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Biorobotics

(Redirected from Biorobot)

Biorobotics is an interdisciplinary science that combines the fields of biomedical engineering, cybernetics, and robotics to develop new technologies that integrate biology with mechanical systems to develop more efficient communication, alter genetic information, and create machines that imitate biological systems.[1]

Cybernetics

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Cybernetics focuses on the communication and system of living organisms and machines that can be applied and combined with multiple fields of study such as biology, mathematics, computer science, engineering, and much more.

This discipline falls under the branch of biorobotics because of its combined field of study between biological bodies and mechanical systems. Studying these two systems allow for advanced analysis on the functions and processes of each system as well as the interactions between them.

History

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Cybernetic theory is a concept that has existed for centuries, dating back to the era of Plato where he applied the term to refer to the "governance of people". The term cybernetique is seen in the mid-1800s used by physicist André-Marie Ampère.[2] The term cybernetics was popularized in the late 1940s to refer to a discipline that touched on, but was separate, from established disciplines, such as electrical engineering, mathematics, and biology.[2]

Science

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Cybernetics is often misunderstood because of the breadth of disciplines it covers. In the early 20th century, it was coined as an interdisciplinary field of study that combines biology, science, network theory, and engineering. Today, it covers all scientific fields with system related processes. The goal of cybernetics is to analyze systems and processes of any system or systems in an attempt to make them more efficient and effective.[2]

Applications

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Cybernetics is used as an umbrella term so applications extend to all systems related scientific fields such as biology, mathematics, computer science, engineering, management, psychology, sociology, art, and more. Cybernetics is used amongst several fields to discover principles of systems, adaptation of organisms, information analysis and much more.[3]

Genetic engineering

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Genetic engineering is a field that uses advances in technology to modify biological organisms. Through different methods, scientists are able to alter the genetic material of microorganisms, plants and animals to provide them with desirable traits. For example, making plants grow bigger, better, and faster.[4] Genetic engineering is included in biorobotics because it uses new technologies to alter biology and change an organism's DNA for their and society's benefit.[5][6]

History

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Although humans have modified genetic material of animals and plants through artificial selection for millennia (such as the genetic mutations that developed teosinte into corn and wolves into dogs), genetic engineering refers to the deliberate alteration or insertion of specific genes to an organism's DNA. The first successful case of genetic engineering occurred in 1973 when Herbert Boyer and Stanley Cohen were able to transfer a gene with antibiotic resistance to a bacterium.[7][8][9]

Science

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There are three main techniques used in genetic engineering: The plasmid method, the vector method and the biolistic method.

Plasmid method

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This technique is used mainly for microorganisms such as bacteria. Through this method, DNA molecules called plasmids are extracted from bacteria and placed in a lab where restriction enzymes break them down. As the enzymes break the molecules down, some develop a rough edge that resembles that of a staircase which is considered 'sticky' and capable of reconnecting. These 'sticky' molecules are inserted into another bacteria where they will connect to the DNA rings with the altered genetic material.[10]

Vector method

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The vector method is considered a more precise technique than the plasmid method as it involves the transfer of a specific gene instead of a whole sequence. In the vector method, a specific gene from a DNA strand is isolated through restriction enzymes in a laboratory and is inserted into a vector. Once the vector accepts the genetic code, it is inserted into the host cell where the DNA will be transferred.[10]

Biolistic method

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The biolistic method is typically used to alter the genetic material of plants. This method embeds the desired DNA with a metallic particle such as gold or tungsten in a high speed gun. The particle is then bombarded into the plant. Due to the high velocities and the vacuum generated during bombardment, the particle is able to penetrate the cell wall and inserts the new DNA into the cell.[11]

Applications

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Genetic engineering has many uses in the fields of medicine, research and agriculture. In the medical field, genetically modified bacteria are used to produce drugs such as insulin, human growth hormones and vaccines. In research, scientists genetically modify organisms to observe physical and behavioral changes to understand the function of specific genes. In agriculture, genetic engineering is extremely important as it is used by farmers to grow crops that are resistant to herbicides and to insects such as BTCorn.[12][13]

Bionics

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Bionics is a medical engineering field and a branch of biorobotics consisting of electrical and mechanical systems that imitate biological systems, such as prosthetics and hearing aids. It's a portmanteau that combines biology and electronics.

