Episode 511 - How the earliest brains developed and handle touch

Peering into the history of brains with some amazing tiny fossils. How did the earliest brains develop? Is a head just an extension of a segmented body or something else entirely? How did the first brains and nervous systems evolve in arthropods. How does your body process the sense of touch? The faintest sensations of touch are handled by specialist cells in your spinal cord. How do your  brain stem and spinal cord help your body process the senses?

1. Nicholas J. Strausfeld, Xianguang Hou, Marcel E. Sayre, Frank Hirth. The lower Cambrian lobopodian Cardiodictyon resolves the origin of euarthropod brains. Science, 2022; 378 (6622): 905 DOI: 10.1126/science.abn6264
2. Turecek, J., Lehnert, B.P. & Ginty, D.D. The encoding of touch by somatotopically aligned dorsal column subdivisions. Nature, 2022 DOI: 10.1038/s41586-022-05470-x
3. Anda M. Chirila, Genelle Rankin, Shih-Yi Tseng, Alan J. Emanuel, Carmine L. Chavez-Martinez, Dawei Zhang, Christopher D. Harvey, David D. Ginty. Mechanoreceptor signal convergence and transformation in the dorsal horn flexibly shape a diversity of outputs to the brain. Cell, 2022; 185 (24): 4541 DOI: 10.1016/j.cell.2022.10.012

Episode 510 - Fungi spreading across the planet and wiping out toxic soils

Fungi have an amazing ability to spread across continents but stay linked as a family lineage. Fungi can adapt to specific geographic niches in the same way as grapes. Different families of highly specialized mushrooms grow side by side across continents. How can fungi protect the plants it's attached to? Fungi often get a bad rap in farming, but they can be used to detoxify soils. Removing mercury and boosting crops; is there anything fungi can't do?

1. Keaton Tremble, J. I. Hoffman, Bryn T. M. Dentinger. Contrasting continental patterns of adaptive population divergence in the holarctic ectomycorrhizal fungus Boletus edulis. New Phytologist, 2022; DOI: 10.1111/nph.18521
2. Congcong Wu, Dan Tang, Jin Dai, Xingyuan Tang, Yuting Bao, Jiali Ning, Qing Zhen, Hui Song, Raymond J. St. Leger, Weiguo Fang. Bioremediation of mercury-polluted soil and water by the plant symbiotic fungus Metarhizium robertsii. Proceedings of the National Academy of Sciences, 2022; 119 (47) DOI: 10.1073/pnas.2214513119

Episode 509 - What connects spicy food, proteins and your gut

How is your gut connected to the rest of your body? How does your nervous system connect to your gut? How can you sense pain inside of your gut? The bacteria that live inside your gut can call for help when under pressure. With the wrong balance of bacteria or signalling proteins our guts can be more prone for inflammation and damage. How can bad bacteria escape from the gut and evade detection? What enables some bacteria to sneak out of the intestine and wreck havoc.

1. Wen Zhang, Mengze Lyu, Nicholas J. Bessman, Zili Xie, Mohammad Arifuzzaman, Hiroshi Yano, Christopher N. Parkhurst, Coco Chu, Lei Zhou, Gregory G. Putzel, Ting-Ting Li, Wen-Bing Jin, Jordan Zhou, Hongzhen Hu, Amy M. Tsou, Chun-Jun Guo, David Artis. Gut-innervating nociceptors regulate the intestinal microbiota to promote tissue protection. Cell, 2022; DOI: 10.1016/j.cell.2022.09.008
2. Yusibeska Ramos, Stephanie Sansone, Sung-Min Hwang, Tito A. Sandoval, Mengmeng Zhu, Guoan Zhang, Juan R. Cubillos-Ruiz, Diana K. Morales. Remodeling of the Enterococcal Cell Envelope during Surface Penetration Promotes Intrinsic Resistance to Stress. mBio, 2022; DOI: 10.1128/mbio.02294-22

Episode 508 - Finding your way as a fish along rivers and into the deep

How can fish keep themselves stable in a fast flowing river? What's the best way to stay on track as a fish? To swim straight ahead fish often end up staring downwards. The riverbed is way easier to track than a fast flowing current. How did fish manage to make their way into the deepest parts of the ocean? What climatic factors drove fish to explore deeper and deeper? What changed in Earth's history to encourage fish to thrive in the deepest parts of oceans?

