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
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
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.
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 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 Testingjudoublen
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.
Nanobots, the new technology thats healing the worldShirisha Ratcha
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.
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.
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
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.
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 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 Testingjudoublen
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.
Nanobots, the new technology thats healing the worldShirisha Ratcha
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.
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.
This document discusses nanobots, which are tiny machines designed to perform tasks at the nanoscale. It provides an introduction to nanobots and their potential uses in molecular manufacturing and self-replication. The history of nanobot development is covered, along with their potential applications in medical, military, and security fields. Both advantages like their small size and effectiveness in medicine, as well as disadvantages like the need for high accuracy and high initial design costs, are outlined.
This document discusses nanorobots and their potential medical applications. It describes a proposed nanorobot called a respirocyte, which could deliver oxygen in the bloodstream more efficiently than red blood cells. The document outlines the key components of nanorobots, including sensors, a CPU system, transport mechanisms, and energy sources like glucose. It suggests nanorobots could be programmed to detect and destroy cancer cells with fewer side effects than traditional treatments like chemotherapy and radiation. In conclusion, the author believes nanorobots may revolutionize medicine in the future through more precise, non-polluting operations.
Biorobotics involves applying biological principles to robotics. It includes biomimetics, which examines nature for inspiration in engineering design. Examples include airplanes modeled after birds, hypodermic needles after snake fangs, and bullet trains after kingfishers. Biomimetic robots copy structures and senses from animals like birds and insects. Biorobotics also applies robotics to biology and medicine problems. Examples are robotic lobsters and fish used for observation and pollution monitoring. Biorobotics continues advancing with robots inspired by snakes, insects, and other organisms.
This document outlines a technical seminar presentation on nanorobots. It discusses how nanorobots could be used in nanomedicine, with sections covering their potential appearance and sizes, methods of control and navigation using external systems like magnetic fields, power sources using chemicals in blood, locomotion through vibrating or magnetic manipulation, applications like targeting cancer cells or breaking up stones, and a conclusion that nanorobots could eliminate diseases and extend human abilities.
This document discusses nanobots, which are tiny robots that can operate at the nanoscale level. It describes several types of nanobots, including respirocytes that act like artificial red blood cells, microbivores that act like white blood cells, and clottocytes that act like platelets. The document outlines how nanobots may be used for cancer treatment, breaking up kidney stones, detecting pathogens, and killing viruses. Both advantages like rapid disease elimination and disadvantages like high costs are presented. The conclusion states that nanobots have potential to provide benefits for medical treatment and diagnosis.
Nanorobotics is the emerging field of engineering nanorobots, which are robotic devices between 0.1-10 micrometers that are constructed of nanoscale or molecular components. Nanorobots could have applications in medicine such as performing surgery. One potential application is using a nanorobot to remove plaque from arteries and perform heart bypass surgery. The nanorobot would navigate through the bloodstream using sensors and propellers. It could identify plaque using temperature sensors and cameras. The nanorobot would then remove the plaque using a rotating needle. It would be powered by a nuclear power source and guided out of the body by surgery to remove it after completing the procedure. This could allow bypass surgery to be performed without major inc
This document discusses nanorobots, which are robots constructed from nanoscale components between 0.1-10 micrometers in size. Nanorobots could be used for applications in medicine like targeted drug delivery, tissue engineering, and finding cures for diseases. They may also be used in space exploration, toxic detection, and replacing heart surgery. The document outlines some of the basic components of nanorobots like sensors, molecular sorting rotors, and fins. It also discusses challenges like developing specialized nanoscale tools for building nanorobots and potential medical applications.
The document discusses the field of bio-robotics, which involves studying how to create robots that emulate or simulate living organisms mechanically or chemically, or making biological organisms as manipulatable as robots. It covers topics like animal-like robots that link biology and engineering, using bio-robotics to understand animal-environment relationships, applications in the military, for disabled people, and in various science fields. Examples are provided of bio-inspired robots like a jumping robot based on a frog and a climbing robot based on geckos, as well as research in brain-computer interfaces and exoskeletons.
The document discusses nanorobotics and describes various components involved. It provides an overview of nanorobotics, defining it as the technology of creating robots at the nanoscale level. It describes challenges in building nanorobots such as reducing friction and supplying power at the nanoscale. The document outlines the components of nanorobots including sensors, computers, actuators, power sources and how they work together. It discusses different types of nanorobots and techniques for their design and manufacture. Applications of nanorobots in medicine are also mentioned.
