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The combination of bismuth (Bi3+) and different types of antibiotics shows powerful synergistic antibacterial activity on Pseudomonas aeruginosa. Image adapted from the journal paper

HKU Chemists Pioneer Metallodrug-Antibiotic Combination Strategy to Combat Superbugs

Antimicrobial resistance (AMR) bacterial infections have become a serious problem threatening human health worldwide. The overuse of antibiotics has promoted drug-resistant mutations in bacteria, causing almost all clinically used antibiotics to develop resistance in different strains. In May 2024, the World Health Organization (WHO) updated its list of drug-resistant bacteria that pose the greatest threat to human health, among which Pseudomonas aeruginosa was listed as a high-priority pathogen. Pseudomonas aeruginosa is a particularly dangerous bacterium that can cause a wide range of infections, including pneumonia, urinary tract infections, and bloodstream infections. It is known for its ability to develop resistance to antibiotics quickly, making it challenging to treat and posing a significant risk to immunocompromised patients, such as those in hospitals or with chronic illnesses. Given the urgency of the situation, it is essential to develop new treatment strategies to combat superbug infections. Recently, a team led by Professor Hongzhe SUN from the Department of Chemistry at The University of Hong Kong, in collaboration with the University of Groningen (Netherlands) and Nankai University, has made a breakthrough in solving this challenging problem. Their work has been published in the internationally renowned journal Nature Microbiology. The team’s work has shown the combination of different types of antibiotics with bismuth-based drugs (such as bismuth subsalicylate, commonly known as Pepto-Bismol) disrupts bacterial iron homeostasis, effectively restoring the bactericidal function of multiple antibiotics. This combination therapy leads to the elimination of multi-drug resistant bacteria Pseudomonas aeruginosa. Their efficacy has been demonstrated in both bacterial-infected cells and in mouse models, providing crucial strategies for combatting the global threat of antibiotic resistance (AMR) and offering potential clinical applications. In a recent feature article in Nature, Professor Hongzhe Sun stated, ‘The next epidemic is likely to be an infection caused by superbugs. We must be fully prepared for it and have powerful arsenals to treat such deadly infections.’   Figure 1. The combination of bismuth (Bi3+) and different types of antibiotics shows powerful synergistic antibacterial activity on Pseudomonas aeruginosa. Image adapted from the journal paper Research Background With increasing concern for antibiotic resistance, scientists and clinicians all over the world are tirelessly working to find new solutions. Antibiotic-resistant bacteria like Pseudomonas aeruginosa are a major global public health challenge. There is an urgent need to develop new antibiotics or enhance and prolong the antibacterial activity of existing clinical antibiotics. Metal compounds have traditionally been used as antibacterial agents. Their multi-target mode of action allows them to interfere with multiple biological pathways in pathogens, resulting in a lower frequency of drug resistance. In recent years, Professor Sun’s team has carried out extensive work to address the problem of ‘superbugs’. For example, metallodrugs such as bismuth citrate have effectively inhibited the activity of metallo-β-lactamase, an important enzyme that bacteria use to destroy commonly used antibiotics. His team also employed a dual ‘Trojan Horse’ strategy, using metallo-sideromycin to restore the activity of cefidercofol, one of the latest antibiotics. Cefidercofol is ‘smuggled’ into bacterial cells through the bacteria’s uptake of ferric iron (Fe3+), enhancing its bactericidal effect. Additionally, a bismuth drug mimicking ferric iron enters bacteria cells and inhibit key bacterial enzymes, achieving a dual function. Key findings The combination of bismuth-based drugs and antibiotics has been proposed as a standard therapy for treating Helicobacter pylori infections in clinics. Sun’s team, for the first time, has applied this regimen to other multi-drug-resistant bacteria. Their study found that bismuth salicylate (Pepto-Bismol), when combined with different antibiotics, not only effectively eliminates multidrug-resistant Pseudomonas aeruginosa infections but also prevents the evolution of further antibiotic resistance. This breakthrough highlights the potential of using bismuth-based drugs alongside specific clinically used antibiotics to combat Pseudomonas aeruginosa infections, which are notoriously difficult to treat given their rapid development of resistance. Developing new antibiotics is both costly and time-consuming, while bacteria are quickly developing resistance, shortening the lifespan of effective antibiotics. As a result, combining existing drugs synergistically is emerging as a powerful alternative to combat the rise and spread of antibiotic-resistant bacterial strains. This study demonstrates that bismuth disrupts iron homeostasis by specifically binding to siderophore (molecules used by bacteria to obtain iron) and iron absorption regulator Fur in Pseudomonas aeruginosa. Within bacterial cells, bismuth specifically targets iron-sulfur cluster enzymes, leading to the inhibition of respiratory complexes. This disruption impairs the electron transport chain and dissipates the proton motive force. Consequently, the activity of export pumps is damaged, resulting in the accumulation of antibiotics within the bacteria and enhancing their efficacy. At the same time, this approach also enhances the killing effect of antibiotics on bacteria within the biofilm The combined treatment also demonstrated powerful antibacterial effects in the bacterial infected cell models, and the team verified the effectiveness of this therapy in over 100 strains of clinically resistant Pseudomonas aeruginosa. Finally, in a mouse lung infection model, the treatment significantly reduced bacterial colonisation in the lungs and improved the survival rate of mice. These findings lay a solid foundation for future efforts to combat drug-resistant bacterial infections and pave the way for further clinical applications. About the research team This study was collaboratively conducted by Professor Hongzhe Sun from the Department of Chemistry, Faculty of Science at The University of Hong Kong (HKU), Professor Oscar P. Kuipers from the University of Groningen, Netherlands, Dr Rubén Cebrián from the San Cecilio University Hospital in Granada, Spain, and Professor Weihui Wu from Nankai University. Dr Yushan Xia served as the first author. The research team also included PhD students Xueying Wei and Chenyuan Wang, Research Assistant Professor Dr Hongyan Li from the Department of Chemistry at HKU; Assistant Professor Dr Peng Gao from the Faculty of Dentistry, HKU, and Professor Richard Yi-Tsun Kao from the Department of Microbiology at the Li Ka Shing Faculty of Medicine at HKU, along with Professor Weihui Wu from the Department of Microbiology at Nankai University. We would like to express our sincere gratitude to the Research Grants Council of Hong Kong SAR, the Health and Medical Research Fund of the Hong Kong Health Bureau, and the and Norman & Cecilia Yip Foundation of the University of Hong Kong for their generous support of this research. Figure 2. Professor Hongzhe Sun, Chair Professor of the Department of Chemistry at The University of Hong Kong (second from right), leads a dedicated team in the battle against superbugs. This team includes (from the left) Ms Chenyuan Wang, Ms Xueying Wei, Dr Yushan Xia and Dr Hongyan Li.   About Professor Hongzhe Sun Professor Hongzhe Sun is the Norman & Cecilia Yip Professor in Bioinorganic Chemistry and Chair Professor of Chemistry at HKU. His research focuses on metalloproteomics and metallomics, the discovery of antimicrobial agents, inorganic chemical biology and chemical biotechnology. Dr Hongyan Li is a Research Assistant Professor in the Department of Chemistry at HKU. The journal paper can be accessed here.  ‘Bismuth-based drugs sensitize Pseudomonas aeruginosa to multiple antibiotics by disrupting iron homeostasis’, Xia Y, Wei X, Li H, Cebrián R, Kuipers OP, Sun H et al, Nature Microbiology, 2024.