1. Emma Alexander, Lanya T. Cai, Sabrina Fuchs, Tim C. Hladnik, Yue Zhang, Venkatesh Subramanian, Nicholas C. Guilbeault, Chinnian Vijayakumar, Muthukumarasamy Arunachalam, Scott A. Juntti, Tod R. Thiele, Aristides B. Arrenberg, Emily A. Cooper. Optic flow in the natural habitats of zebrafish supports spatial biases in visual self-motion estimation. Current Biology, 2022; DOI: 10.1016/j.cub.2022.10.009
2. Elizabeth Christina Miller, Christopher M. Martinez, Sarah T. Friedman, Peter C. Wainwright, Samantha A. Price, Luke Tornabene. Alternating regimes of shallow and deep-sea diversification explain a species-richness paradox in marine fishes. Proceedings of the National Academy of Sciences, 2022; 119 (43) DOI: 10.1073/pnas.2123544119

Episode 507 - Peering beneath Mars’ surface

How does a single sensor help change your outlook on a planet? A single small seismometer on Mars can help understand Mars' past, present and future. What do an ultrasound and Mars have in common? Both can use a single sensor to peer deep inside. Listening to the echoes of marsquakes helps researchers understand what's in Mars' core. Modelling the inside of Mars' core helps researchers understand its past and future. Mars is often thought to be volcanically dead, but there are signs of some activity. A cluster of marsquakes can help researchers find evidence of vulcanism on Mars.

1. Sheng Wang, Hrvoje Tkalčić. Scanning for planetary cores with single-receiver intersource correlations. Nature Astronomy, 2022; DOI: 10.1038/s41550-022-01796-8
2. Simon C. Stähler, Anna Mittelholz, Cleément Perrin, Taichi Kawamura, Doyeon Kim, Martin Knapmeyer, Géraldine Zenhäusern, John Clinton, Domenico Giardini, Philippe Lognonné, W. Bruce Banerdt. Tectonics of Cerberus Fossae unveiled by marsquakes. Nature Astronomy, 2022; DOI: 10.1038/s41550-022-01803-y

Episode 506 - Assimilating all microbes in it’s path to chow down on Methane

How have microbes changed the course of life on our planet? How has our atmosphere changed as a result of bacteria and archaea? Assimilation can help enhance single cellular life. Archaea can collect long strings of extra genes just in case. Finding the right gene at the right moment can help Archaea make the most of available food.

1. Basem Al-Shayeb, Marie C. Schoelmerich, Jacob West-Roberts, Luis E. Valentin-Alvarado, Rohan Sachdeva, Susan Mullen, Alexander Crits-Christoph, Michael J. Wilkins, Kenneth H. Williams, Jennifer A. Doudna, Jillian F. Banfield. Borgs are giant genetic elements with potential to expand metabolic capacity. Nature, 2022; DOI: 10.1038/s41586-022-05256-1

Episode 505 - Complex ocean currents sustaining life across the depths

Ocean currents can have global impacts shaping our climate and life in the seas and onshore. How do the ocean currents circulate and vary not just on the surface but beneath the waves? It's easy to picture different layers of clouds, but the same is true for our oceans. Large circulating patterns of currents called Gyres govern the oceans. Tiny phytoplankton keep our oceans alive but how do they get enough food themselves? The middle of a gyre gets baked in sun and seems to lack nutrient sources, so how do microbes survive there? When phytoplankton die they rain down nutrients and carbon to lower layers of the ocean as marine snow.

1. Mukund Gupta, Richard G. Williams, Jonathan M. Lauderdale, Oliver Jahn, Christopher Hill, Stephanie Dutkiewicz, Michael J. Follows. A nutrient relay sustains subtropical ocean productivity. Proceedings of the National Academy of Sciences, 2022; 119 (41) DOI: 10.1073/pnas.2206504119

Episode 504 - Looking inside living cells with Bioorthogonal chemistry

A big prize like the Nobel for Chemistry doesn't appear out of nowhere. To win a Nobel Prize, a lot of team work in laboratories and across the world has to come together. We find out about the research that led towards the Nobel Prize for chemistry and how it grew. How does Click Chemistry solve the problem of messy and complicated reactions? How do you look inside a cell when it's working without destroying it? How can you get precise tracking of cells behavior using Bioorthogonal chemistry.

