts of sulfur emission to the stratosphere since the 1991 Mt. Pinatubo eruption. Satellite measurements indicate a consensus best estimate of 1.5 Tg for the sulfur dioxide (SO 2) injected at an altitude of around 14–15 km. The peak Northern Hemisphere (NH) mean 525 nm stratospheric aerosol optical depth (SAOD) increased to 0.025, a factor of 3 higher than background levels. The Volcano Response (VolRes) initiative provided a platform for the community to share information about this eruption which significantly enhanced coordination efforts in the days after the eruption. A multi-platform satellite observation subgroup formed to prepare an initial report to present eruption parameters including SO 2 emissions and their vertical distribution for the modeling community. It allowed us to make the first estimate of what would be the peak in SAOD 1 week after the eruption using a simple volcanic aerosol model. In this retrospective analysis, we show that revised volcanic SO 2 injection profiles yield a higher peak injection of the SO 2 mass. This highlights difficulties in accurately representing the vertical distribution for moderate SO 2 explosive eruptions in the lowermost stratosphere due to limited vertical sensitivity of the current satellite sensors (± 2 km accuracy) and low horizontal resolution of lidar observations. We also show that the SO 2 lifetime initially assumed in the simple aerosol model was overestimated by 66 %, pointing to challenges for simple models to capture how the life cycle of volcanic gases and aerosols depends on the SO 2 injection magnitude, latitude, and height. Using a revised injection profile, modeling results indicate a peak NH monthly mean SAOD at 525 nm of 0.024, in excellent agreement with observations, associated with a global monthly mean radiative forcing of - 0.17 W m -2 resulting in an annual global mean surface temperature anomaly of - 0.028 K. Given the relatively small magnitude of the forcing, it is unlikely that the surface response can be dissociated from surface temperature variability. [ABSTRACT FROM AUTHOR]

Published

2024

6. Antarctic vortex dehydration in 2023 as a substantial removal pathway for Hunga Tonga-Hunga Ha'apai water vapour

Author

Zhou, Xin, primary, Dhomse, Sandip S, additional, Feng, Wuhu, additional, Mann, Graham, additional, Heddell, Saffron, additional, Pumphrey, Hugh, additional, Kerridge, Brian J, additional, Latter, Barry, additional, Siddans, Richard, additional, Ventress, Lucy, additional, Querel, Richard, additional, Smale, Penny, additional, Asher, Elizabeth, additional, Hall, Emrys G, additional, Bekki, Slimane, additional, and Chipperfield, Martyn P, additional

Published

2024

7. Prognosis for people with multiple primary melanomas compared with a single primary melanoma

Author

Ni, Yuan, primary, Watts, Caroline G., additional, Scolyer, Richard A., additional, Madronio, Christine, additional, Armstrong, Bruce K., additional, Morton, Rachael L., additional, Menzies, Scott W., additional, Mann, Graham J., additional, Thompson, John F., additional, Cust, Anne E., additional, and Lo, Serigne N., additional

Published

2024

8. Co-observation of germline pathogenic variants in breast cancer predisposition genes: Results from analysis of the BRIDGES sequencing dataset