This document discusses nanobots and their potential medical applications. It begins with definitions of nanotechnology and nanorobotics. It then describes several types of proposed nanobots, including microbivores to destroy bacteria, respirocytes to carry oxygen like red blood cells, and clottocytes resembling platelets. The document outlines how nanobots could be used in chemotherapy to precisely deliver drugs to cancer cells while avoiding healthy cells. It reviews mechanisms for nanobot movement and detection of cancer. Potential advantages include rapid treatment and diagnosis, while drawbacks include risks of replication getting out of control and high costs. The conclusion is that nanobots may significantly improve treatment and diagnosis of diseases by reducing side effects.
A seminar on Brain Chip Interface Abhishek VermaÂßhîshêk Vêrmã
This document discusses brain-computer interfaces (BCIs). It begins with an introduction and overview of BCIs, including their history starting with Hans Berger's discovery of EEG in 1924. It then covers the basic working of BCIs, including signal acquisition, feature translation, and device commands. The document discusses invasive, non-invasive, and semi-invasive BCIs. It outlines several applications of BCIs, such as assisting paralyzed individuals and gaming control. Concerns about the current limitations and future directions are also mentioned, such as combining BCIs with vision and using them for security applications like lie detection.
The document discusses biorobotics and its application in improving quality of life. Biorobotics involves applying robotics and engineering principles to biology and medicine. It describes the Disease Detector (DDX) system, a portable device that detects response time and psychophysical conditions to diagnose neurological conditions like Parkinson's and Alzheimer's disease. The DDX has advantages like being small, portable and user-friendly. However, its control system relies on a small internal fuzzy logic board that may not adequately handle variable traffic. The document also discusses various biorobotics inventions and applications.
ROBOTICS FOR BIOLOGICAL AND MEDICAL APPLICATIONSsathish sak
Robotics for Biological and Medical Applications
Robotics provides valuable experiments in life science research by automating delivery and dispensation of biological samples and solutions in large numbers with small volumes. It also aids important medical diagnosis. Some applications of robotics include cell manipulation, DNA insertion, cell injection, and prolonged exploration of molecular and cellular biology. Key technologies used include sensing, microscopy, actuation, and miniaturized tools for handling bio samples. Nanorobots could potentially cure cancer by injecting them into patients to detect and destroy cancer cells without affecting healthy cells.
Assuming the nanorobot is ’ nt tethered or designed to float passively through the bloodstream , it will need a means of propulsion to get around the body.
Because it may have to travel against the flow of blood , the propulsion system has to be relatively strong for its size.
Another important consideration is the safety of the patient , the system must be able to move the nanorobot around without causing damaging to the host.
Nanobots are tiny machines that can operate inside the human body at the nanoscale level. They are injected into the bloodstream and can target specific cells and organs to deliver drugs or perform other tasks. Some proposed applications of nanobots include breaking up blood clots and kidney stones, curing skin diseases, assisting with heart surgery and removing tumors. While nanobots show promise for revolutionizing medicine, there are also safety and technical challenges that need to be addressed before widespread use.
Brain gate technology allows people to control external devices like computers and robotic limbs using only their brain signals. It involves implanting a microchip in the motor cortex of the brain that detects neural activity and transmits it via wires to a computer for translation into device commands. While promising for restoring function to paralyzed individuals, it requires invasive brain surgery and users must undergo training to learn how to produce distinct brain patterns to control different devices. Current research focuses on developing smaller, wireless versions of the technology.
Robotics can be used in medical procedures to increase surgical accuracy and decrease operating times. The first documented use of a robot in surgery was in 1985 using the PUMA 560 robotic arm to assist with a delicate neurosurgery. Since then, robots have been used in minimally invasive laparoscopic surgeries. Medical robotics is important as it can reduce patient discomfort and costs, improve access to care, shorten procedures, and allow non-specialists to perform complex surgeries. Popular medical robot systems include the Da Vinci Surgical System for laparoscopy and Intuitive Surgical's tissue engineering robots. While automation may replace some human roles in the operating room, it also has potential for long-term cost
This document provides an overview of nanorobotics. It discusses the specifications and parts of nanorobots, including sensors, CPUs, transport systems, and energy sources. A specific nanorobot called a respirocyte is described that could dramatically increase oxygen delivery. The applications of nanorobots discussed include cancer treatment, heart surgery, space exploration, and counterterrorism. Concerns about the safety of nanorobots are also mentioned.
Nanorobotics is a new field of science. Most of the projects are in research and development phase. The only proper applications have been made in the medicinal field.
