nanobio technology drug delivery robot Microbivores ppt
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It is a nano robot used to kill pathogens and used to deliver the drug to required part of our body without effecting to any other part rather than infected part
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Btech Final Seminar Topic Microbivore
Microbivores in simple terms means microbiological pathogens destroyer
It is an ideal nanotechnology-based drug delivery system which is—self- powered, computer-controlled medical nanorobot system capable of digitally precise transport, timing, and targeted delivery of pharmaceutical agents to specific cellular and intracellular destinations within the human body
Microbivores-The future of Nanomedicines
This presentation will provide you the details of a special category of the so called Medical Nanorobots known as "Microbivores" or the artificial white blood cells.
Microbivores
Detailed digesting process of microbivores and applications of microbivores. Advantages and disadvantages of microbivores.
Microbivores ppt to kill pathogens
This document presents information about microbivores, a proposed type of nanorobot that could be injected into the human bloodstream to treat diseases. Microbivores are described as artificial white blood cells that would float through the bloodstream, using sensors to detect pathogens and then digesting them into harmless molecules through a "digest protocol." They are proposed to be made of diamond, roughly 3-4 microns in diameter, powered by fuel cells at 200pW each. The document suggests that microbivores could decrease biohazards in the body while also selectively delivering drugs to targeted areas without affecting other tissues.
Microbivores-The future of Nanomedicines
Microbivores are a type of proposed nanorobotic phagocytes or artificial white blood cells. They would be spheroid devices 3.4 μm in diameter made of over 600 billion precisely arranged atoms. Microbivores would trap and destroy blood pathogens much faster than natural white blood cells, completely destroying one pathogen within 30 seconds. They could have applications for drug delivery, cancer treatment, and more. However, challenges remain regarding their safety and the technical difficulties of manufacturing at the nanoscale.
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This document discusses the potential advantages of using 3D in vitro models compared to traditional 2D models for drug testing. It notes that 3D cultures more closely mimic the in vivo microenvironment and cell morphology. This allows 3D cultures to better predict cellular responses to drugs and provide more accurate models of disease. The document outlines several applications of 3D cultures, such as studying tumor development, evaluating drug sensitivity, and developing organs-on-chips microfluidic devices that model human organ functions.
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Btech Final Seminar Topic Microbivore
Microbivores in simple terms means microbiological pathogens destroyer
It is an ideal nanotechnology-based drug delivery system which is—self- powered, computer-controlled medical nanorobot system capable of digitally precise transport, timing, and targeted delivery of pharmaceutical agents to specific cellular and intracellular destinations within the human body
Microbivores-The future of Nanomedicines
This presentation will provide you the details of a special category of the so called Medical Nanorobots known as "Microbivores" or the artificial white blood cells.
Microbivores
Detailed digesting process of microbivores and applications of microbivores. Advantages and disadvantages of microbivores.
Microbivores ppt to kill pathogens
This document presents information about microbivores, a proposed type of nanorobot that could be injected into the human bloodstream to treat diseases. Microbivores are described as artificial white blood cells that would float through the bloodstream, using sensors to detect pathogens and then digesting them into harmless molecules through a "digest protocol." They are proposed to be made of diamond, roughly 3-4 microns in diameter, powered by fuel cells at 200pW each. The document suggests that microbivores could decrease biohazards in the body while also selectively delivering drugs to targeted areas without affecting other tissues.
Microbivores-The future of Nanomedicines
Microbivores are a type of proposed nanorobotic phagocytes or artificial white blood cells. They would be spheroid devices 3.4 μm in diameter made of over 600 billion precisely arranged atoms. Microbivores would trap and destroy blood pathogens much faster than natural white blood cells, completely destroying one pathogen within 30 seconds. They could have applications for drug delivery, cancer treatment, and more. However, challenges remain regarding their safety and the technical difficulties of manufacturing at the nanoscale.
3D In Vitro Model for Drug Efficiency Testing
This document discusses the potential advantages of using 3D in vitro models compared to traditional 2D models for drug testing. It notes that 3D cultures more closely mimic the in vivo microenvironment and cell morphology. This allows 3D cultures to better predict cellular responses to drugs and provide more accurate models of disease. The document outlines several applications of 3D cultures, such as studying tumor development, evaluating drug sensitivity, and developing organs-on-chips microfluidic devices that model human organ functions.
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The document discusses the potential for nanorobots in medicine. It describes how nanorobots smaller than blood cells could be injected into the body to detect and treat medical issues. Researchers are working to design nanorobots that could treat conditions like cancer, repair damaged tissues, and more. While still in early stages of research, nanorobots may one day revolutionize healthcare by providing targeted treatment and curing currently incurable diseases with few side effects.
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Cyborg technology was presented by several speakers. A cyborg is a theoretical or fictional being with both organic and biomechatronic parts. Cyborgs allow humans to live in environments different from normal through external modification of control mechanisms. Applications of cyborg technology discussed include using it in medicine to restore lost functions, in the military by controlling insect motions, and in space to mitigate risks of sending humans. Many cyborg inventions exist while others remain fictional, with a wide range of current and potential future applications.
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- 1. PRESENTED BY: S.ROHIT SAGAR (450) UNDER THE GUIDENCE OF: SAAD AFZAL SIR
- 2. CONTENT INTRODUCTION PURPOSE SPECIFICATIONS WORKING CONCLUSION FUTURE SCOPE
- 3. Nanotechnology offers a new powerful tool to treat the human diseases in biological systems i.e; MICROBIVORES used to digest the pathogens (diseases causing viruses) in human body by injecting it into the blood stream.
- 4. Microbivores acts as a artificial white blood cells in human body which floats along with blood stream.
- 5. To decrease the bio-hazards in body. This nano -robot is also used to delivery the drug into the body along with the function of digesting pathogens. Without effecting any other parts of human body the drug is been delivered to the specified part of the body.
- 6. Microbivores is made with an element of carbon i.e; diamond (strong). Microbivores has diameter of about 3-4 microns. Input Power=200pW using the fuel cells.
- 7. Microbivores works with the principal of digest protocol. Group of microbivores are injected into the body which flows along with the blood stream . This robots are of type computered controlled devices.
- 8. The pathogen are been sensed with the internal sensors such as glucose sensor;oxygen sensor & CO2 sensor’s and then the pathogens are targeted.
- 9. The targeted pathogen are been selected and those are passed through the microbivores and made them into fine small elements(pieces). So by this the immunity power of the pathogen get decreased and required amount of drug can be delivered to the specified part of the body.
- 11. By this nano-robots the pathogens are completely digested into harmless sugars and amino-acids .
- 12. Rather than group of microbivores using only single microbivores function of pathogens can be digestible.