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HKU Delegation Explores New Educational Frontiers and Opportunities in Vietnam

  In a successful trip to Ho Chi Ming City, Vietnam, from September 25 to 29, 2024, the Faculty of Science, in partnership with the Faculty of Social Sciences, Admissions Office and Representative Office of HKU in Vietnam, has made strides in strengthening its global presence and unlocking potential opportunities in the Vietnamese education sector.   In a series of visits and events, the delegation started meaningful conversations with Vietnamese high school counsellors, potential students, and local organisations and institutions, sharing insights about HKU's world-class education. Through these dialogues, bridges that could lead to exciting collaborations and partnerships in the future were established.   The Open House event on September 28 was a key highlight, drawing an enthusiastic turnout of over 120 participants, including students, parents, teachers, and media personnel. Professor Qiang ZHOU, Dean of Science, highlighted the university's global standing, stating, ‘As the oldest tertiary institution in Hong Kong, HKU stands as a beacon of academic excellence and innovation.’     In the same vein, Professor Ming WEN, Dean of Social Science, accentuated HKU’s position at the forefront of global education and its esteemed reputation as an innovative educational hub. She noted, ‘HKU's ascending international ranking stands as a testimony to our dedication to academic excellence and research proficiency, solidifying our status as a globally recognised institution.’    Their remarks conveyed both Faculties' academic prowess and diverse opportunities available, tailored specifically to the aspirations of the Vietnamese audience. This event facilitated robust engagement with the local community, serving as a platform to showcase HKU’s commitment to academic excellence, dedication to fostering intellectual growth, and continuous efforts to shape the leaders of tomorrow.   Simultaneously, visits to local high schools provided an in-depth understanding of Vietnam’s educational landscape and the unique needs and preferences of Vietnamese students interested in science and social sciences-related fields. The delegation also engaged with the Vietnam National University (HCMC) and Fulbright University Vietnam, fostering dialogue and exchange of ideas on possible collaboration and best educational practices.    Courtesy visits to local organisations, such as the Chinese Embassy and the Department of Science and Technology, further solidified diplomatic and educational ties while providing insight into Vietnam's scientific, technological, and commercial landscapes.   This trip has opened doors to new collaborations and exchanges, highlighting the potential of the Vietnamese market. HKU Science remains committed to nurturing these invaluable connections, and holds an optimistic outlook towards the myriad of opportunities awaiting in this strategically significant landscape.    Professor Qiang ZHOU, Dean of Science   The Open House event on September 28th, attracting more than 120 participants   HKU delegation paying visit to the Chinese Embassy HKU delegation visiting the Vietnam National University HKU delegation visiting to the Sunwah Innovation Center

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The leadership team of the School of Computing and Data Science (CDS).