The document describes a seminar report submitted by Yogesh Sharma on nanobotics to fulfill requirements for a Bachelor of Technology degree. It includes an abstract that discusses nanorobotics as the field of creating robots at the microscopic nanometer scale and potential applications in medical technology and environmental monitoring. The report also provides acknowledgements, table of contents, introduction to nanorobotics concepts, and planned chapters on topics like biochips, fractal robots, and challenges of nanobotics.
This document discusses nanobots, which are tiny machines designed to perform tasks at the nanoscale. It provides an introduction to nanobots and their potential uses in molecular manufacturing and self-replication. The history of nanobot development is covered, along with their potential applications in medical, military, and security fields. Both advantages like their small size and effectiveness in medicine, as well as disadvantages like the need for high accuracy and high initial design costs, are outlined.
This document discusses nanorobots and their potential medical applications. It describes a proposed nanorobot called a respirocyte, which could deliver oxygen in the bloodstream more efficiently than red blood cells. The document outlines the key components of nanorobots, including sensors, a CPU system, transport mechanisms, and energy sources like glucose. It suggests nanorobots could be programmed to detect and destroy cancer cells with fewer side effects than traditional treatments like chemotherapy and radiation. In conclusion, the author believes nanorobots may revolutionize medicine in the future through more precise, non-polluting operations.
Biorobotics involves applying biological principles to robotics. It includes biomimetics, which examines nature for inspiration in engineering design. Examples include airplanes modeled after birds, hypodermic needles after snake fangs, and bullet trains after kingfishers. Biomimetic robots copy structures and senses from animals like birds and insects. Biorobotics also applies robotics to biology and medicine problems. Examples are robotic lobsters and fish used for observation and pollution monitoring. Biorobotics continues advancing with robots inspired by snakes, insects, and other organisms.
This document outlines a technical seminar presentation on nanorobots. It discusses how nanorobots could be used in nanomedicine, with sections covering their potential appearance and sizes, methods of control and navigation using external systems like magnetic fields, power sources using chemicals in blood, locomotion through vibrating or magnetic manipulation, applications like targeting cancer cells or breaking up stones, and a conclusion that nanorobots could eliminate diseases and extend human abilities.
This document discusses nanobots, which are tiny robots that can operate at the nanoscale level. It describes several types of nanobots, including respirocytes that act like artificial red blood cells, microbivores that act like white blood cells, and clottocytes that act like platelets. The document outlines how nanobots may be used for cancer treatment, breaking up kidney stones, detecting pathogens, and killing viruses. Both advantages like rapid disease elimination and disadvantages like high costs are presented. The conclusion states that nanobots have potential to provide benefits for medical treatment and diagnosis.
Nanorobotics is the emerging field of engineering nanorobots, which are robotic devices between 0.1-10 micrometers that are constructed of nanoscale or molecular components. Nanorobots could have applications in medicine such as performing surgery. One potential application is using a nanorobot to remove plaque from arteries and perform heart bypass surgery. The nanorobot would navigate through the bloodstream using sensors and propellers. It could identify plaque using temperature sensors and cameras. The nanorobot would then remove the plaque using a rotating needle. It would be powered by a nuclear power source and guided out of the body by surgery to remove it after completing the procedure. This could allow bypass surgery to be performed without major inc
This document discusses nanorobots, which are robots constructed from nanoscale components between 0.1-10 micrometers in size. Nanorobots could be used for applications in medicine like targeted drug delivery, tissue engineering, and finding cures for diseases. They may also be used in space exploration, toxic detection, and replacing heart surgery. The document outlines some of the basic components of nanorobots like sensors, molecular sorting rotors, and fins. It also discusses challenges like developing specialized nanoscale tools for building nanorobots and potential medical applications.
The document discusses the field of bio-robotics, which involves studying how to create robots that emulate or simulate living organisms mechanically or chemically, or making biological organisms as manipulatable as robots. It covers topics like animal-like robots that link biology and engineering, using bio-robotics to understand animal-environment relationships, applications in the military, for disabled people, and in various science fields. Examples are provided of bio-inspired robots like a jumping robot based on a frog and a climbing robot based on geckos, as well as research in brain-computer interfaces and exoskeletons.
The document discusses nanorobotics and describes various components involved. It provides an overview of nanorobotics, defining it as the technology of creating robots at the nanoscale level. It describes challenges in building nanorobots such as reducing friction and supplying power at the nanoscale. The document outlines the components of nanorobots including sensors, computers, actuators, power sources and how they work together. It discusses different types of nanorobots and techniques for their design and manufacture. Applications of nanorobots in medicine are also mentioned.