Author

Sahlberg, Kristine K., Børresen-Dale, Anne-Lise, Gram, Inger Torhild, Olsen, Karina Standahl, Engebråten, Olav, Naume, Bjørn, Geisler, Jürgen, OSBREAC, Grenaker Alnæs, Grethe I., Amor, David, Andrews, Lesley, Antill, Yoland, Balleine, Rosemary, Beesley, Jonathan, Bennett, Ian, Bogwitz, Michael, Bodek, Simon, Botes, Leon, Brennan, Meagan, Brown, Melissa, Buckley, Michael, Burke, Jo, Butow, Phyllis, Caldon, Liz, Campbell, Ian, Cao, Michelle, Chakrabarti, Anannya, Chauhan, Deepa, Chauhan, Manisha, Christian, Alice, Cohen, Paul, Colley, Alison, Crook, Ashley, Cui, James, Courtney, Eliza, Cummings, Margaret, Dawson, Sarah-Jane, deFazio, Anna, Delatycki, Martin, Dickson, Rebecca, Dixon, Joanne, Edwards, Stacey, Farshid, Gelareh, Fellows, Andrew, Fenton, Georgina, Field, Michael, Flanagan, James, Fong, Peter, Forrest, Laura, Fox, Stephen, French, Juliet, Friedlander, Michael, Gaff, Clara, Gattas, Mike, George, Peter, Greening, Sian, Harris, Marion, Hart, Stewart, Harraka, Philip, Hayward, Nick, Hopper, John, Hoskins, Cass, Hunt, Clare, Jenkins, Mark, Kidd, Alexa, Kirk, Judy, Koehler, Jessica, Kollias, James, Lakhani, Sunil, Lawrence, Mitchell, Lee, Jason, Li, Shuai, Lindeman, Geoff, Lippey, Jocelyn, Lipton, Lara, Lobb, Liz, Loi, Sherene, Mann, Graham, Marsh, Deborah, McLachlan, Sue Anne, Meiser, Bettina, Nightingale, Sophie, O'Connell, Shona, O'Sullivan, Sarah, Ortega, David Gallego, Pachter, Nick, Pang, Jia-Min, Pathak, Gargi, Patterson, Briony, Pearn, Amy, Phillips, Kelly, Pieper, Ellen, Ramus, Susan, Rickard, Edwina, Ragunathan, Abi, Robinson, Bridget, Saleh, Mona, Skandarajah, Anita, Salisbury, Elizabeth, Saunders, Christobel, Saunus, Jodi, Savas, Peter, Scott, Rodney, Scott, Clare, Sexton, Adrienne, Shaw, Joanne, Shelling, Andrew, Srinivasa, Shweta, Simpson, Peter, Taylor, Jessica, Taylor, Renea, Thorne, Heather, Trainer, Alison, Tucker, Kathy, Visvader, Jane, Walker, Logan, Williams, Rachael, Winship, Ingrid, Young, Mary Ann, Zaheed, Milita, Davidson, Aimee L., Michailidou, Kyriaki, Parsons, Michael T., Fortuno, Cristina, Bolla, Manjeet K., Wang, Qin, Dennis, Joe, Naven, Marc, Abubakar, Mustapha, Ahearn, Thomas U., Alonso, M. Rosario, Andrulis, Irene L., Antoniou, Antonis C., Auvinen, Päivi, Behrens, Sabine, Bermisheva, Marina A., Bogdanova, Natalia V., Bojesen, Stig E., Brüning, Thomas, Byers, Helen J., Camp, Nicola J., Campbell, Archie, Castelao, Jose E., Cessna, Melissa H., Chang-Claude, Jenny, Chanock, Stephen J., Chenevix-Trench, Georgia, Collée, J. Margriet, Czene, Kamila, Dörk, Thilo, Eriksson, Mikael, Evans, D. Gareth, Fasching, Peter A., Figueroa, Jonine D., Flyger, Henrik, Gago-Dominguez, Manuela, García-Closas, Montserrat, Glendon, Gord, González-Neira, Anna, Grassmann, Felix, Gronwald, Jacek, Guénel, Pascal, Hadjisavvas, Andreas, Haeberle, Lothar, Hall, Per, Hamann, Ute, Hartman, Mikael, Ho, Peh Joo, Hooning, Maartje J., Hoppe, Reiner, Howell, Anthony, Jakubowska, Anna, Khusnutdinova, Elza K., Kristensen, Vessela N., Li, Jingmei, Lim, Joanna, Lindblom, Annika, Liu, Jenny, Lophatananon, Artitaya, Mannermaa, Arto, Mavroudis, Dimitrios A., Mensenkamp, Arjen R., Milne, Roger L., Muir, Kenneth R., Newman, William G., Obi, Nadia, Panayiotidis, Mihalis I., Park, Sue K., Park-Simon, Tjoung-Won, Peterlongo, Paolo, Radice, Paolo, Rashid, Muhammad U., Rhenius, Valerie, Saloustros, Emmanouil, Sawyer, Elinor J., Schmidt, Marjanka K., Seibold, Petra, Shah, Mitul, Southey, Melissa C., Teo, Soo Hwang, Tomlinson, Ian, Torres, Diana, Truong, Thérèse, van de Beek, Irma, van der Hout, Annemieke H., Wendt, Camilla C., Dunning, Alison M., Pharoah, Paul D.P., Devilee, Peter, Easton, Douglas F., James, Paul A., and Spurdle, Amanda B.