HKU Announces the Launch of New School of Computing and Data Science to Nurture Talent in AI and Data Science

The University of Hong Kong (HKU) announces the establishment of the new School of Computing and Data Science (CDS) to consolidate and advance education and research across the fields of computing and data science, artificial intelligence (AI), statistical decision sciences, fintech, and actuarial science. The new School of CDS combines the Department of Computer Science from the Faculty of Engineering and Department of Statistics and Actuarial Science from the Faculty of Science. It aims to take a truly integrated approach to reform these related academic disciplines, as well as foster multidisciplinary research collaboration within the University and beyond. Professor Richard WONG, Provost and Deputy Vice-Chancellor, said: ‘The rapid advancements in computing technology, data science, and artificial intelligence have the potential to offer groundbreaking solutions to numerous industrial, economic, and societal challenges. It is anticipated that the demand for new and top-tier talent in these fields will rise significantly in the future. Consequently, reforming education and fundamental research in computing and data science has become a priority and a trend among top universities worldwide. This initiative also aligns well with the strategic scientific and technological plans of Hong Kong and the nation. The University of Hong Kong is determined to seize this opportunity and tackle the associated challenges. By establishing the School of Computing and Data Science, HKU aims to create synergies that will position it as a leader in transforming Hong Kong into an international hub for education and research in computing and data science.’ Professor Yi MA, Chair Professor of Artificial Intelligence, has been appointed the inaugural Director of the School of CDS. ‘By converging computing, data science, and statistics, the School of CDS aims to foster a vibrant academic community that drives innovative education, promotes multidisciplinary research, and facilitates technological innovation. It will transform education in computer science, data science, and artificial intelligence, incubating future leaders who are well-versed in these new knowledge and technology,’ said Professor Ma. Formally established on 1 July 2024, the School of CDS will admit students directly starting from the academic year 2025-26, offering eight undergraduate programmes in total. Besides revamping its flagship programme, the Bachelor of Engineering in Computer Science, the School plans to introduce a new programme, the Bachelor of Engineering in Artificial Intelligence and Data Science, which is designed to be a standalone or AI+X double degree programme. Furthermore, the School of CDS will be the home department to offer AI literacy micro-credentials for all incoming HKU undergraduate students from 2025/26. The School will also offer three new professional degrees, namely the Bachelor of Science in Decision Analytics, Risk Management, and Statistics programmes respectively. Current undergraduate students reading the existing programmes will continue their studies without being affected by the transition. For postgraduate education, new programmes will be designed in close collaboration with industry partners to cater to market needs. To mark the establishment of the School of CDS, an opening ceremony will be held on October 24 (Thursday). The ceremony will be officiated by esteemed guests, followed by keynote lectures featuring distinguished speakers.   Photo Caption: The leadership team of the School of Computing and Data Science (CDS) includes Director Professor Yi MA (front row, centre); Associate Directors Professor Tak-Wah LAM (front row, left), Professor Stephen LEE (back row, 2nd from right), Professor Siu-Ming YIU (back row, 1st from right), Professor Yizhou YU (back row, 1st from left), Professor Guosheng YIN (back row, 2nd from left); and Division Heads Professor Reynold CHENG (back row, centre) and Professor KC CHEUNGow, right

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The combination of bismuth (Bi3+) and different types of antibiotics shows powerful synergistic antibacterial activity on Pseudomonas aeruginosa. Image adapted from the journal paper

HKU Chemists Pioneer Metallodrug-Antibiotic Combination Strategy to Combat Superbugs

