Relevant bibliographies by topics / Nanoroboter

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'Nanoroboter'

Author: Grafiati
Published: 4 June 2021
Last updated: 6 February 2022

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Journal articles on the topic "Nanoroboter"

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Müller, Thomas. "Bakterielle Nanoroboter für die Krebstherapie." Info Onkologie 19, no. 7 (November 2016): 27. http://dx.doi.org/10.1007/s15004-016-5474-x.

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Sengupta, Samudra, Michael E. Ibele, and Ayusman Sen. "Die phantastische Reise: Nanoroboter mit Eigenantrieb." Angewandte Chemie 124, no. 34 (August 7, 2012): 8560–71. http://dx.doi.org/10.1002/ange.201202044.

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Xie, Jiaying, Yiliang Jin, Kelong Fan, and Xiyun Yan. "The prototypes of nanozyme-based nanorobots." Biophysics Reports 6, no. 6 (November 20, 2020): 223–44. http://dx.doi.org/10.1007/s41048-020-00125-8.

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AbstractArtificial nanorobot is a type of robots designed for executing complex tasks at nanoscale. The nanorobot system is typically consisted of four systems, including logic control, driving, sensing and functioning. Considering the subtle structure and complex functionality of nanorobot, the manufacture of nanorobots requires designable, controllable and multi-functional nanomaterials. Here, we propose that nanozyme is a promising candidate for fabricating nanorobots due to its unique properties, including flexible designs, controllable enzyme-like activities, and nano-sized physicochemical characters. Nanozymes may participate in one system or even combine several systems of nanorobots. In this review, we summarize the advances on nanozyme-based systems for fabricating nanorobots, and prospect the future directions of nanozyme for constructing nanorobots. We hope that the unique properties of nanozymes will provide novel ideas for designing and fabricating nanorobotics.
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Zhao, Qingying, Min Li, Jun Luo, Hanqing Wang, and Jinge Cao. "Approaching Tumor Tissue in Local Blood Vessel for Targeted Drug Delivery by Nanorobots." Journal of Computational and Theoretical Nanoscience 13, no. 10 (October 1, 2016): 6654–61. http://dx.doi.org/10.1166/jctn.2016.5611.

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This paper describes a nanorobot control algorithm designed for approaching tumor tissue in local blood vessel for targeted drug delivery. The algorithm coordinates nanorobots’ movements through use of two types of chemical molecules, an acoustic signal and velocity characteristic of blood fluid. After detecting the chemical molecules released by cancer cells, a nanorobot moves toward the area of higher concentration of the molecule and releases another chemical molecule which alerts others to aggregate to the target. When nanorobots detect acoustic signals emitted by nanorobots reaching target, their paths will be planned according to intensity of acoustic signals and velocity characteristic of blood fluid. The simulations show that compared with the existed approaches, the proposed algorithm results in an increase of nanorobots’ population and a decrease of cost time to reach target site with the help of acoustic signals and velocity characteristic. As a whole, the results obtained suggest that the algorithm presented in this paper is a better strategy for approaching tumor tissue in local blood vessel by nanorobots.
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Wang, Hao, Jiacheng Kan, Xin Zhang, Chenyi Gu, and Zhan Yang. "Pt/CNT Micro-Nanorobots Driven by Glucose Catalytic Decomposition." Cyborg and Bionic Systems 2021 (August 6, 2021): 1–8. http://dx.doi.org/10.34133/2021/9876064.