1. Castelvecchi, D. and Ledford, H., 2022. Chemists who invented revolutionary ‘click’ reactions win Nobel. [online] Nature.com. Available at: <https://www.nature.com/articles/d41586-022-03087-8> [Accessed 8 October 2022].
2. Ramström, O., 2022. CLICK CHEMISTRY A N D BIOORTHOGONAL CHEMISTRY. [online] Nobelprize.org. Available at: <https://www.nobelprize.org/uploads/2022/10/advanced-chemistryprize2022.pdf> [Accessed 8 October 2022].
3. Zhang, H., 2022. Nobel Prize: How click chemistry and bioorthogonal chemistry are transforming the pharmaceutical and material industries. [online] The Conversation. Available at: <https://theconversation.com/nobel-prize-how-click-chemistry-and-bioorthogonal-chemistry-are-transforming-the-pharmaceutical-and-material-industries-191995> [Accessed 8 October 2022].

Episode 503 - Blending nanotubes and living cells

Episode 502 - Ignobel prizes ’22 - Blind dates and Mother Ducks

We celebrate the Ignobel prizes for 2022 with science that makes you laugh and then think. What connects a Fish, ducks and slipstream racing? How do mother ducks manage to keep all their ducklings in tow? Does swimming in formation help the ducks save energy? What's the best spot in the slipstream to be? We all know following in the slipstream is good, but if you're 3 or more back you can literally get pulled along. Complex fluid mechanics makes swimming in a line a way for a mother duck to pull the ducklings along. What happens physically when you find someone who is a good match? Is eye contact or heart rate a better measure of having  a 'spark' with someone new?

1. Wave-Riding and Wave-Passing by Ducklings in Formation Swimming,” Zhi-Ming Yuan, Minglu Chen, Laibing Jia, Chunyan Ji, and Atilla Incecik, Journal of Fluid Mechanics, vol. 928, no. R2, 2021.
2. “Energy Conservation by Formation Swimming: Metabolic Evidence from Ducklings,” Frank E. Fish, in the book Mechanics and Physiology of Animal Swimming, 1994, pp. 193-204.
3. Physiological Synchrony is Associated with Attraction in a Blind Date Setting,” Eliska Prochazkova, Elio Sjak-Shie, Friederike Behrens, Daniel Lindh, and Mariska E. Kret, Nature Human Behaviour, vol. 6, no. 2, 2022, pp. 269-278.

Episode 501 - The journey of the mandarin

Mandarin oranges are very closely related but also incredibly diverse. A quirk of cloning means we can accurately trace the journey of all mandarins back to their origins in Hunan province. Mandarins come in so many shapes and sizes and are used to celebrate by many cultures, but they all share a lot in common. Oregano and Thyme both produce some great smells, but these chemicals can carry a useful punch. How do Oregano and Thyme produce chemicals with antibacterial properties?

1. Sandra T. Krause, Pan Liao, Christoph Crocoll, Benoît Boachon, Christiane Förster, Franziska Leidecker, Natalie Wiese, Dongyan Zhao, Joshua C. Wood, C. Robin Buell, Jonathan Gershenzon, Natalia Dudareva, Jörg Degenhardt. The biosynthesis of thymol, carvacrol, and thymohydroquinone in Lamiaceae proceeds via cytochrome P450s and a short-chain dehydrogenase. Proceedings of the National Academy of Sciences, 2021; 118 (52): e2110092118 DOI: 10.1073/pnas.2110092118
2. Guohong Albert Wu, Chikatoshi Sugimoto, Hideyasu Kinjo, Chika Azama, Fumimasa Mitsube, Manuel Talon, Frederick G. Gmitter, Daniel S. Rokhsar. Diversification of mandarin citrus by hybrid speciation and apomixis. Nature Communications, 2021; 12 (1) DOI: 10.1038/s41467-021-24653-0

Episode 500 - Forest helping pump water and create rain

Plants harness the energy from the sun for so much more than photosynthesis. You have a beating hart to pump around your blood, but what do plants. Plants' vascular systems aren't pressurized so how do they power their circulation? Just how much energy do plants use globally each year to pump water out of the ground and into their leaves? Plants use incredible amounts of energy each year just to pump water out of the ground into their leaves. The fresh scents of plants are organic compounds that can reveal a lot about a plants condition. The scents of plants can play a role in influencing the climate around them. 