This document discusses nanobots and their potential medical applications. It begins with definitions of nanotechnology and nanorobotics. It then describes several types of proposed nanobots, including microbivores to destroy bacteria, respirocytes to carry oxygen like red blood cells, and clottocytes resembling platelets. The document outlines how nanobots could be used in chemotherapy to precisely deliver drugs to cancer cells while avoiding healthy cells. It reviews mechanisms for nanobot movement and detection of cancer. Potential advantages include rapid treatment and diagnosis, while drawbacks include risks of replication getting out of control and high costs. The conclusion is that nanobots may significantly improve treatment and diagnosis of diseases by reducing side effects.
A seminar on Brain Chip Interface Abhishek VermaÂßhîshêk Vêrmã
This document discusses brain-computer interfaces (BCIs). It begins with an introduction and overview of BCIs, including their history starting with Hans Berger's discovery of EEG in 1924. It then covers the basic working of BCIs, including signal acquisition, feature translation, and device commands. The document discusses invasive, non-invasive, and semi-invasive BCIs. It outlines several applications of BCIs, such as assisting paralyzed individuals and gaming control. Concerns about the current limitations and future directions are also mentioned, such as combining BCIs with vision and using them for security applications like lie detection.
The document discusses biorobotics and its application in improving quality of life. Biorobotics involves applying robotics and engineering principles to biology and medicine. It describes the Disease Detector (DDX) system, a portable device that detects response time and psychophysical conditions to diagnose neurological conditions like Parkinson's and Alzheimer's disease. The DDX has advantages like being small, portable and user-friendly. However, its control system relies on a small internal fuzzy logic board that may not adequately handle variable traffic. The document also discusses various biorobotics inventions and applications.
ROBOTICS FOR BIOLOGICAL AND MEDICAL APPLICATIONSsathish sak
Robotics for Biological and Medical Applications
Robotics provides valuable experiments in life science research by automating delivery and dispensation of biological samples and solutions in large numbers with small volumes. It also aids important medical diagnosis. Some applications of robotics include cell manipulation, DNA insertion, cell injection, and prolonged exploration of molecular and cellular biology. Key technologies used include sensing, microscopy, actuation, and miniaturized tools for handling bio samples. Nanorobots could potentially cure cancer by injecting them into patients to detect and destroy cancer cells without affecting healthy cells.
Assuming the nanorobot is ’ nt tethered or designed to float passively through the bloodstream , it will need a means of propulsion to get around the body.
Because it may have to travel against the flow of blood , the propulsion system has to be relatively strong for its size.
Another important consideration is the safety of the patient , the system must be able to move the nanorobot around without causing damaging to the host.
Nanobots are tiny machines that can operate inside the human body at the nanoscale level. They are injected into the bloodstream and can target specific cells and organs to deliver drugs or perform other tasks. Some proposed applications of nanobots include breaking up blood clots and kidney stones, curing skin diseases, assisting with heart surgery and removing tumors. While nanobots show promise for revolutionizing medicine, there are also safety and technical challenges that need to be addressed before widespread use.
Brain gate technology allows people to control external devices like computers and robotic limbs using only their brain signals. It involves implanting a microchip in the motor cortex of the brain that detects neural activity and transmits it via wires to a computer for translation into device commands. While promising for restoring function to paralyzed individuals, it requires invasive brain surgery and users must undergo training to learn how to produce distinct brain patterns to control different devices. Current research focuses on developing smaller, wireless versions of the technology.
Robotics can be used in medical procedures to increase surgical accuracy and decrease operating times. The first documented use of a robot in surgery was in 1985 using the PUMA 560 robotic arm to assist with a delicate neurosurgery. Since then, robots have been used in minimally invasive laparoscopic surgeries. Medical robotics is important as it can reduce patient discomfort and costs, improve access to care, shorten procedures, and allow non-specialists to perform complex surgeries. Popular medical robot systems include the Da Vinci Surgical System for laparoscopy and Intuitive Surgical's tissue engineering robots. While automation may replace some human roles in the operating room, it also has potential for long-term cost
This document provides an overview of nanorobotics. It discusses the specifications and parts of nanorobots, including sensors, CPUs, transport systems, and energy sources. A specific nanorobot called a respirocyte is described that could dramatically increase oxygen delivery. The applications of nanorobots discussed include cancer treatment, heart surgery, space exploration, and counterterrorism. Concerns about the safety of nanorobots are also mentioned.