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Swimming micro-nanorobots have attracted researchers’ interest in potential medical applications on target therapy, biosensor, drug carrier, and others. At present, the experimental setting of the swimming micro-nanorobots was mainly studied in pure water or H2O2 solution. This paper presents a micro-nanorobot that applied glucose in human body fluid as driving fuel. Based on the catalytic properties of the anode and cathode materials of the glucose fuel cell, platinum (Pt) and carbon nanotube (CNT) were selected as the anode and cathode materials, respectively, for the micro-nanorobot. The innovative design adopted the method of template electrochemical and chemical vapor deposition to manufacture the Pt/CNT micro-nanorobot structure. Both the scanning electron microscope (SEM) and transmission electron microscope (TEM) were employed to observe the morphology of the sample, and its elements were analyzed by energy-dispersive X-ray spectroscopy (EDX). Through a large number of experiments in a glucose solution and according to Stoker’s law of viscous force and Newton’s second law, we calculated the driving force of the fabricated micro-nanorobot. It was concluded that the structure of the Pt/CNT micro-nanorobot satisfied the required characteristics of both biocompatibility and motion.
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Muthukumaran, G., U. Ramachandraiah, and D. G. Harris Samuel. "Role of Nanorobots and their Medical Applications." Advanced Materials Research 1086 (February 2015): 61–67. http://dx.doi.org/10.4028/www.scientific.net/amr.1086.61.

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Nanorobotics is the technology of creating robots at nanoscale. Specifically, nanorobotics refers to the hypothetical nanotechnology engineering discipline of designing and building nanorobots, devices ranging in size from 0.1-10 micrometers and constructed of molecular components. On this concept of artificial non-biological nanorobots, many research centers are performing the research activities. The names nanobots, nanoids, nanites or nanomites have also been used to describe these hypothetical devices. They are applied in advanced medical applications like diagnosis and treatment of diabetes, early detection and treatment of cancer, cellular nonosurgery and genetherapy. A few generations from now someone diagnosed with cancer might be offered a new alternative to chemotherapy. A doctor practicing nanomedicine of chemotherapy would offer the patient an injection of a special type of nanorobot that would seek out cancer cells and destroy them, dispelling the disease at the source, leaving healthy cells untouched unlike the traditional treatment of radiation that kills not only cancer cells but also healthy human cells. Radiation treatment may also cause hair loss, fatigue, nausea, depression, and a host of other symptoms. Thus in nanorobotics, the extent of the hardship to the patient would essentially be a prick to the arm. A person undergoing a nanorobotic treatment could expect to have no awareness of the molecular devices working inside them, other than rapid betterment of their health. A major advantage that nanorobots provide is durability, as they could last for years. The operation time would also be much lower because their displacements are smaller. Hence reduced material costs, accessibility to previously unreachable areas are the motivating factors. Thus our review explains that the designing and testing of primitive devices and their potential applications promise rich benefits for patients, medical personal, engineers, and scientists.
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Mandal, T. K., and V. Patait. "Utilization of Nanomaterials in Target Oriented Drug Delivery Vehicles." Journal of Scientific Research 13, no. 1 (January 1, 2021): 299–316. http://dx.doi.org/10.3329/jsr.v13i1.47690.

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The present investigation deals with the fundamentals of nanorobots, its fabrication, and possible utilization in a different target-oriented drug delivery vehicles. Details of various types of nanorobots and their specific applications are studied in this research. The use of nanorobots in cancer treatment, target-oriented drug delivery, medical imaging, and in new health sensing devices has also been studied. The mechanism of action of nanorobots for the treatment of cancerous cells as well as the formulation and working functions of some recently studied nanorobots are investigated in this work. This paper reviews the research in finding the suitable nanorobotic materials, different fabrication processes of nanorobots, and the current status of application of nanorobots in biomedical, especially in the treatment of cancers. Superparamagnetic iron oxide nanoparticles (SPIONs) have been observed to be used as novel drug delivery vehicle materials. The future perspectives of nanorobots for the utilization in drug delivery are also addressed herewith.
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Mandal, T. K., and V. Patait. "Utilization of Nanomaterials in Target Oriented Drug Delivery Vehicles." Journal of Scientific Research 13, no. 1 (January 1, 2021): 299–316. http://dx.doi.org/10.3329/jsr.v13i1.47690.