1. Gregory R. Quetin, Leander D. L. Anderegg, Alexandra G. Konings, Anna T. Trugman. Quantifying the Global Power Needed for Sap Ascent in Plants. Journal of Geophysical Research: Biogeosciences, 2022; 127 (8) DOI: 10.1029/2022JG006922
2. Joseph Byron, Juergen Kreuzwieser, Gemma Purser, Joost van Haren, S. Nemiah Ladd, Laura K. Meredith, Christiane Werner, Jonathan Williams. Chiral monoterpenes reveal forest emission mechanisms and drought responses. Nature, 2022; 609 (7926): 307 DOI: 10.1038/s41586-022-05020-5

Episode 499 - Air and atmospheres on exoplanets

CO2 gets a lot of bad press on earth, but in space, it could actually be incredibly helpful. On Mars, the Perseverance mission turned CO2 into Oxygen just like a tree. Making air on Mars requires a bit of Moxie and Perseverance. Mar's atmosphere may be thin, highly variable and full of CO2 but it can be harnessed to produce Oxygen. Could future mission to Mars make their own oxygen on the surface of Mars? Finding CO2 on exoplanets has been incredibly hard but the JWST helps shed light on this universal gas. Incredible hot, massive but not super dense, the Hot Jupiter WASP-39b becomes the latest target of the JWST. What can a hot Jupiter like WASP-39b teach us about exoplanet formation?

1. The JWST Transiting Exoplanet Community Early Release Science Team et al. Identification of carbon dioxide in an exoplanet atmosphere. Nature (in press), 2022 [abstract]
2. Jeffrey A. Hoffman, Michael H. Hecht, Donald Rapp, Joseph J. Hartvigsen, Jason G. Soohoo, Asad M. Aboobaker, John B. Mcclean, Andrew M. Liu, Eric D. Hinterman, Nasr, Shravan Hariharan, Kyle J. Horn, Forrest E. Meyen, Harald Okkels, Parker Steen, Singaravelu Elangovan, Christopher R. Graves, Piyush Khopkar, Morten B. Madsen, Gerald E. Voecks, Peter, H. Smith, Theis, L. Skafte, Koorosh R. Araghiand, David J. Eisenman. Mars Oxygen ISRU Experiment (MOXIE)—Preparing for human Mars exploration. Science Advances, 2022 DOI: DOI: 10.1126/sciadv.abp8636

Episode 498 - Proteins, MRNA and fighting back against cancer

How can we develop new treatments to tackle antibiotic resistance and tumors. Antibiotics were the miracle of public health in the 20th century, but how can we establish new treatments into the 21st. Find the right protein and you can stop bacteria in its tracks by splitting it in two. New treatments can tackle antibiotic resistant bacteria by using proteins to break them in two. Cancer vaccines are benefiting from the mRNA revolution. A challenge with vaccines is that they can end up in the liver, so how do you get them to  deliver their instructions more effectively. Using special lipid nano particles, cancer mRNA vaccines can target the lymph nodes making for more powerful vaccines.