Nanorobotics is a new field of science. Most of the projects are in research and development phase. The only proper applications have been made in the medicinal field.
The document describes a seminar report submitted by Yogesh Sharma on nanobotics to fulfill requirements for a Bachelor of Technology degree. It includes an abstract that discusses nanorobotics as the field of creating robots at the microscopic nanometer scale and potential applications in medical technology and environmental monitoring. The report also provides acknowledgements, table of contents, introduction to nanorobotics concepts, and planned chapters on topics like biochips, fractal robots, and challenges of nanobotics.
Nanotechnology is the engineering of functional systems at the molecular scale.
The technology of creating machines or robots at or close to the microscopic scale of a nanometer (10−9 meters).
The document discusses the potential of nanorobots and molecular nanotechnology (MNT) for medical applications. It describes how nanorobots could work inside the body to break up blood clots, fight cancer, and remove parasites through metabolizing energy and simple computation. Both benefits and risks of molecular nanotechnology are discussed, including how it could cure diseases but also enable new types of weapons and mass surveillance.
Nanorobotics involves the design and construction of robots on the nanoscale level using components that are between 1 to 100 nanometers. It includes programming swarms of nanorobots to perform tasks like breaking up kidney stones or repairing spacesuits. While nanorobots show promise for medical applications and space technology, challenges remain around their power supply, control, and potential health and environmental risks if replication gets out of control. A pioneer in medical nanorobotics developed prototypes for applications like monitoring brain aneurysms and treating diabetes.
This document provides an overview of nanorobotics. It discusses how nanorobotics involves engineering systems at the nanoscale using materials like carbon composites. Nanorobots could be 0.1-10 micrometers in size and could have molecular sorting rotors, propellers, fins and sensors. The document outlines applications for nanorobotics in medicine like treating tumors, kidney stones and blood clots. It also discusses benefits like speeding up treatment and more precise diagnosis. The future of nanorobotics may include uses in industry, manufacturing, supercomputers and healthcare.
This document discusses targeted drug delivery systems. It defines targeted drug delivery as selectively delivering medication to its site of action to increase concentration in tissues of interest while reducing it in other tissues, improving efficacy and reducing side effects. The document outlines various strategies for targeted delivery including passive, active, ligand-mediated and physical targeting. It also describes several types of targeted delivery systems including liposomes, dendrimers, nanotubes, nanoshells and others. The goal is to achieve the desired pharmacological response at selected sites with minimal side effects.
The document discusses the emerging field of polytronics, which uses conductive polymers rather than silicon in electronic devices. It notes that polytronics offers lower costs than silicon chips and more flexibility. The document provides an introduction to polymers and their properties. It outlines some of the history behind polytronics and discusses how polymers can conduct electricity. Examples of applications are given, such as organic field-effect transistors. Advantages of polytronics include lower electronic waste and more affordable access to technology.
This document discusses transparent electronics, which employs wide band-gap semiconductors like zinc oxide and amorphous indium gallium zinc oxide to create invisible electronic circuits and optoelectronic devices. These oxide semiconductors combine high visual transparency with high or low conductivity. Transparent oxide transistors have been made using zinc oxide channels. Key applications of transparent electronics include transparent passive devices, transparent active devices, security, entertainment, and more efficient energy utilization. The technology holds promise for impacting human-machine interaction and reducing environmental pollution from traditional techniques.
This document summarizes the potential applications of nanorobotics in medicine and healthcare. It discusses how nanorobots at the nanoscale could be used to cure diseases by delivering targeted drug therapies, performing microsurgery, breaking up blood clots, treating cancer and arteriosclerosis, and more. While nanorobotics is still a theoretical field, researchers are working to design microscopic robots that can safely navigate and operate within the human body to improve treatment outcomes with fewer side effects than traditional methods. Many challenges remain including developing biocompatible materials, powering nanorobots, and enabling navigation through the complex human circulatory system. If realized, nanorobots promise transformative applications across medicine.
Blu-ray or Blu-ray Disc (BD, BRD) is a digital optimal dics storage format. It was designed to supersede the DVD format, in that it is capable of storing high definition video resolution (1080p)
The document provides an overview of nanotechnology in drug delivery. It defines nanotechnology as research and development at the atomic, molecular and macromolecular levels between 1 to 100 nm. Nanomedicine is described as using engineered nanodevices and nanostructures to monitor, repair, construct and control human biological systems at the molecular level. Various nanomedicines are discussed, including nanoparticles, quantum dots, fullerenes, nanoshells, dendrimers, and potential future nanorobots. Their applications in drug delivery such as targeted drug delivery and reduced side effects are highlighted.