History

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The history of bionics goes as far back in time as ancient Egypt. A prosthetic toe made out of wood and leather was found on the foot of a mummy. The time period of the mummy corpse was estimated to be from around the fifteenth century B.C.[citation needed] Bionics can also be witnessed in ancient Greece and Rome. Prosthetic legs and arms were made for amputee soldiers. In the early 16th century, a French military surgeon by the name of Ambroise Pare became a pioneer in the field of bionics. He was known for making various types of upper and lower prosthetics. One of his most famous prosthetics, Le Petit Lorrain, was a mechanical hand operated by catches and springs. During the early 19th century, Alessandro Volta further progressed bionics. He set the foundation for the creation of hearing aids with his experiments. He found that electrical stimulation could restore hearing by inserting an electrical implant to the saccular nerve of a patient's ear. In 1945, the National Academy of Sciences created the Artificial Limb Program, which focused on improving prosthetics since there were a large number of World War II amputee soldiers. Since this creation, prosthetic materials, computer design methods, and surgical procedures have improved, creating modern-day bionics.[14]

Science

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Prosthetics

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The important components that make up modern-day prosthetics are the pylon, the socket, and the suspension system. The pylon is the internal frame of the prosthetic that is made up of metal rods or carbon-fiber composites. The socket is the part of the prosthetic that connects the prosthetic to the person's missing limb. The socket consists of a soft liner that makes the fit comfortable, but also snug enough to stay on the limb. The suspension system is important in keeping the prosthetic on the limb. The suspension system is usually a harness system made up of straps, belts or sleeves that are used to keep the limb attached.

The operation of a prosthetic could be designed in various ways. The prosthetic could be body-powered, externally-powered, or myoelectrically powered. Body-powered prosthetics consist of cables attached to a strap or harness, which is placed on the person's functional shoulder, allowing the person to manipulate and control the prosthetic as he or she deems fit. Externally-powered prosthetics consist of motors to power the prosthetic and buttons and switches to control the prosthetic. Myoelectrically powered prosthetics are new, advanced forms of prosthetics where electrodes are placed on the muscles above the limb. The electrodes will detect the muscle contractions and send electrical signals to the prosthetic to move the prosthetic. The downside to this type of prosthetic is that if the sensors are not placed correctly on the limb then the electrical impulses will fail to move the prosthetic.[15] TrueLimb is a specific brand of prosthetics that uses myoelectrical sensors which enable a person to have control of their bionic limb.[15]

Hearing aids

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Four major components make up the hearing aid: the microphone, the amplifier, the receiver, and the battery. The microphone takes in outside sound, turns that sound to electrical signals, and sends those signals to the amplifier. The amplifier increases the sound and sends that sound to the receiver. The receiver changes the electrical signal back into sound and sends the sound into the ear. Hair cells in the ear will sense the vibrations from the sound, convert the vibrations into nerve signals, and send it to the brain so the sounds can become coherent to the person. The battery simply powers the hearing aid.[16]

Applications

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Cochlear Implant

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Cochlear implants are a type of hearing aid for those who are deaf. Cochlear implants send electrical signals straight to the auditory nerve, the nerve responsible for sound signals, instead of just sending the signals to the ear canal like conventional hearing aids.

Bone-Anchored Hearing Aids

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These hearing aids are also used for people with severe hearing loss. They attach to the bones of the middle ear to create sound vibrations in the skull and send those vibrations to the cochlea.

Artificial sensing skin

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Artificial sensing-skin detects any pressure put on it and is meant for people who have lost any sense of feeling on parts of their bodies, such as diabetics with peripheral neuropathy.

Bionic eye

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A bionic eye is a bioelectronic implant designed to restore vision for individuals with blindness.

Although the technology is still in development, it has enabled some legally blind individuals to distinguish letters again. [17]

Replicating the retina, which contains millions of photoreceptors, and matching the human eye’s exceptional lensing and dynamic range capabilities pose significant challenges. Neural integration further complicates the process. Despite these difficulties, ongoing research and prototyping have led to several major achievements in recent years.[17]

Orthopedic bionics

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Orthopedic bionics consist of advanced bionic limbs that use a person's neuromuscular system to control the bionic limb. A new advancement in the comprehension of brain function has led to the development and implementation of brain-machine interfaces (BMIs).[18] BMIs allow for the processing of neural messaging between motor regions of the brain to muscles of a specific limb to initiate movement.[18] BMIs contribute greatly to the restoration of a person's independent movement who has a bionic limb and or an exoskeleton.[18]

Endoscopic robotics

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These robotics can remove a polyp during a colonoscopy.