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The present investigation deals with the fundamentals of nanorobots, its fabrication, and possible utilization in a different target-oriented drug delivery vehicles. Details of various types of nanorobots and their specific applications are studied in this research. The use of nanorobots in cancer treatment, target-oriented drug delivery, medical imaging, and in new health sensing devices has also been studied. The mechanism of action of nanorobots for the treatment of cancerous cells as well as the formulation and working functions of some recently studied nanorobots are investigated in this work. This paper reviews the research in finding the suitable nanorobotic materials, different fabrication processes of nanorobots, and the current status of application of nanorobots in biomedical, especially in the treatment of cancers. Superparamagnetic iron oxide nanoparticles (SPIONs) have been observed to be used as novel drug delivery vehicle materials. The future perspectives of nanorobots for the utilization in drug delivery are also addressed herewith.
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Hu, Mengyi, Xuemei Ge, Xuan Chen, Wenwei Mao, Xiuping Qian, and Wei-En Yuan. "Micro/Nanorobot: A Promising Targeted Drug Delivery System." Pharmaceutics 12, no. 7 (July 15, 2020): 665. http://dx.doi.org/10.3390/pharmaceutics12070665.

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Micro/nanorobot, as a research field, has attracted interest in recent years. It has great potential in medical treatment, as it can be applied in targeted drug delivery, surgical operation, disease diagnosis, etc. Differently from traditional drug delivery, which relies on blood circulation to reach the target, the designed micro/nanorobots can move autonomously, which makes it possible to deliver drugs to the hard-to-reach areas. Micro/nanorobots were driven by exogenous power (magnetic fields, light energy, acoustic fields, electric fields, etc.) or endogenous power (chemical reaction energy). Cell-based micro/nanorobots and DNA origami without autonomous movement ability were also introduced in this article. Although micro/nanorobots have excellent prospects, the current research is mainly based on in vitro experiments; in vivo research is still in its infancy. Further biological experiments are required to verify in vivo drug delivery effects of micro/nanorobots. This paper mainly discusses the research status, challenges, and future development of micro/nanorobots.
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Yu, Hao, Wentian Tang, Guanyu Mu, Haocheng Wang, Xiaocong Chang, Huijuan Dong, Liqun Qi, Guangyu Zhang, and Tianlong Li. "Micro-/Nanorobots Propelled by Oscillating Magnetic Fields." Micromachines 9, no. 11 (October 23, 2018): 540. http://dx.doi.org/10.3390/mi9110540.

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Recent strides in micro- and nanomanufacturing technologies have sparked the development of micro-/nanorobots with enhanced power and functionality. Due to the advantages of on-demand motion control, long lifetime, and great biocompatibility, magnetic propelled micro-/nanorobots have exhibited considerable promise in the fields of drug delivery, biosensing, bioimaging, and environmental remediation. The magnetic fields which provide energy for propulsion can be categorized into rotating and oscillating magnetic fields. In this review, recent developments in oscillating magnetic propelled micro-/nanorobot fabrication techniques (such as electrodeposition, self-assembly, electron beam evaporation, and three-dimensional (3D) direct laser writing) are summarized. The motion mechanism of oscillating magnetic propelled micro-/nanorobots are also discussed, including wagging propulsion, surface walker propulsion, and scallop propulsion. With continuous innovation, micro-/nanorobots can become a promising candidate for future applications in the biomedical field. As a step toward designing and building such micro-/nanorobots, several types of common fabrication techniques are briefly introduced. Then, we focus on three propulsion mechanisms of micro-/nanorobots in oscillation magnetic fields: (1) wagging propulsion; (2) surface walker; and (3) scallop propulsion. Finally, a summary table is provided to compare the abilities of different micro-/nanorobots driven by oscillating magnetic fields.
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Dissertations / Theses on the topic "Nanoroboter"

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Diez, Stefan, and Jonathon Howard. "Nanotechnological applications of biomolecular motor systems." Saechsische Landesbibliothek- Staats- und Universitaetsbibliothek Dresden, 2008. http://nbn-resolving.de/urn:nbn:de:bsz:14-ds-1223724473713-41365.