1. Shouya Feng, Daniel Enosi Tuipulotu, Abhimanu Pandey, Weidong Jing, Cheng Shen, Chinh Ngo, Melkamu B. Tessema, Fei-Ju Li, Daniel Fox, Anukriti Mathur, Anyang Zhao, Runli Wang, Klaus Pfeffer, Daniel Degrandi, Masahiro Yamamoto, Patrick C. Reading, Gaetan Burgio, Si Ming Man. Pathogen-selective killing by guanylate-binding proteins as a molecular mechanism leading to inflammasome signaling. Nature Communications, 2022; 13 (1) DOI: 10.1038/s41467-022-32127-0
2. Jinjin Chen, Zhongfeng Ye, Changfeng Huang, Min Qiu, Donghui Song, Yamin Li, Qiaobing Xu. Lipid nanoparticle-mediated lymph node–targeting delivery of mRNA cancer vaccine elicits robust CD8 + T cell response. Proceedings of the National Academy of Sciences, 2022; 119 (34) DOI: 10.1073/pnas.2207841119

Episode 497 - Wearable med-tech inside and out

Wearable medical devices inside and outside of your body. Understanding what's happening inside your body can be tricky. Lugging around a scanning device with you all day isn't practical, but how can doctors tell what's happening in your daily life? Want to know what your organs are doing when you go for a jog or live your daily life? Wearable ultrasonic patches can give precise and long term ultrasounds making precise medicine possible. Stimulating nerves is a useful treatment for some conditions like Parkinson's or epilepsy but are very invasive. How can you use magnets to make these treatments much more friendly.

1. Chonghe Wang, Xiaoyu Chen, Liu Wang, Mitsutoshi Makihata, Hsiao-Chuan Liu, Tao Zhou, Xuanhe Zhao. Bioadhesive ultrasound for long-term continuous imaging of diverse organs. Science, 2022; 377 (6605): 517 DOI: 10.1126/science.abo2542
2. Joshua C. Chen, Peter Kan, Zhanghao Yu, Fatima Alrashdan, Roberto Garcia, Amanda Singer, C. S. Edwin Lai, Ben Avants, Scott Crosby, Zhongxi Li, Boshuo Wang, Michelle M. Felicella, Ariadna Robledo, Angel V. Peterchev, Stefan M. Goetz, Jeffrey D. Hartgerink, Sunil A. Sheth, Kaiyuan Yang, Jacob T. Robinson. A wireless millimetric magnetoelectric implant for the endovascular stimulation of peripheral nerves. Nature Biomedical Engineering, 2022; DOI: 10.1038/s41551-022-00873-7

Episode 496 - Dwarf Planets and Massive collisions forming Moons

Dwarf planets are strange objects in our solar systems, but Ceres is unusual amongst that group. Why is Ceres' surface so strange and how could it have formed without a hot core? Ceres is too small to really have a molten core or large molten surfaces. How did Ceres end up with odd plateaus and continent like features without an active core? How could radiation cause Ceres to form in such an odd way? The Moon's relative size is puzzling but how can we prove that it was caused by a colossal collision?

1. Scott D. King, Michael T. Bland, Simone Marchi, Carol A. Raymond, Christopher T. Russell, Jennifer E. C. Scully, Hanna G. Sizemore. Ceres’ Broad‐Scale Surface Geomorphology Largely Due To Asymmetric Internal Convection. AGU Advances, 2022; 3 (3) DOI: 10.1029/2021AV000571
2. Patrizia Will, Henner Busemann, My E. I. Riebe, Colin Maden. Indigenous noble gases in the Moon’s interior. Science Advances, 2022; 8 (32) DOI: 10.1126/sciadv.abl4920

Episode 495 - Plants without sunlight and electricity from sweat

How can we take ideas from nature and turn them upside down like growing plants without sunlight. There are some plants that thrive in 'low light' but what if they needed no light? Is it possible to change photosynthesis to work even without sunlight? Photosynthesis is great and all, but it's only around 1% efficient, so can it be improved? IF you were to make artificial photosynthesis can it outperform good ol natural sunlight? Biofilms are often the scourge of wearable devices, but what if they could help generate power? Turning sweat into electricity with bacteria could power your wearable devices.