Animal-robot interactions

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Block representation of the animal-robot interactions research field

Animal-robot interactions is a field of Biorobotics that focuses on the blending of robotic compounds with animal individuals or populations.[19] The domain can be subdivided into two main branches, one that relates mechatronic devices with individual animals, and another one with animal populations. Both branches have a variety of applications, ranging from animal cyborgs benefiting from animals' superior motor capabilities[20] to ethological studies around animal collective behaviour.[21][22][23] While this representation draws a globally accurate view of the domain, some animal-robot interactions cannot be strictly classified into one or the other of these branches, or are sometimes a mixture of both. This is the case namely for ethological robots that interact on a one-to-one basis[22][24] or when eusocial animals are considered as a single superorganism interacting with a single robotic device. In the latter case, the term Bio-Hybrid superorganism is used to describe the blending of a robotic device with a superorganism to enable interaction, control and thus studying of the latter superorganism.[25][26][27]

Bio-Hybrid organisms

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Mixed societies

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Mixed societies blend together a set of animals (animal society) with a set of robotic devices (artificial society). Care should be take when using the word society, as the noun could be misleading within the zoologist community that is involved in this domain; a more accurate word would be populations,[19] which is also the one used for the rest of this section.

Typically, the robotic population is composed of robotic replica of the target animal individuals aimed to integrate within the animal population. To do this, stimuli naturally perceived by the animals are emitted by the robotic individuals, and this through different communication channels: visual cues, thermal pulses, vibration signals, etc. The degree to which the robotic individuals successfully blend with the animal population is related to as bio-acceptance, and is often key to enable further behavioural study of the target species.[28]

Once interactions between the animal and robot population is achieved by establishing relevant communication channels, mixed societies offer the potential for adaptive robotic behaviours driven by real-time feedback from the animal population. By responding directly to animal behaviour, the robots can dynamically adjust their actions to better integrate into the group. This capability is particularly valuable for understanding collective behaviours in animal populations. Adaptive robots can be used to implement models of specific roles or interactions within a group, enabling the testing of hypotheses about coordination, decision-making, or social organisation. This approach bridges experimental and modelling techniques, in an attempt to offer insights into the underlying mechanisms of collective behaviour.[29]