Antimicrobial resistance (AMR) bacterial infections have become a serious problem threatening human health worldwide. The overuse of antibiotics has promoted drug-resistant mutations in bacteria, causing almost all clinically used antibiotics to develop resistance in different strains. In May 2024, the World Health Organization (WHO) updated its list of drug-resistant bacteria that pose the greatest threat to human health, among which Pseudomonas aeruginosa was listed as a high-priority pathogen. Pseudomonas aeruginosa is a particularly dangerous bacterium that can cause a wide range of infections, including pneumonia, urinary tract infections, and bloodstream infections. It is known for its ability to develop resistance to antibiotics quickly, making it challenging to treat and posing a significant risk to immunocompromised patients, such as those in hospitals or with chronic illnesses. Given the urgency of the situation, it is essential to develop new treatment strategies to combat superbug infections. Recently, a team led by Professor Hongzhe SUN from the Department of Chemistry at The University of Hong Kong, in collaboration with the University of Groningen (Netherlands) and Nankai University, has made a breakthrough in solving this challenging problem. Their work has been published in the internationally renowned journal Nature Microbiology. The team’s work has shown the combination of different types of antibiotics with bismuth-based drugs (such as bismuth subsalicylate, commonly known as Pepto-Bismol) disrupts bacterial iron homeostasis, effectively restoring the bactericidal function of multiple antibiotics. This combination therapy leads to the elimination of multi-drug resistant bacteria Pseudomonas aeruginosa. Their efficacy has been demonstrated in both bacterial-infected cells and in mouse models, providing crucial strategies for combatting the global threat of antibiotic resistance (AMR) and offering potential clinical applications. In a recent feature article in Nature, Professor Hongzhe Sun stated, ‘The next epidemic is likely to be an infection caused by superbugs. We must be fully prepared for it and have powerful arsenals to treat such deadly infections.’   Figure 1. The combination of bismuth (Bi3+) and different types of antibiotics shows powerful synergistic antibacterial activity on Pseudomonas aeruginosa. Image adapted from the journal paper Research Background With increasing concern for antibiotic resistance, scientists and clinicians all over the world are tirelessly working to find new solutions. Antibiotic-resistant bacteria like Pseudomonas aeruginosa are a major global public health challenge. There is an urgent need to develop new antibiotics or enhance and prolong the antibacterial activity of existing clinical antibiotics. Metal compounds have traditionally been used as antibacterial agents. Their multi-target mode of action allows them to interfere with multiple biological pathways in pathogens, resulting in a lower frequency of drug resistance. In recent years, Professor Sun’s team has carried out extensive work to address the problem of ‘superbugs’. For example, metallodrugs such as bismuth citrate have effectively inhibited the activity of metallo-β-lactamase, an important enzyme that bacteria use to destroy commonly used antibiotics. His team also employed a dual ‘Trojan Horse’ strategy, using metallo-sideromycin to restore the activity of cefidercofol, one of the latest antibiotics. Cefidercofol is ‘smuggled’ into bacterial cells through the bacteria’s uptake of ferric iron (Fe3+), enhancing its bactericidal effect. Additionally, a bismuth drug mimicking ferric iron enters bacteria cells and inhibit key bacterial enzymes, achieving a dual function. Key findings The combination of bismuth-based drugs and antibiotics has been proposed as a standard therapy for treating Helicobacter pylori infections in clinics. Sun’s team, for the first time, has applied this regimen to other multi-drug-resistant bacteria. Their study found that bismuth salicylate (Pepto-Bismol), when combined with different antibiotics, not only effectively eliminates multidrug-resistant Pseudomonas aeruginosa infections but also prevents the evolution of further antibiotic resistance. This breakthrough highlights the potential of using bismuth-based drugs alongside specific clinically used antibiotics to combat Pseudomonas aeruginosa infections, which are notoriously difficult to treat given their rapid development of resistance. Developing new antibiotics is both costly and time-consuming, while bacteria are quickly developing resistance, shortening the lifespan of effective antibiotics. As a result, combining existing drugs synergistically is emerging as a powerful alternative to combat the rise and spread of antibiotic-resistant bacterial strains. This study demonstrates that bismuth disrupts iron homeostasis by specifically binding to siderophore (molecules used by bacteria to obtain iron) and iron absorption regulator Fur in Pseudomonas aeruginosa. Within bacterial cells, bismuth specifically targets iron-sulfur cluster enzymes, leading to the inhibition of respiratory complexes. This disruption impairs the electron transport chain and dissipates the proton motive force. Consequently, the activity of export pumps is damaged, resulting in the accumulation of antibiotics within the bacteria and enhancing their efficacy. At the same time, this approach also enhances the killing effect of antibiotics on bacteria within the biofilm The combined treatment also demonstrated powerful antibacterial effects in the bacterial infected cell models, and the team verified the effectiveness of this therapy in over 100 strains of clinically resistant Pseudomonas aeruginosa. Finally, in a mouse lung infection model, the treatment significantly reduced bacterial colonisation in the lungs and improved the survival rate of mice. These findings lay a solid foundation for future efforts to combat drug-resistant bacterial infections and pave the way for further clinical applications. About the research team This study was collaboratively conducted by Professor Hongzhe Sun from the Department of Chemistry, Faculty of Science at The University of Hong Kong (HKU), Professor Oscar P. Kuipers from the University of Groningen, Netherlands, Dr Rubén Cebrián from the San Cecilio University Hospital in Granada, Spain, and Professor Weihui Wu from Nankai University. Dr Yushan Xia served as the first author. The research team also included PhD students Xueying Wei and Chenyuan Wang, Research Assistant Professor Dr Hongyan Li from the Department of Chemistry at HKU; Assistant Professor Dr Peng Gao from the Faculty of Dentistry, HKU, and Professor Richard Yi-Tsun Kao from the Department of Microbiology at the Li Ka Shing Faculty of Medicine at HKU, along with Professor Weihui Wu from the Department of Microbiology at Nankai University. We would like to express our sincere gratitude to the Research Grants Council of Hong Kong SAR, the Health and Medical Research Fund of the Hong Kong Health Bureau, and the and Norman & Cecilia Yip Foundation of the University of Hong Kong for their generous support of this research. Figure 2. Professor Hongzhe Sun, Chair Professor of the Department of Chemistry at The University of Hong Kong (second from right), leads a dedicated team in the battle against superbugs. This team includes (from the left) Ms Chenyuan Wang, Ms Xueying Wei, Dr Yushan Xia and Dr Hongyan Li.   About Professor Hongzhe Sun Professor Hongzhe Sun is the Norman & Cecilia Yip Professor in Bioinorganic Chemistry and Chair Professor of Chemistry at HKU. His research focuses on metalloproteomics and metallomics, the discovery of antimicrobial agents, inorganic chemical biology and chemical biotechnology. Dr Hongyan Li is a Research Assistant Professor in the Department of Chemistry at HKU. The journal paper can be accessed here.  ‘Bismuth-based drugs sensitize Pseudomonas aeruginosa to multiple antibiotics by disrupting iron homeostasis’, Xia Y, Wei X, Li H, Cebrián R, Kuipers OP, Sun H et al, Nature Microbiology, 2024.