1. Elizabeth C. Hann, Sean Overa, Marcus Harland-Dunaway, Andrés F. Narvaez, Dang N. Le, Martha L. Orozco-Cárdenas, Feng Jiao, Robert E. Jinkerson. A hybrid inorganic–biological artificial photosynthesis system for energy-efficient food production. Nature Food, 2022; 3 (6): 461 DOI: 10.1038/s43016-022-00530-x
2. Elizabeth C. Hann, Sean Overa, Marcus Harland-Dunaway, Andrés F. Narvaez, Dang N. Le, Martha L. Orozco-Cárdenas, Feng Jiao, Robert E. Jinkerson. A hybrid inorganic–biological artificial photosynthesis system for energy-efficient food production. Nature Food, 2022; 3 (6): 461 DOI: 10.1038/s43016-022-00530-x

Episode 494 - Mass extinctions and recovery in our oceans

What happens when most life in the ocean just dies off? Our oceans have seen many mass extinctions in the past, how long does it take to recover? What happened at the end of the Permian that caused massive extinctions in the ocean? What creatures were best able to survive when 80% of the rest of life in the ocean died? Burrowing and feeding on mud at the ocean depths helped soft bodied creatures survive a mass extinction. What lurked in the north Pacific that heated up the oceans? What was 'The Blob' and how were seals able to uncover it's secrets in the North pacific?

1. Xueqian Feng, Zhong-Qiang Chen, Michael J. Benton, Chunmei Su, David J. Bottjer, Alison T. Cribb, Ziheng Li, Laishi Zhao, Guangyou Zhu, Yuangeng Huang, Zhen Guo. Resilience of infaunal ecosystems during the Early Triassic greenhouse Earth. Science Advances, 2022; 8 (26) DOI: 10.1126/sciadv.abo0597
2. Rachel R. Holser, Theresa R. Keates, Daniel P. Costa, Christopher A. Edwards. Extent and Magnitude of Subsurface Anomalies During the Northeast Pacific Blob as Measured by Animal‐Borne Sensors. Journal of Geophysical Research: Oceans, 2022; 127 (7) DOI: 10.1029/2021JC018356

Episode 493 - Pleasant memories of sound and music relieving pain

There are plenty of tales of music soothing wild beasts, but is there actually a link between music and pain relief? How did researchers quantitatively study the soothing powers of music? What's better for blocking out pain ; Classical music, discordant arrangements or white noise? How does sound dull the effect of pain in mice? Just how good is a bat's auditory long term memory? can you train a bat to recognize the sound of a tasty treat? How do bats process and associate sounds with food?

1. Wenjie Zhou, Chonghuan Ye, Haitao Wang, Yu Mao, Weijia Zhang, An Liu, Chen-Ling Yang, Tianming Li, Lauren Hayashi, Wan Zhao, Lin Chen, Yuanyuan Liu, Wenjuan Tao, Zhi Zhang. Sound induces analgesia through corticothalamic circuits. Science, 2022; 377 (6602): 198 DOI: 10.1126/science.abn4663
2. M. May Dixon, Patricia L. Jones, Michael J. Ryan, Gerald G. Carter, Rachel A. Page. Long-term memory in frog-eating bats. Current Biology, 2022; 32 (12): R557 DOI: 10.1016/j.cub.2022.05.031

Episode 492 - Finding hidden objects in the early universe

How can you find objects that are hard to see in the depths of space? There is plenty of gas in a galaxy, but trying to see a cloud amongst all those starts is not easy. The further back in time you look in the history of the universe, the colder and darker it gets. How do you figure out the structure of the earliest galaxies and their cold gas? A black hole roaming across a galaxy sounds like bad sci fi horror, but may have been found. How can you spot a black hole without any frame of reference? Detecting a roaming black hole is tricky but not impossible.