See also

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References

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  1. ^ Dario, Paolo (15 July 2005). "Journal of the Robotics Society of Japan". 23 (5): 552–554. doi:10.7210/jrsj.23.552. {{cite journal}}: Cite journal requires |journal= (help)
  2. ^ a b c "Cybernetics – A Definition". pangaro.com. Retrieved 2020-04-03.
  3. ^ "Cybernetics - Encyclopedia of Mathematics". encyclopediaofmath.org. Retrieved 2020-04-03.
  4. ^ Turner, Lisa (June 2001). "Weird science: what you need to know about genetic engineering". library.brookdalecc.edu. Retrieved 2023-04-24.
  5. ^ "What is genetic engineering?". yourgenome. Retrieved 2020-04-03.
  6. ^ Mulligan, Pamela K. (2021). "Genetic engineering". Access Science. doi:10.1036/1097-8542.285000.
  7. ^ Rangel, Gabriel (2015-08-09). "From Corgis to Corn: A Brief Look at the Long History of GMO Technology". Science in the News. Harvard University. Retrieved 2020-04-03.
  8. ^ "History of genetic engineering". Royal Society Te Apārangi. Retrieved 2020-04-03.
  9. ^ "Genetic Engineering". Genome.gov. Retrieved 2020-04-03.
  10. ^ a b "Methods of Genetic Engineering". mrlloyder. Retrieved 2020-04-03.
  11. ^ "Biolistic Transformation - an overview | ScienceDirect Topics". sciencedirect.com. Retrieved 2020-04-03.
  12. ^ "7.23B: Applications of Genetic Engineering". Biology LibreTexts. 2017-06-06. Retrieved 2020-04-03.
  13. ^ "genetic engineering | Definition, Process, & Uses". Encyclopædia Britannica. Retrieved 2020-04-03.
  14. ^ "The History of Bionics". Bionic Medicine. 2012-12-10. Retrieved 2020-04-03.
  15. ^ a b "How Prosthetic Arms Are Controlled, and How TrueLimb is Different". Unlimited Tomorrow. 2021-08-04. Retrieved 2023-11-15.
  16. ^ "Hearing Aid Basics". HowStuffWorks. 2007-08-23. Retrieved 2020-04-03.
  17. ^ a b Lu, Donna (2019). "Bionic eye helps people who are blind read letters again". New Scientist. 243 (3241): 15. Bibcode:2019NewSc.243...15L. doi:10.1016/S0262-4079(19)31410-1. S2CID 201259631.
  18. ^ a b c Pandarinath, Chethan; Bensmaia, Sliman J. (2022-04-01). "The science and engineering behind sensitized brain-controlled bionic hands". Physiological Reviews. 102 (2): 551–604. doi:10.1152/physrev.00034.2020. ISSN 0031-9333. PMC 8742729. PMID 34541898.
  19. ^ a b Romano, Donato; Donati, Elisa; Benelli, Giovanni; Stefanini, Cesare (June 2019). "A review on animal–robot interaction: from bio-hybrid organisms to mixed societies". Biological Cybernetics. 113 (3): 201–225. doi:10.1007/s00422-018-0787-5. ISSN 0340-1200.
  20. ^ Wang, Yueming; Lu, Minlong; Wu, Zhaohui; Tian, Liwen; Xu, Kedi; Zheng, Xiaoxiang; Pan, Gang (May 2015). "Visual Cue-Guided Rat Cyborg for Automatic Navigation [Research Frontier]". IEEE Computational Intelligence Magazine. 10 (2): 42–52. doi:10.1109/MCI.2015.2405318. ISSN 1556-603X.
  21. ^ Krause, Jens; Winfield, Alan F.T.; Deneubourg, Jean-Louis (July 2011). "Interactive robots in experimental biology". Trends in Ecology & Evolution. 26 (7): 369–375. doi:10.1016/j.tree.2011.03.015.
  22. ^ a b Phamduy, P; Polverino, G; Fuller, R C; Porfiri, M (2014-08-27). "Fish and robot dancing together: bluefin killifish females respond differently to the courtship of a robot with varying color morphs". Bioinspiration & Biomimetics. 9 (3): 036021. doi:10.1088/1748-3182/9/3/036021. ISSN 1748-3182.
  23. ^ Michelsen, Axel; Andersen, Bent Bach; Storm, Jesper; Kirchner, Wolfgang H.; Lindauer, Martin (April 1992). "How honeybees perceive communication dances, studied by means of a mechanical model". Behavioral Ecology and Sociobiology. 30 (3–4): 143–150. doi:10.1007/BF00166696. ISSN 0340-5443.
  24. ^ Patricelli, Gail L.; Coleman, Seth W.; Borgia, Gerald (January 2006). "Male satin bowerbirds, Ptilonorhynchus violaceus, adjust their display intensity in response to female startling: an experiment with robotic females". Animal Behaviour. 71 (1): 49–59. doi:10.1016/j.anbehav.2005.03.029.
  25. ^ Barmak, Rafael; Stefanec, Martin; Hofstadler, Daniel N.; Piotet, Louis; Schönwetter-Fuchs-Schistek, Stefan; Mondada, Francesco; Schmickl, Thomas; Mills, Rob (2023-03-22). "A robotic honeycomb for interaction with a honeybee colony". Science Robotics. 8 (76). doi:10.1126/scirobotics.add7385. ISSN 2470-9476.
  26. ^ Barmak, Rafael; Hofstadler, Daniel N.; Stefanec, Martin; Piotet, Louis; Cherfan, Raphaël; Schmickl, Thomas; Mondada, Francesco; Mills, Rob (2024). "Biohybrid Superorganisms—On the Design of a Robotic System for Thermal Interactions With Honeybee Colonies". IEEE Access. 12: 50849–50871. doi:10.1109/ACCESS.2024.3385658. ISSN 2169-3536.
  27. ^ Botner Barmak, Rafael (2024). A Biohybrid Superorganism - Investigating honeybees' collective behaviors via interactive robotics (Thesis). [object Object]. doi:10.5075/epfl-thesis-10594.
  28. ^ Halloy, José; Mondada, Francesco; Kernbach, Serge; Schmickl, Thomas (2013), Lepora, Nathan F.; Mura, Anna; Krapp, Holger G.; Verschure, Paul F. M. J. (eds.), "Towards Bio-hybrid Systems Made of Social Animals and Robots", Biomimetic and Biohybrid Systems, vol. 8064, Berlin, Heidelberg: Springer Berlin Heidelberg, pp. 384–386, doi:10.1007/978-3-642-39802-5_42, ISBN 978-3-642-39801-8, retrieved 2024-11-19
  29. ^ Kernbach, Serge, ed. (2013-05-29), "Developmental Collective Robotics: Advantages and Challenges of Unbounded Self-Development", Handbook of Collective Robotics (0 ed.), Jenny Stanford Publishing, pp. 529–570, doi:10.1201/b14908-19, ISBN 978-0-429-06759-4, retrieved 2024-11-19
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