Nano med bot technology by manish myst ssgbcoetManish Myst
This presentation discusses nano-biotechnology and how it can be used for medical applications. It describes how nano-robots smaller than blood cells could be used as nano-medicine to deliver drugs, improve imaging, create artificial tissues, and analyze DNA. Examples discussed include respirocytes that could deliver more oxygen than red blood cells and microbivores that could destroy pathogens faster than the body's natural defenses. While this technology holds potential benefits, it also poses risks if nano-robots were able to self-replicate uncontrolled and threaten human existence. The development of nano-robotic systems able to manipulate objects at the molecular scale remains a major challenge.
Uses of Nanotechnology:
1- Diagnosis and treatment of cancer
According to the US National Cancer Institute (OTIR, 2006) “Nanotechnology will
change the very foundations of cancer diagnosis, treatment, and prevention”. We have
already seen how nanotechnology, an extremely wide and versatile field, can affect many
of its composing disciplines in amazingly innovative and unpredictable ways.
Q- what is cancer ?
Cancer is a disease caused by normal cells changing them so that they grow in an uncontrolled way.
The uncontrolled growth can cause problems in one or more of the following ways:
-spreading into normal tissues nearby.
-causing pressure on other body structure.
-spreading to other parts of the body through the lymphatic system or blood stream.
The word cancer was first applied to the disease by Hippocrates (460–370 B.C.), the
Greek philosopher, who used the words carcinos and carcinoma to refer to non-ulcer
forming and ulcer forming tumors. The words refer to a crab, probably due to the
external appearance of cancerous tumors, which have branch-like projections that
resemble the claws of a crab.
In nanomedicine, nanotechnology is being applied to medicine and health care. Some potential applications of nanomedicine discussed in the document include using nanomachines to monitor vital signs in the body, precisely deliver drugs and hormones as needed, and affect heart cell behavior in devices like pacemakers.
Regulation and control refer to government intervention in markets through various policies. There are several rationales for regulation, including addressing market failures from natural monopolies and externalities. However, regulation also imposes costs. When competition is eliminated and a monopoly is formed, either private or public, welfare loss occurs as output is restricted and prices rise. Resources also may be wasted in "rent-seeking," which refers to efforts to capture wealth transfers from the government, such as through lobbying for regulations that create monopolies, tariffs, quotas, or subsidies.
This document discusses nanorobotics and their potential medical applications. Nanorobots are microscopic devices measured on the nanometer scale that could work at the atomic, molecular, and cellular levels. They may be programmed to identify and quarantine harmful cells, deliver targeted drug treatments, monitor blood glucose levels, break up blood clots and kidney stones, treat cancer and arteriosclerosis. While nanorobots show promise for precision medicine and non-invasive procedures, challenges remain around their environmental and biological impacts if not properly designed.
Robotics can help with experiments in biology that require handling large numbers of biological samples in small volumes. It also assists with medical diagnoses. Some applications of robotics in biology and medicine include cell manipulation, stereotactic brain surgery, and lung biopsies. Key technologies used include sensing technologies like visual sensing and force sensing, as well as actuation methods and microtools for handling biological samples. One potential future application is using nanorobots to detect and destroy cancer cells without affecting healthy cells as a non-invasive treatment method.
Nanorobots are tiny machines that could be used for medical applications in the future. They are approximately 10-9 meters in size. Nanorobots may have components like power sources, sensors, manipulators and payloads to carry drugs. They could be designed in different shapes and sizes to perform tasks like targeting and destroying cancer cells, breaking up blood clots or kidney stones, or precisely delivering drugs. While nanorobots show promise for rapid disease treatment, their design and safety would need to be carefully evaluated before human use due to regulatory challenges. Overall, nanorobots may revolutionize medicine if technical hurdles are overcome.
Nanorobots and its application in medicineSagor Sakhaoat
For years, the cutting edge of medicine has promised nanobots. Tiny little machines that could run around your body delivering drugs, checking up on arteries, and generally keeping people healthy. But so far, those machines haven’t quite come to dominate the way some people thought they might. The human body is vastly more complicated than any robot we’ve ever made. So creating a miniscule robot to go inside of it, to work with that vast infrastructure, and to do our bidding, is a huge challenge.
1) The document discusses the concept of bacterial dirigibles, which are bacteria programmed using synthetic DNA to autonomously navigate and deliver therapeutic agents to targeted locations in the body.