1. 1. Kieran A. Cleary, Jowita Borowska, Patrick C. Breysse, Morgan Catha, Dongwoo T. Chung, Sarah E. Church, Clive Dickinson, Hans Kristian Eriksen, Marie Kristine Foss, Joshua Ott Gundersen, Stuart E. Harper, Andrew I. Harris, Richard Hobbs, Håvard T. Ihle, Junhan Kim, Jonathon Kocz, James W. Lamb, Jonas G. S. Lunde, Hamsa Padmanabhan, Timothy J. Pearson, Liju Philip, Travis W. Powell, Maren Rasmussen, Anthony C. S. Readhead, Thomas J. Rennie, Marta B. Silva, Nils-Ole Stutzer, Bade D. Uzgil, Duncan J. Watts, Ingunn Kathrine Wehus, David P. Woody, Lilian Basoalto, J. Richard Bond, Delaney A. Dunne, Todd Gaier, Brandon Hensley, Laura C. Keating, Charles R. Lawrence, Norman Murray, Roberta Paladini, Rodrigo Reeves, Marco P. Viero, Risa H. Wechsler. COMAP Early Science. I. Overview. The Astrophysical Journal, 2022; 933 (2): 182 DOI: 10.3847/1538-4357/ac63cc
   2. Casey Y. Lam, Jessica R. Lu, Andrzej Udalski, Ian Bond, David P. Bennett, Jan Skowron, Przemek Mroz, Radek Poleski, Takahiro Sumi, Michal K. Szymanski, Szymon Kozlowski, Pawel Pietrukowicz, Igor Soszynski, Krzysztof Ulaczyk, Lukasz Wyrzykowski, Shota Miyazaki, Daisuke Suzuki, Naoki Koshimoto, Nicholas J. Rattenbury, Matthew W. Hosek Jr., Fumio Abe, Richard Barry, Aparna Bhattacharya, Akihiko Fukui, Hirosane Fujii, Yuki Hirao, Yoshitaka Itow, Rintaro Kirikawa, Iona Kondo, Yutaka Matsubara, Sho Matsumoto, Yasushi Muraki, Greg Olmschenk, Clement Ranc, Arisa Okamura, Yuki Satoh, Stela Ishitani Silva, Taiga Toda, Paul J. Tristram, Aikaterini Vandorou, Hibiki Yama, Natasha S. Abrams, Shrihan Agarwal, Sam Rose, Sean K. Terry. An isolated mass gap black hole or neutron star detected with astrometric microlensing. Accepted to APJ Letters, 2022 [abstract]
   3. Kailash C. Sahu, Jay Anderson, Stefano Casertano, Howard E. Bond, Andrzej Udalski, Martin Dominik, Annalisa Calamida, Andrea Bellini, Thomas M. Brown, Marina Rejkuba, Varun Bajaj, Noe Kains, Henry C. Ferguson, Chris L. Fryer, Philip Yock, Przemek Mroz, Szymon Kozlowski, Pawel Pietrukowicz, Radek Poleski, Jan Skowron, Igor Soszynski, Michael K. Szymanski, Krzysztof Ulaczyk, Lukasz Wyrzykowski, Richard Barry, David P. Bennett, Ian A. Bond, Yuki Hirao, Stela Ishitani Silva, Iona Kondo, Naoki Koshimoto, Clement Ranc, Nicholas J. Rattenbury, Takahiro Sumi, Daisuke Suzuki, Paul J. Tristram, Aikaterini Vandorou, Jean-Philippe Beaulieu, Jean-Baptiste Marquette, Andrew Cole, Pascal Fouque, Kym Hill, Stefan Dieters, Christian Coutures, Dijana Dominis-Prester, Clara Bennett, Etienne Bachelet, John Menzies, Michael Alb-row, Karen Pollard, Andrew Gould, Jennifer Yee, William Allen, Leonardo Andrade de Almeida, Grant Christie, John Drummond, Avishay Gal-Yam, Evgeny Gorbikov, Francisco Jablonski, Chung-Uk Lee, Dan Maoz, Ilan Manulis, Jennie McCormick, Tim Natusch, Richard W. Pogge, Yossi Shvartzvald, Uffe G. Jorgensen, Khalid A. Alsubai, Michael I. Andersen, Valerio Bozza, Sebastiano Calchi Novati, Martin Burgdorf, Tobias C. Hinse, Markus Hundertmark, Tim-Oliver Husser, Eamonn Kerins, Penelope Longa-Pena, Luigi Mancini, Matthew Penny, Sohrab Rahvar, Davide Ricci, Sedighe Sajadian, Jesper Skottfelt, Colin Snodgrass, John Southworth, Jeremy Tregloan-Reed, Joachim Wambsganss, Olivier Wertz, Yiannis Tsapras, Rachel A. Street, Daniel M. Bramich, Keith Horne, Iain A. Steele. An Isolated Stellar-Mass Black Hole Detected Through Astrometric Microlensing. Accepted to APJ, 2022 [abstract]