Published

2024

9. Antarctic Vortex Dehydration in 2023 as a Substantial Removal Pathway for Hunga Tonga‐Hunga Ha'apai Water Vapor.

Author

Zhou, Xin, Dhomse, Sandip S., Feng, Wuhu, Mann, Graham, Heddell, Saffron, Pumphrey, Hugh, Kerridge, Brian J., Latter, Barry, Siddans, Richard, Ventress, Lucy, Querel, Richard, Smale, Penny, Asher, Elizabeth, Hall, Emrys G., Bekki, Slimane, and Chipperfield, Martyn P.

Subjects

WATER vapor, POLAR vortex, STRATOSPHERIC aerosols, HUNGA Tonga-Hunga Ha'apai Eruption & Tsunami, 2022, ATMOSPHERIC water vapor measurement, OZONE layer depletion, ATMOSPHERIC models, STRATOSPHERIC chemistry

Abstract

The January 2022 eruption of Hunga Tonga‐Hunga Ha'apai (HTHH) injected a huge amount (∼150 Tg) of water vapor (H2O) into the stratosphere, along with small amount of SO2. An off‐line 3‐D chemical transport model (CTM) successfully reproduces the spread of the injected H2O through October 2023 as observed by the Microwave Limb Sounder. Dehydration in the 2023 Antarctic polar vortex caused the first substantial (∼20 Tg) removal of HTHH H2O from the stratosphere. The CTM indicates that this process will dominate removal of HTHH H2O for the coming years, giving an overall e‐folding timescale of 4 years; around 25 Tg of the injected H2O is predicted to still remain in the stratosphere by 2030. Following relatively low Antarctic column ozone in midwinter 2023 due to transport effects, additional springtime depletion due to H2O‐related chemistry was small and maximized at the vortex edge (10 DU in column). Plain Language Summary: Around 150 Tg (150 million tons) of water vapor was injected into the stratosphere during the eruption of Hunga Tonga‐Hunga Ha'apai. Water vapor is a greenhouse gas and this increase is expected to have a warming effect in the troposphere, as well causing perturbations in stratospheric chemistry and aerosols. We use an atmospheric model to study the residence time of this excess water vapor and its impact on the recent Antarctic ozone hole. The model performance is evaluated by comparison with satellite measurements. Wintertime dehydration in the Antarctic stratosphere in 2023 is found to be an important mechanism for removal of the volcanic water from the stratosphere. However, the overall removal rate is predicted to be slow; around 25 Tg (17%) is still present in 2030. The direct impact of the excess water vapor on ozone via chemical processes in the Antarctic ozone hole in 2023 is small. Key Points: Antarctic dehydration is a major removal pathway of stratospheric H2O injected from Hunga Tonga‐Hunga Ha'apai (HTHH) eruptionHTHH H2O caused small (up to 10 DU) additional chemical ozone depletion in 2023 Antarctic springModel indicates e‐folding timescale of 4 years for removal of HTHH H2O from stratosphere [ABSTRACT FROM AUTHOR]

Published

2024

10. Variation in initial biopsy technique for primary melanoma diagnosis: a population-based cohort study in New South Wales, Australia

Author

Dempsey, Kathy, Ho, Genevieve, Lo, Serigne N., McKeown, Janet, Watts, Caroline G., Cust, Anne E., Guitera, Pascale, Scolyer, Richard A., Thompson, John F., Morton, Rachael L., Menzies, Scott, Madronio, Christine, and Mann, Graham

Abstract

Factors associated with non-adherence to guideline-recommended complete excision of suspicious cutaneous lesions are unclear.

Published

2024