2) Bacterial dirigibles are designed to have properties like targeted delivery, sensing capabilities, and producing medicines only where needed. They act like "nanofactories" and genetic circuits program their behavior.
3) Potential applications discussed include using bacterial dirigibles to treat diseases like cancer and inflammatory bowel disease, repair concrete, and destroy environmental pollutants. The document outlines how genetic circuits could program bacteria for these diverse functions.
Nanorobotics is an emerging field that could revolutionize medicine. Nanorobots are microscopic robots made of nanocomponents that could operate inside the human body to deliver drugs, break up kidney stones, clear blockages in arteries, and more. They may be equipped with sensors to monitor things like glucose levels and inject stem cells. Researchers are developing controls, sensors and actuators to enable different medical applications of nanorobotics. While still in the research phase, primitive nanorobots have been tested, and the first applications may be in medicine to identify pathogens and toxins. Nanorobots also have the potential to help the environment by purifying air and water and controlling pollution.
Biochip Informatics Technology For Electronic & Communication EngineeringNazakatHussain15
Biochips are small-scale devices analogous to integrated circuits that are constructed of or used to analyze organic molecules associated with living organisms. There are two main types of biochips: 1) those constructed of large organic molecules like proteins that can perform data storage and processing like computers, and 2) those capable of performing rapid small-scale biochemical reactions to identify things like gene sequences, pollutants, or other biochemical constituents. Biochips work by emitting a light beam through a fluidic channel that objects passing through will distort, allowing detection of small intensity changes. While biochips raise privacy issues and concerns about control, they also have advantages like identifying individuals uniquely, performing thousands of biochemical reactions quickly, and aiding in medical diagnosis and analytical
Nanobots: Lecture on the Artificial BloodSindhBiotech
This Lecture is presented by our volunteer Laraib Elahi, she is from Karachi, Pakistan, and she is covering "Nanobots: The Artificial Blood. "
For video: https://youtu.be/TsUgvOh6tOA
Nanobots are tiny machines that can perform tasks at the nanoscale level. They are made from DNA and bacteria phages and have sizes around 10-9 meters. Different types of nanobots include respirocytes that act as artificial red blood cells, microbivores that act as white blood cells, and clottocytes that act as platelets. Nanobots have a variety of medical applications such as identifying and destroying cancer cells, clearing artery blockages, and repairing DNA and spinal cord issues. While nanobots show promise for rapid treatment, their replication needs to be carefully controlled and their use presents some economic and technical challenges.
This document discusses the classification and applications of bionanomaterials. It describes how bionanotechnology combines biology with nanotechnology to create new materials and devices. Some key bionanomaterials that are discussed include DNA, amyloid fibrils, actin filaments, aromatic peptides, bacteriophages, minerals, viruses, and enzymes and nucleic acids. Each material is described in terms of its structure, properties, and potential applications in areas like nanotechnology, medicine, and engineering.
lab cultured or in vitro meat is an eco-friendly substitute for the natural meat which eliminates the need for raising and slaughtering animals for food. It supports the sustainable food production and helps to decrease the carbon credit by livestock sector.
Nanobots are microscopic machines that can operate inside the human body. They have potential applications in medicine such as targeted drug delivery, breaking up blood clots and kidney stones, gene therapy, and fighting cancer. Nanobots may one day help cure diseases by performing tasks at the nano scale. While nanobots offer advantages like rapid treatment and low costs, challenges remain around replication control and biocompatibility. Future areas of focus include the central nervous system and more advanced cancer treatments.
NANO TECHNOLOGY IN THE FIELD OF MEDICINEsathish sak
This document discusses the potential applications of nanotechnology in the field of medicine. It describes how medical nanorobots could be used for cell repair by entering cells and tissues to repair damage. These machines would free medicine from solely relying on self-repair for healing. Other potential applications mentioned include targeted drug delivery, correcting genetic disorders, deep anesthesia for surgery, and establishing healthy immune systems and tissue repair. Ongoing research discussed includes using nanoparticles for drug delivery and DNA nanotechnology for electronic devices. Potential issues raised include ensuring nanorobots do not become self-replicating threats.
The document discusses the potential of nanorobots for cancer treatment. It describes how nanorobots could detect cancer cells in early stages using various nanotechnology tools and destroy the cancerous cells while leaving healthy cells unharmed. This would provide a more targeted treatment compared to surgery and chemotherapy, reducing side effects and allowing faster recovery for patients. The document outlines key considerations for designing nanorobots for medical applications like size, structure, communication methods, and biocompatibility.