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HKU Delegation Explores New Educational Frontiers and Opportunities in Vietnam

  In a successful trip to Ho Chi Ming City, Vietnam, from September 25 to 29, 2024, the Faculty of Science, in partnership with the Faculty of Social Sciences, Admissions Office and Representative Office of HKU in Vietnam, has made strides in strengthening its global presence and unlocking potential opportunities in the Vietnamese education sector.   In a series of visits and events, the delegation started meaningful conversations with Vietnamese high school counsellors, potential students, and local organisations and institutions, sharing insights about HKU's world-class education. Through these dialogues, bridges that could lead to exciting collaborations and partnerships in the future were established.   The Open House event on September 28 was a key highlight, drawing an enthusiastic turnout of over 120 participants, including students, parents, teachers, and media personnel. Professor Qiang ZHOU, Dean of Science, highlighted the university's global standing, stating, ‘As the oldest tertiary institution in Hong Kong, HKU stands as a beacon of academic excellence and innovation.’     In the same vein, Professor Ming WEN, Dean of Social Science, accentuated HKU’s position at the forefront of global education and its esteemed reputation as an innovative educational hub. She noted, ‘HKU's ascending international ranking stands as a testimony to our dedication to academic excellence and research proficiency, solidifying our status as a globally recognised institution.’    Their remarks conveyed both Faculties' academic prowess and diverse opportunities available, tailored specifically to the aspirations of the Vietnamese audience. This event facilitated robust engagement with the local community, serving as a platform to showcase HKU’s commitment to academic excellence, dedication to fostering intellectual growth, and continuous efforts to shape the leaders of tomorrow.   Simultaneously, visits to local high schools provided an in-depth understanding of Vietnam’s educational landscape and the unique needs and preferences of Vietnamese students interested in science and social sciences-related fields. The delegation also engaged with the Vietnam National University (HCMC) and Fulbright University Vietnam, fostering dialogue and exchange of ideas on possible collaboration and best educational practices.    Courtesy visits to local organisations, such as the Chinese Embassy and the Department of Science and Technology, further solidified diplomatic and educational ties while providing insight into Vietnam's scientific, technological, and commercial landscapes.   This trip has opened doors to new collaborations and exchanges, highlighting the potential of the Vietnamese market. HKU Science remains committed to nurturing these invaluable connections, and holds an optimistic outlook towards the myriad of opportunities awaiting in this strategically significant landscape.    Professor Qiang ZHOU, Dean of Science   The Open House event on September 28th, attracting more than 120 participants   HKU delegation paying visit to the Chinese Embassy HKU delegation visiting the Vietnam National University HKU delegation visiting to the Sunwah Innovation Center

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The leadership team of the School of Computing and Data Science (CDS).

HKU Announces the Launch of New School of Computing and Data Science to Nurture Talent in AI and Data Science

The University of Hong Kong (HKU) announces the establishment of the new School of Computing and Data Science (CDS) to consolidate and advance education and research across the fields of computing and data science, artificial intelligence (AI), statistical decision sciences, fintech, and actuarial science. The new School of CDS combines the Department of Computer Science from the Faculty of Engineering and Department of Statistics and Actuarial Science from the Faculty of Science. It aims to take a truly integrated approach to reform these related academic disciplines, as well as foster multidisciplinary research collaboration within the University and beyond. Professor Richard WONG, Provost and Deputy Vice-Chancellor, said: ‘The rapid advancements in computing technology, data science, and artificial intelligence have the potential to offer groundbreaking solutions to numerous industrial, economic, and societal challenges. It is anticipated that the demand for new and top-tier talent in these fields will rise significantly in the future. Consequently, reforming education and fundamental research in computing and data science has become a priority and a trend among top universities worldwide. This initiative also aligns well with the strategic scientific and technological plans of Hong Kong and the nation. The University of Hong Kong is determined to seize this opportunity and tackle the associated challenges. By establishing the School of Computing and Data Science, HKU aims to create synergies that will position it as a leader in transforming Hong Kong into an international hub for education and research in computing and data science.’ Professor Yi MA, Chair Professor of Artificial Intelligence, has been appointed the inaugural Director of the School of CDS. ‘By converging computing, data science, and statistics, the School of CDS aims to foster a vibrant academic community that drives innovative education, promotes multidisciplinary research, and facilitates technological innovation. It will transform education in computer science, data science, and artificial intelligence, incubating future leaders who are well-versed in these new knowledge and technology,’ said Professor Ma. Formally established on 1 July 2024, the School of CDS will admit students directly starting from the academic year 2025-26, offering eight undergraduate programmes in total. Besides revamping its flagship programme, the Bachelor of Engineering in Computer Science, the School plans to introduce a new programme, the Bachelor of Engineering in Artificial Intelligence and Data Science, which is designed to be a standalone or AI+X double degree programme. Furthermore, the School of CDS will be the home department to offer AI literacy micro-credentials for all incoming HKU undergraduate students from 2025/26. The School will also offer three new professional degrees, namely the Bachelor of Science in Decision Analytics, Risk Management, and Statistics programmes respectively. Current undergraduate students reading the existing programmes will continue their studies without being affected by the transition. For postgraduate education, new programmes will be designed in close collaboration with industry partners to cater to market needs. To mark the establishment of the School of CDS, an opening ceremony will be held on October 24 (Thursday). The ceremony will be officiated by esteemed guests, followed by keynote lectures featuring distinguished speakers.   Photo Caption: The leadership team of the School of Computing and Data Science (CDS) includes Director Professor Yi MA (front row, centre); Associate Directors Professor Tak-Wah LAM (front row, left), Professor Stephen LEE (back row, 2nd from right), Professor Siu-Ming YIU (back row, 1st from right), Professor Yizhou YU (back row, 1st from left), Professor Guosheng YIN (back row, 2nd from left); and Division Heads Professor Reynold CHENG (back row, centre) and Professor KC CHEUNGow, right

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From the left: Dr Ruihua Zhang, Professor Fraser Stoddart and Dr Chun Tang from HKU Department of Chemistry.