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Neuerliche Fortschritte im Verständnis biomolekularer Motoren rücken ihre Anwendung als Nanomaschinen in den Bereich des Möglichen. So könnten sie zum Beispiel als Nanoroboter arbeiten, um in molekularen Fabriken kleine – aber dennoch komplizierte – Strukturen auf winzigen Förderbändern herzustellen, um Netzwerke molekularer Nanodrähte und Transistoren für elektronische Anwendungen zu assemblieren oder sie könnten in adaptiven Materialien patrouillieren und diese, wenn nötig, reparieren. In diesem Sinne besitzen biomolekulare Motoren das Potenzial, die Basis für die Konstruktion, Strukturierung und Wartung nanoskaliger Materialien zu bilden
Recent advances in understanding how biomolecular motors work have raised the possibility that they might find applications as nanomachines. For example, they could be used as molecule- sized robots that work in molecular factories where small, but intricate structures are made on tiny assembly lines, that construct networks of molecular conductors and transistors for use as electrical circuits, or that continually patrol inside “adaptive” materials and repair them when necessary. Thus biomolecular motors could form the basis of bottom-up approaches for constructing, active structuring and maintenance at the nanometer scale
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Wortmann, Tim [Verfasser]. "Automatic Image Analysis in Micro- and Nanorobotic Environments / Tim Wortmann." München : Verlag Dr. Hut, 2012. http://d-nb.info/1024242927/34.

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Bartenwerfer, Malte [Verfasser]. "Automation Capabilities in the Nanorobotic Handling of Nanomaterials / Malte Bartenwerfer." München : Verlag Dr. Hut, 2019. http://d-nb.info/117625099X/34.

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Kratochvil, Bradley E. "Visual tracking for nanorobotic manipulation and 3D reconstruction in an electron microscope /." Zürich : ETH, 2008. http://e-collection.ethbib.ethz.ch/show?type=diss&nr=17953.

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Eichhorn, Volkmar [Verfasser]. "Nanorobotic handling and characterization of carbon nanotubes inside the scanning electron microscope / Volkmar Eichhorn." München : Verlag Dr. Hut, 2011. http://d-nb.info/1011441667/34.

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Tan, Ning. "Calibration of micro and nanorobotic systems : Contribution of influential parameters to the geometric accuracy." Phd thesis, Université de Franche-Comté, 2013. http://tel.archives-ouvertes.fr/tel-01025313.

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Une des conditions fondamentales de la performance des système repose sur leur capacité à généré des déplacement avec précision de positionnement élevée. Cependant, à l'échelle micrométrique, de nombreux paramètres agissent et réduisent cette précision. A cette échelle, il est également particulièrement complexe de mesurer la précision de positionnement d'un système micro ou nanorobotique et donc d'identifier les différentes sources d'imprécision. L'étalonnage géométrique des systèmes micro et nanorobotiques prenant en compte ces différents sources est rarement étudié. Pour ces raisons, l'originalité et les contribution de cette thèse portent sur deux aspects principaux (i) la caractérisation des perperformances des systèmes micro et nanorobotiques et l'analyse des paramètres affectant leur précision de positionnement (ii) l'amélioration des performances de ces robots fondés sur différents types de modèles robotiques.
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Sanchez, Samuel, Alexander A. Solovev, Sabine Schulze, and Oliver G. Schmidt. "Controlled manipulation of multiple cells using catalytic microbots." Saechsische Landesbibliothek- Staats- und Universitaetsbibliothek Dresden, 2014. http://nbn-resolving.de/urn:nbn:de:bsz:14-qucosa-138608.

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Self-propelled microjet engines (microbots) can transport multiple cells into specific locations in a fluid. The motion is externally controlled by a magnetic field which allows to selectively load, transport and deliver the cells
Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich
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Sanchez, Samuel, Alexander A. Solovev, Sabine Schulze, and Oliver G. Schmidt. "Controlled manipulation of multiple cells using catalytic microbots." Royal Society of Chemistry, 2011. https://tud.qucosa.de/id/qucosa%3A27763.

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Self-propelled microjet engines (microbots) can transport multiple cells into specific locations in a fluid. The motion is externally controlled by a magnetic field which allows to selectively load, transport and deliver the cells.
Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.
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Marras, Alexander Edison. "DNA Origami Mechanisms and Machines." The Ohio State University, 2013. http://rave.ohiolink.edu/etdc/view?acc_num=osu1366227349.

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Sahu, Sudheer. "DNA Based Self-Assembly and Nanorobotic : theory and experiments." Diss., 2007. http://hdl.handle.net/10161/443.

