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Research summary
We design bionic units that mimic specific biological functions and/or introduce operations that do not exist in Nature. We apply a constructionist approach where we mimic biological complexity in the form of design principles to produce functional units from simple building blocks and their interactions. We called this Molecular Bionics. Such an effort is multidisciplinary and involves inputs from Chemistry, Physics, Material Science and Engineering from one side and Cell and Molecular Biology, Physiology, Immunology, Oncology and Neuroscience from the other side.
From the physical science side, we are engaged in several activities of synthesis and characterisation of novel hierarchal materials whose properties are the result of the holistic combination of its components. We combine synthetic and supramolecular chemistry to tune inter/intramolecular interactions and self-assembly processes to form dynamic soft materials whose molecular, supramolecular and mesoscale structures are tuned and fit for the final application (Molecular Engineering). These materials are often designed to interact with living systems and thus its biological activity is studied in high details. We have, indeed, developed and established new methodologies to study living systems and how synthetic materials interact with them combining holistically physical and life sciences (Physical Biology). Both know-hows are applied together to study biological organisation and complexity creating synthetic surrogates that act as model system (Synthetic Biology) as well as to engineer novel sophisticated ways to interact with complex living organism with the final aim to explore its interior. In analogy to medical Bionics, where engineering and physical science converge to the design of replacement and/or enhancement of malfunctioning body parts, we take inspiration from viruses, trafficking vesicles and exosomes to apply molecular engineering to create nanoscopic carriers that can navigate the human body (Nanomedicine) with the final aim to improve drug delivery or create new diagnostic tools.
We design bionic units that mimic specific biological functions and/or introduce operations that do not exist in Nature. We apply a constructionist approach where we mimic biological complexity in the form of design principles to produce functional units from simple building blocks and their interactions. We called this Molecular Bionics. Such an effort is multidisciplinary and involves inputs from Chemistry, Physics, Material Science and Engineering from one side and Cell and Molecular Biology, Physiology, Immunology, Oncology and Neuroscience from the other side.
From the physical science side, we are engaged in several activities of synthesis and characterisation of novel hierarchal materials whose properties are the result of the holistic combination of its components. We combine synthetic and supramolecular chemistry to tune inter/intramolecular interactions and self-assembly processes to form dynamic soft materials whose molecular, supramolecular and mesoscale structures are tuned and fit for the final application (Molecular Engineering). These materials are often designed to interact with living systems and thus its biological activity is studied in high details. We have, indeed, developed and established new methodologies to study living systems and how synthetic materials interact with them combining holistically physical and life sciences (Physical Biology). Both know-hows are applied together to study biological organisation and complexity creating synthetic surrogates that act as model system (Synthetic Biology) as well as to engineer novel sophisticated ways to interact with complex living organism with the final aim to explore its interior. In analogy to medical Bionics, where engineering and physical science converge to the design of replacement and/or enhancement of malfunctioning body parts, we take inspiration from viruses, trafficking vesicles and exosomes to apply molecular engineering to create nanoscopic carriers that can navigate the human body (Nanomedicine) with the final aim to improve drug delivery or create new diagnostic tools.
研究兴趣
论文共 265 篇作者统计合作学者相似作者
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Junyang Chen, Xiang Pan,Aroa Duro-Castano,Huawei Cai, Bin Guo,Xiqin Liu,Yifan Yu,Su Lui,Kui Luo, Bowen Ke,Lorena Ruiz Perez,Xiawei Wei,Qiyong Gong,Xiaohe Tian,Giuseppe Battaglia
crossref(2024)
Ibrain (2024)
Biomacromoleculesno. 9 (2024): 5454-5467
Akhil Venugopal, Subhadip Ghosh, Annalisa Calo, Gian Marco Tuveri, Zhendong Xie,Giuseppe Battaglia, Mohit Kumar
crossref(2024)
Carla Garcia-Cabau,Anna Bartomeu,Giulio Tesei, Kai Chit Cheung,Julia Pose-Utrilla,Sara Picó, Andreea Balaceanu, Berta Duran-Arqué,Marcos Fernández-Alfara,Judit Martín,Cesare De Pace,Lorena Ruiz-Pérez,Jesús García,Giuseppe Battaglia,José J. Lucas,Rubén Hervás,Kresten Lindorff-Larsen,Raúl Méndez,Xavier Salvatella
biorxiv(2024)
Mingzhu Zhang, Shaoqi Zhong, Lujing An, Pan Xiang,Na Hu, Wei Huang,Yupeng Tian,Giuseppe Battaglia,Xiaohe Tian,Min Wu
BIOMATERIALS RESEARCH (2024)
Ibrainno. 3 (2024): 266-289
Macromolecular bioscienceno. 8 (2023)
BIOPHYSICS REVIEWSno. 4 (2023): 041306-041306
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作者统计
#Papers: 266
#Citation: 11179
H-Index: 55
G-Index: 101
Sociability: 7
Diversity: 0
Activity: 2
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