HKU Chemists Develop Organic Supramolecular Crystals with High Hydrogen Storage Performance Promising to Enhance the Efficiency of Fuel Cell Vehicles

Hydrogen is often seen as the fuel of the future on account of its zero-emission and high gravimetric energy density, meaning it stores more energy per unit of mass compared to gasoline. Its low volumetric density, however, means it takes up a large amount of space, posing challenges for efficient storage and transport. In order to address these deficiencies, hydrogen must be compressed in tanks to 700-bar pressure, which is extremely high. This situation not only incurs high costs but also raises safety concerns. For hydrogen-powered fuel-cell vehicles (FCVs) to become widespread, the US Department of Energy (DOE) has set specific targets for hydrogen storage systems: 6.5% of the storage material’s weight should be hydrogen (gravimetric storage capacity of 6.5 wt%), and one litre of storage material should hold 50 grams of hydrogen (a volumetric storage capacity of 50 g L‒1). These targets ensure that vehicles can travel reasonable distances without excessive fuel. One promising strategy to achieve these targets is to develop porous adsorbent materials, such as metal-organic frameworks (MOFs), covalent organic frameworks (COFs), and porous organic polymers (POPs). All these materials share a common feature: they possess a porous structure that allows them to effectively trap and store hydrogen gas. This approach also aims to facilitate hydrogen storage at lower pressure, such as within 100 bar. Despite advancements in surpassing the DOE’s gravimetric target, many adsorbent materials still struggle to meet volumetric capacity needs, and few can balance both volumetric and gravimetric targets. From an industrial standpoint, volumetric capacity is more crucial than gravimetric capacity, as vehicle storage tanks have limited space. A hydrogen storage system’s volume directly impacts the driving range of FCVs. Therefore, developing hydrogen adsorbents that maximise volumetric capacity while maintaining excellent gravimetric capacity is essential. Achieving this goal involves balancing a high volumetric and gravimetric surface area within the same material. Researchers are investigating various materials for hydrogen storage, with organic supramolecular crystals assembly from organic molecules through noncovalent interactions, being a promising option as a result of their recyclability. Their potential remains largely untapped, however, because designing supramolecular crystals with balanced high gravimetric and volumetric surface areas, while maintaining stability, is difficult. A phenomenon known as catenation, which involves mechanically interlocked networks in porous materials, typically enhances stability. Catenation, however, often reduces surface area by blocking accessible surfaces, making the material less porous and generally undesirable for hydrogen storage. Efforts are usually made to minimise or avoid it. To unlock the potential of supramolecular crystals for hydrogen storage, a collaborative research team led by Professor Fraser STODDART, along with Research Assistant Professors, Dr Chun TANG, Dr Ruihua ZHANG from the Department of Chemistry, The University of Hong Kong (HKU), and Professor Randall Snurr from the Department of Chemical and Biological Engineering, the Northwestern University, US, demonstrated a controlled ‘point-contact catenation strategy’. This innovative approach uses hydrogen bonds, the cross-section of which can be seen as a ‘point’, rather than the traditional [π···π] stacking which involves large ‘surface’ overlap, to guide catenation in a precise manner in supramolecular crystals. Based on this strategy, researchers create a well-organised framework that minimises surface loss caused by interpenetration and tailors the pore diameter (~1.2–1.9 nm) for optimal hydrogen storage. As a result, the research team obtained a supramolecular crystal with record-high gravimetric (3526 m2 g‒1) and balanced volumetric (1855 m2 cm‒3) surface areas among all the reported (supra)molecular crystals, in addition to high stability, whilst (i) bringing about excellent material-level volumetric capacity (53.7 g L‒1), (ii) balancing high gravimetric capacity (9.3 wt%) for hydrogen storage under practical pressure and temperature swing conditions (77 K/100 bar → 160 K/5 bar), and (iii) surpassing the DOE ultimate system-level targets (50 g L‒1 and 6.5 wt%) both volumetrically and gravimetrically, albeit at cryogenic temperatures. Innovative design Designing organic supramolecular crystals that balance high gravimetric and volumetric surface areas, while also maintaining high stability, is a momentous challenge, which has hindered its potential for many applications. The team, however, has proposed a point-contact catenation strategy that utilises point-contact interactions involving hydrogen bonding to minimise surface loss during catenation. This design strategy endows these supramolecular crystals with balanced high volumetric and gravimetric surface areas, high stability, and ideal pore sizes for hydrogen storage. This research unlocks the potential of organic supramolecular crystals as promising candidates for onboard hydrogen storage and highlights the potential of a directional catenation strategy in designing robust porous materials for applications. About the research team   The control point-contact catenation strategy, guided by hydrogen bonding endows supramolecular crystals with both high volumetric and gravimetric storage capacities for hydrogen. Image adapted from Zhang et al., 2024, Nature Chemistry. This research is a collaboration between Professor Fraser Stoddart and Research Assistant Professors Dr Chun Tang, Dr Ruihua Zhang from the Department of Chemistry (Faculty of Science, HKU) and Professor Randall Snurr’s team from the Department of Chemical and Biological Engineering (Northwestern University, United States). Research Assistant Professor Dr Ruihua Zhang, from Professor Stoddart’s team, led the design and synthesis of the highly catenated supramolecular crystals and is the first author of the article published recently in Nature Chemistry. Other HKU-affiliated researchers, including Drs Han Han, Guangcheng Wu, Yong Wu and Professor Aspen X.-Y. Chen, also made contributions to this research project. About the research paper: ‘R. Zhang; H. Daglar; C. Tang*; P. Li; L. Feng; H. Han; G. Wu; B. N. Limketkai; Y. Wu; S. Yang; Aspen X.-Y. Chen; C. L. Stern; C. D. Malliakas; R. Q. Snurr*; J. F. Stoddart*; Balancing Volumetric and Gravimetric Capacity for Hydrogen in Supramolecular Crystals. Nature Chemistry 2024’ The journal paper can be accessed from here: https://www.nature.com/articles/s41557-024-01622-w