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Books on the topic "Nanoroboter"

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author, Li Guangyong joint, ed. Introduction to nanorobotic manipulation and assembly. Boston: Artech House, 2012.

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Fukuda, Toshio, Fumihito Arai, and Masahiro Nakajima. Micro-Nanorobotic Manipulation Systems and Their Applications. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-36391-7.

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Fukuda, Toshio. Micro-Nanorobotic Manipulation Systems and Their Applications. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013.

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Hamdi, Mustapha. Design, Modeling and Characterization of Bio-Nanorobotic Systems. Dordrecht: Springer Science+Business Media B.V., 2011.

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Hamdi, Mustapha, and Antoine Ferreira. Design, Modeling and Characterization of Bio-Nanorobotic Systems. Dordrecht: Springer Netherlands, 2011. http://dx.doi.org/10.1007/978-90-481-3180-8.

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Perkins, E. J. Nanorobots and the Hunt for H1no1. Dog Ear Publishing, LLC, 2011.

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Fukuda, Toshio, Fumihito Arai, and Masahiro Nakajima. Micro-Nanorobotic Manipulation Systems and Their Applications. Springer, 2015.

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Fukuda, Toshio, Fumihito Arai, and Masahiro Nakajima. Micro-Nanorobotic Manipulation Systems and Their Applications. Springer, 2013.

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Hamdi, Mustapha, and Antoine Ferreira. Design, Modeling and Characterization of Bio-Nanorobotic Systems. Springer, 2010.

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Fukuda, Toshio, Masahiro Nakajima, Masaru Takeuchi, and Yasuhisa Hasegawa. Micro- and nanotechnology for living machines. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199674923.003.0052.

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The chapter Micro- and nanotechnology for living machines describes research on new biohybrid technologies, engineered at the micro- and nano-scales, that combine some of the benefits of mechanical and electronic systems with those of biological systems. The chapter begins by reviewing some of the challenges of building devices at very small physical scales and discusses how new fabrication methodologies could impact on different classes of industrial, daily life, and biomedical products. We next explain how progress is being achieved through advances in micro- and nanomechatronics, particularly in the field of nanorobotic manipulation. Finally, we summarize recent progress towards building biohybrid living machines that combine nanomaterials with biological cells and outline the design of a micro- and nanorobotic manipulation system for cell assembly called the nanolaboratory.
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Book chapters on the topic "Nanoroboter"

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Yoda, Minami, Jean-Luc Garden, Olivier Bourgeois, Aeraj Haque, Aloke Kumar, Hans Deyhle, Simone Hieber, et al. "Nanorobotic Assembly." In Encyclopedia of Nanotechnology, 1692. Dordrecht: Springer Netherlands, 2012. http://dx.doi.org/10.1007/978-90-481-9751-4_100541.

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Nelson, Bradley J., Lixin Dong, and Fumihito Arai. "Micro-/Nanorobots." In Springer Handbook of Robotics, 671–716. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-32552-1_27.

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Nelson, Bradley J., Lixin Dong, and Fumihito Arai. "Micro/Nanorobots." In Springer Handbook of Robotics, 411–50. Berlin, Heidelberg: Springer Berlin Heidelberg, 2008. http://dx.doi.org/10.1007/978-3-540-30301-5_19.

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Wang, Xiaopu, and Bradley Nelson. "Micro-/Nanorobots." In Encyclopedia of Robotics, 1–11. Berlin, Heidelberg: Springer Berlin Heidelberg, 2021. http://dx.doi.org/10.1007/978-3-642-41610-1_145-1.

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Dong, Lixin, Xinyong Tao, Zheng Fan, Li Zhang, Xiaobin Zhang, Bradley J. Nelson, Mustapha Hamdi, and Antoine Ferreira. "Nanorobotic Mass Transport." In Nanorobotics, 137–53. New York, NY: Springer New York, 2012. http://dx.doi.org/10.1007/978-1-4614-2119-1_8.