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Symphony in the Concrete Jungle: Inspiring Stewards of Nature

‘By introducing our rich local biodiversity to a wide audience, we would like to establish a sense of pride among Hong Kong people while nurturing care for the diverse habitats and species that inhabit the city.’   BSc alumni (major in Ecology & Biodiversity) Mr Matt CHAN (Programme Manager) Mr Matthew CHENG (Founder)  Miss Melody KONG (Founder) Mr Anthony YEUNG (Founder) Miss Betty WOO (Founder)   In the heart of Hong Kong, a city often seen as a concrete jungle, the harmonious melody of environmental stewardship resonates, guided by a group of dedicated Ecology & Biodiversity graduates from the School of Biological Sciences. Through Little Woods Nature Education (Little Woods), they weave a connection between urban dwellers and the city's rich biodiversity, inspiring a new generation to become stewards of the environment. In an enlightening conversation with the environmental educators, including Melody, Anthony, Betty, Matthew, and Matt, we journeyed from the verdant campus of HKU to the blossoming vision of Little Woods Nature Education. Their story, an intertwining narrative of passion, innovation, and commitment, embodies a philosophy that transcends mere business operations.    Sowing Seeds of Love for Nature As natural educators, these Science graduates' journey into the captivating world of biodiversity began with a spark, an innate curiosity that drew them to explore the wonders of nature. As children, they were mesmerised by the beauty of life unfolding in nature documentaries, textbooks, and the hidden biodiversity of Hong Kong's urban landscape.    Their passion was nurtured through various avenues – from university coursework and local or overseas research opportunities to chance encounters with passionate peers who shared the same fervour for understanding the natural world. Their journey went far beyond studying the fascinating relationships between organisms and their environment; it was also about cultivating an appreciation for the delicate balance sustaining life on Earth. As Melody put it, ‘The more I learned, the more I became aware of how much I don't know! This motivates me to keep exploring.’   Contributing to the Local Environmental Education Landscape With an aim to inspire appreciation for nature by transforming the intricate language of sustainability into an engaging dialogue for the public, Little Woods organises immersive activities like creating habitats for local species, identifying plants, and exploring the significance of wetland ecosystems. Anchored in their vision of inspiring reflection on personal lifestyles and their impacts on nature, these educators draw from their university experiences to develop interactive workshops and field trips. As Anthony reflects on his time at HKU, ‘The field trips I participated in during my undergraduate study have provided me with valuable knowledge of local biodiversity and demonstration skills in eco-tour.’ These experiences not only provided them with a solid understanding of ecological principles but also equipped them with the skills to effectively communicate these complex concepts.     Their dedication to making complex ecological concepts accessible has led them to employ innovative teaching strategies like gamification and storytelling. ‘Through gamification, we incorporate ecological concepts into gameplay, making the learning experience enjoyable for all participants,’ one founder explained. Specifically, their focus on explaining the 'why' behind certain behaviours or phenomena echoes their experiences at HKU, where they were instilled with an inquisitive mindset and unique approaches to researching and presenting the work. By balancing scientific rigour with engaging content, they captivate the audience and shed light on the intricacy of nature in which we all play a part.   This inspiring pursuit has also faced challenges, especially engaging audiences not initially drawn to ecology. ‘One strategy we have used is to promote environmental education as a means of developing soft skills like observation, inquisitiveness, or empathy,’ they shared. Their efforts have yielded fruitful results, particularly in their work with students with special educational needs (SEN), who exhibit increased engagement and expressiveness in natural settings.   Cultivating Tomorrow's Environmental Stewards As graduates in Ecology & Biology, the founders and operators of Little Woods are passionate about moulding the environmental guardians of tomorrow. Their unwavering commitment to remaining at the forefront of the latest research in ecology and biodiversity breathes life into their educational programmes, ensuring relevance and engagement.   Looking ahead, they envisage synergistic collaborations with diverse organisations to widen their reach and deepen their impact. ‘We have found collaboration inspiring and enriching, as working with individuals from varied backgrounds has provided us with valuable new perspectives and insights,’ revealed a founder. By unveiling the richness of local biodiversity to a broad audience, they aim to instil a sense of pride and stewardship for the diverse habitats and species that call Hong Kong home.   The echoes of Little Woods in the hearts and minds of individuals, communities, and the environment highlight the transformative power of environmental education. These natural educators credit their time at HKU Science for nurturing their passion and dedication to making a difference. As Melody advises current Science students, ‘Follow your passion and use your knowledge to create positive change.’   With the seeds of ecological love nurtured by Little Woods, the future of Hong Kong promises to be greener, and its song of nature, louder. The breeze whispers: ‘Nature's realm, vast and wide, a classroom without walls or pride, earth and sky, woods and streams, mountains and sea, all our teachers in our dreams.’   Video Sharing   Website Little Woods Nature Education   

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New research led by Dr Kohen Bauer, who began the research at HKU Earth Sciences, examines the climate ‘tipping point’ for ocean deoxygenation.