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Yoda, Minami, Jean-Luc Garden, Olivier Bourgeois, Aeraj Haque, Aloke Kumar, Hans Deyhle, Simone Hieber, et al. "Nanorobotic Spot Welding." In Encyclopedia of Nanotechnology, 1692–700. Dordrecht: Springer Netherlands, 2012. http://dx.doi.org/10.1007/978-90-481-9751-4_229.

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Dong, Lixin, Xinyong Tao, Zheng Fan, Zhang Li, Xiaobin Zhang, and Bradley J. Nelson. "Nanorobotic Spot Welding." In Encyclopedia of Nanotechnology, 2632–40. Dordrecht: Springer Netherlands, 2016. http://dx.doi.org/10.1007/978-94-017-9780-1_229.

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Dong, Lixin, Li Zhang, Miao Yu, and Bradley J. Nelson. "Nanorobotic Manipulation of Helical Nanostructures." In Advanced Micro and Nanosystems, 477–503. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2015. http://dx.doi.org/10.1002/9783527690237.ch19.

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Fukuda, Toshio, and Masahiro Nakajima. "Nanobioscience Based on Nanorobotic Manipulation." In Control Technologies for Emerging Micro and Nanoscale Systems, 169–80. Berlin, Heidelberg: Springer Berlin Heidelberg, 2011. http://dx.doi.org/10.1007/978-3-642-22173-6_10.

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Yoda, Minami, Jean-Luc Garden, Olivier Bourgeois, Aeraj Haque, Aloke Kumar, Hans Deyhle, Simone Hieber, et al. "Nanorobotic Manipulation of Biological Cells." In Encyclopedia of Nanotechnology, 1692. Dordrecht: Springer Netherlands, 2012. http://dx.doi.org/10.1007/978-90-481-9751-4_100542.

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Conference papers on the topic "Nanoroboter"

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Ahmed, S., S. E. Amin, and T. Elarif. "Navigation and Cooperative Control for Nanorobots in the Bloodstream Environment Based on Swarm Intelligence." In ASME 2015 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2015. http://dx.doi.org/10.1115/detc2015-46506.

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In this paper, an innovative technique was tested to solve the path-planning problem of swarm nanorobots’ navigation within the human environment. Blood elements were treated as obstacles to nanorobot movement. Blood flow was also factored into the movement problem, as was the environment’s physical properties, including blood viscosity and density, both of which can potentially affect nanorobot behavior. To account for all these considerations in a human body environment, two algorithms were combined, yielding a single algorithm responsible for the self-organized control of nanorobots to avoid obstacles during their movement trajectory. The technique is based on modification of the Particle Swarm Optimization algorithm, referred to as the MPSO algorithm which is classified as a swarm intelligence algorithm, and modification of the Obstacle Avoidance Algorithm, referred to as the MOA algorithm. The proposed MPSO algorithm generated the best locations in a given operational area enabling nanorobots to detect the target areas. The proposed MOA algorithm allowed nanorobots to efficiently avoid collision with blood elements. The simulation results show that the combined MPSO-MOA algorithm safely routes all nanorobots past blood elements while navigating within the human body.
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Bharath, Sudharsan, M. Balaji, and G. R. Sai Krishna. "Future of NEMS." In ASME 2008 First International Conference on Micro/Nanoscale Heat Transfer. ASMEDC, 2008. http://dx.doi.org/10.1115/mnht2008-52239.

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Nanorobots are quintessential NEMS (nanoelectromechanical systems) and raise all the important issues that must be addressed in NEMS design: sensing, actuation, control, communications, power, and interfacing across spatial scales and between the organic/inorganic and biotic/abiotic realms. Nanorobots are expected to have evolutionary applications in such areas as environmental monitoring and health care. This paper begins by discussing nanorobot construction, which is still at an embryonic stage. The emphasis is on nanomachines, an area which has seen a spate of rapid progress over the last few years. Nanoactuators will be essential components of future NEMS. The paper’s focus then changes to nanoassembly by manipulation with scanning probe microscopes (SPMs), which is a relatively well established process for prototyping nanosystems. Prototyping of nanodevices and systems is important for design validation, parameter optimization and sensitivity studies. Nanomanipulation also has applications in repair and modification of nanostructures built by other means. High throughput SPM manipulation may be achieved by using multi tip arrays. Experimental results are presented which show that interactive SPM manipulation can be used to accurately and reliably position molecular-sized components. These can then be linked by chemical means to form subassemblies, which in turn can be further manipulated. Applications in building wires, single electron transistors and nanowaveguides are presented.
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Nelson, B. J. "Towards nanorobots." In TRANSDUCERS 2009 - 2009 International Solid-State Sensors, Actuators and Microsystems Conference. IEEE, 2009. http://dx.doi.org/10.1109/sensor.2009.5285633.