Ancient Volcanic Emissions Reveal a Climate ‘Tipping Point’ for Ocean Deoxygenation

A recent study published in Nature, led by Dr Kohen BAUER, reveals that massive volcanic CO2 emissions over 120 million years ago contributed to a severe global ocean deoxygenation event, with modern implications for understanding climate warming ‘tipping points’. Dr Bauer, now the Director of Science at Ocean Networks Canada, began this research as a Postdoctoral Fellow in Professor Ryan MCKENZIE's group at the Department of Earth Sciences, The University of Hong Kong (HKU) and completed it at the University of Victoria (UVic). The paper titled ‘A Climate Threshold for Ocean Deoxygenation during the Early Cretaceous’ reconstructs historical Earth-system processes to establish a climate warming threshold that, when crossed, leads to widespread and persistent ocean deoxygenation. Collaborated with PhD student C. CHEUNG and Research Assistant Professor Dr A. NORDSVAN of McKenzie's group at HKU Department of Earth Sciences, the team utilised extensive high-resolution data generated in the analytical facilities at HKU. This effort extends ongoing collaborative work aimed at understanding the mechanisms responsible for ancient changes in Earth's surface environment, particularly the relationship between changes in tectonic processes, climate, and ocean chemistry at various spatial and temporal scales.   Insights from Ancient Sedimentary Rocks The research team led by Bauer reconstructed environmental conditions using rock samples from the University of Milan archive. The sedimentary rocks studied date back between 115 and 130 million years and were originally deposited in the ancient oceans. By measuring the geochemical composition of the rocks, the team produced a unique high-resolution record of environmental change. ‘Our work shows that massive volcanic carbon emissions led to a rapid increase in atmospheric CO2 concentrations and the crossing of a climate-warming threshold, or tipping point, that resulted in widespread ocean deoxygenation. Following this, Earth's climate system then remained in a warmed state for over two million years,’ says Bauer. Forecasted climate scenarios for the next few hundred years suggest that significant warming may emerge as a result of rising human-generated CO2 emissions. Today, widespread climate warming-induced deoxygenation of the oceans is already being observed and is expected to intensify in the absence of climate change mitigation solutions. ‘If current CO2 emissions cause the climate system to approach and cross the threshold for ocean deoxygenation, we may expect the severity of global ocean anoxia to have huge implications for species, ecosystem and human health,’ says Bauer. The research team noted that it was a natural process that eventually restored oxygen to Earth's ancient oceans—but the recovery took over a million years. ‘We see that reoxygenation of the oceans was only possible once CO2 concentrations were drawn back down below this critical threshold, due to a natural climate feedback—silicate rock weathering, Earth's main mechanism for stabilising climate over longer periods of time,’ says Bauer. The rock weathering feedback is a key component of the Earth's long-term carbon cycle and stabilises the climate by regulating atmospheric CO2 levels. The paper concludes that this natural mechanism eventually lowered atmospheric carbon levels below the tipping point, resulting in rapid reoxygenation of the oceans after a prolonged period of sustained warming. ‘Empirical constraints from Earth’s past provide important context through which the relationships between climate warming, ocean deoxygenation, and the broader impacts on the biosphere can be explored,’ says Sean CROWE, a senior author on the research paper and Professor in the departments of Microbiology and Immunology and Earth, Ocean, and Atmospheric Sciences at the University of British Columbia. Professor Ryan McKenzie in the volcanically active caldera of Mt. Ijen in southern Java, Indonesia. Professor Ryan McKenzie of the HKU Department of Earth Sciences emphasised that understanding ancient climate dynamics is vital for predicting the effects of human CO2 emissions. Dr Bauer's data shows the recovery lag after volcanic CO2 emissions caused oceanic anoxia. Unlike ancient events, today's human emissions far exceed natural volcanic rates, highlighting the difficulty of recovery after crossing climatic thresholds. Related work recently published in Nature Ecology and Evolution similarly argues that aquatic deoxygenation represents a critical planetary boundary and is a key regulator of current and future Earth system stability with thresholds that should not be crossed. More information on ocean deoxygenation and its impacts can be found through the UNESCO Global Ocean Oxygen Network (GO2NE). Real-time oxygen concentrations in the Northeast Pacific Ocean can be accessed through Ocean Networks Canada's data portal system, Ocean 3.0. Ocean Networks Canada Ocean Networks Canada (ONC) operates world-leading observatories in the deep ocean and coastal waters of the Pacific, Atlantic, and Arctic coasts of Canada as well as the Southern Ocean, collecting ocean data that accelerates scientific discovery and makes possible services and solutions for a resilient planet. ONC's cabled observatories supply continuous power and Internet connectivity to scientific instruments, cameras, and 12,000-plus ocean sensors. ONC also operates mobile and land-based assets, including coastal radar. ONC is an initiative of the University of Victoria and is funded by the Canada Foundation for Innovation and the Government of Canada. The journal paper can be accessed from here.  Click here for more information about HKU Department of Earth Sciences. 

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