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Fan, Zheng, Xinyong Tao, Xiaobin Zhang, and Lixin Dong. "Nanorobotic mass transport." In 2012 IEEE 12th International Conference on Nanotechnology (IEEE-NANO). IEEE, 2012. http://dx.doi.org/10.1109/nano.2012.6322198.

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Stemmer, Andreas, and Markus Brunner. "Sensor-guided nanorobots." In Intelligent Systems & Advanced Manufacturing, edited by Armin Sulzmann. SPIE, 1998. http://dx.doi.org/10.1117/12.298040.

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Venkatesan, Mithra, and Bhuvaneshwari Jolad. "Nanorobots in cancer treatment." In 2010 International Conference on Emerging Trends in Robotics and Communication Technologies (INTERACT 2010). IEEE, 2010. http://dx.doi.org/10.1109/interact.2010.5706154.

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Nikitin, M. P. "Nanorobots for biomedical applications." In 2016 International Conference Laser Optics (LO). IEEE, 2016. http://dx.doi.org/10.1109/lo.2016.7549994.

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Vartholomeos, Panagiotis, Suleyman S. Aylak, and Constantinos Mavroidis. "Computational Studies of Controlled Nanoparticle Agglomerations for MRI-Guided Nanorobotic Drug-Delivery Systems." In ASME 2010 Dynamic Systems and Control Conference. ASMEDC, 2010. http://dx.doi.org/10.1115/dscc2010-4245.

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Abstract:
Magnetic Resonance Imaging (MRI) guided nanorobotic systems that could perform diagnostic, curative and reconstructive treatments in the human body at the cellular and sub-cellular level in a controllable manner have recently been proposed. The concept of a MRI-guided nanorobotic system is based on the use of a MRI scanner to induce the required external driving forces to guide magnetic nanocapsules to a specific target. However, the maximum magnetic gradient specifications of existing clinical MRI systems are not capable of driving superparamagnetic nanocapsules against the blood flow and therefore these MRIs do not allow for navigation. The present paper proposes a way to overcome this critical drawback through the formation of micron size agglomerations where their size can be regulated by external magnetic stimuli. This approach is investigated through modeling of the physics that govern the self-assembly of the nanoparticles. Additionally a computational tool has been developed that incorporates the derived models and performs simulation, visualization and post-processing analysis. Preliminary simulation results demonstrate that external magnetic field causes aggregation of nanoparticles while they flow in the vessel. This is a promising result — in accordance with similar experimental results — and encourages further investigation on the nanoparticle based self-assembly structures for use in nanorobotic drug delivery.
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Liu, Pou, Fumihito Arai, and Toshio Fukuda. "Nanorobotic Manipulator Controlled Nanowire Growth." In 2006 IEEE/RSJ International Conference on Intelligent Robots and Systems. IEEE, 2006. http://dx.doi.org/10.1109/iros.2006.282316.

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Jiang, Huai-wei, Shi-gang Wang, Wei Xu, Zhi-zhou Zhang, and Lin He. "Construction of medical nanorobot." In 2005 IEEE International Conference on Robotics and Biomimetics. IEEE, 2005. http://dx.doi.org/10.1109/robio.2005.246254.

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Reports on the topic "Nanoroboter"

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Kladitis, Paul. Identifying Technology Barriers to the Realization of True Microrobots and Nanorobots for Military Application by 2035. Fort Belvoir, VA: Defense Technical Information Center, January 2010. http://dx.doi.org/10.21236/ada537168.

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