Stem cell therapy and organoid and 3D bioprintingCandy Swift
This document discusses two emerging techniques in cell therapy: organoids and 3D bioprinting. Organoids are 3D organ models derived from stem cells that mimic native tissue structures and physiology. They allow study of biological processes and have applications in transplantation, research, disease modeling, and drug testing. 3D bioprinting precisely creates living tissues and organs by combining cells, growth factors, and biomaterials in a layer-by-layer process. It has potential applications to produce tissues like skin, bone and blood vessels for transplantation and regenerative medicine. Both organoids and 3D bioprinting are establishing as critical tools in biological research with significant implications for clinical applications.
Nanorobotics is an emerging field that involves creating tiny machines at the nanoscale to perform specific tasks. Some key points:
- Nanorobots are proposed to have applications in medicine such as performing targeted surgeries and drug delivery. They could help minimize tissue damage and side effects compared to traditional therapies.
- Challenges include engineering nanoscale parts and assembling robots, ensuring biocompatibility, and addressing ethical concerns about privacy and misuse.
- If developed successfully, nanorobots may be able to diagnose and treat diseases, monitor health conditions, and potentially end human suffering from many common illnesses. However, significant technological and biological hurdles remain before nanorobots can be
A Review Paper on Latest Biomedical Applications using Nano-Technologyijsrd.com
At present, Nano technology has been improved in many ways but it had improved a lot in the case of Nano Medicine.It also plays a major role in engineering basis. The application of nano technology in medicine is called as Nano medicine. This paper explains the detail regarding Nano medicine. Nano technology has many molecular properties and applications of biological nano structure. These have physical, chemical and biological properties. These are mainly used to diagonize diseases from our body. Nano technology has special application in Nano medicine using Nano robot. This paper relates the use of Nano robots in surgeries. thes Nano robots are not oly safebut also faster. The size of these nano robot is 1-100nm.These use to cure many problems.
The document outlines an iGEM project that aims to detect and remove cadmium from the environment by engineering Bacillus subtilis to sense and sequester cadmium. It describes several subprojects involving building genetic circuits for cadmium sensing, stochastic switching of gene expression, cadmium sequestration using metallothioneins, and modeling the population-level effects of modifying the bacteria's life cycle. The overall goal is to render cadmium bio-unavailable by packaging it inside resilient bacterial spores.
Similar to nanobio technology drug delivery robot Microbivores ppt (20)
Unlocking the mysteries of reproduction: Exploring fecundity and gonadosomati...AbdullaAlAsif1
The pygmy halfbeak Dermogenys colletei, is known for its viviparous nature, this presents an intriguing case of relatively low fecundity, raising questions about potential compensatory reproductive strategies employed by this species. Our study delves into the examination of fecundity and the Gonadosomatic Index (GSI) in the Pygmy Halfbeak, D. colletei (Meisner, 2001), an intriguing viviparous fish indigenous to Sarawak, Borneo. We hypothesize that the Pygmy halfbeak, D. colletei, may exhibit unique reproductive adaptations to offset its low fecundity, thus enhancing its survival and fitness. To address this, we conducted a comprehensive study utilizing 28 mature female specimens of D. colletei, carefully measuring fecundity and GSI to shed light on the reproductive adaptations of this species. Our findings reveal that D. colletei indeed exhibits low fecundity, with a mean of 16.76 ± 2.01, and a mean GSI of 12.83 ± 1.27, providing crucial insights into the reproductive mechanisms at play in this species. These results underscore the existence of unique reproductive strategies in D. colletei, enabling its adaptation and persistence in Borneo's diverse aquatic ecosystems, and call for further ecological research to elucidate these mechanisms. This study lends to a better understanding of viviparous fish in Borneo and contributes to the broader field of aquatic ecology, enhancing our knowledge of species adaptations to unique ecological challenges.
This presentation explores a brief idea about the structural and functional attributes of nucleotides, the structure and function of genetic materials along with the impact of UV rays and pH upon them.
The ability to recreate computational results with minimal effort and actionable metrics provides a solid foundation for scientific research and software development. When people can replicate an analysis at the touch of a button using open-source software, open data, and methods to assess and compare proposals, it significantly eases verification of results, engagement with a diverse range of contributors, and progress. However, we have yet to fully achieve this; there are still many sociotechnical frictions.
Inspired by David Donoho's vision, this talk aims to revisit the three crucial pillars of frictionless reproducibility (data sharing, code sharing, and competitive challenges) with the perspective of deep software variability.
Our observation is that multiple layers — hardware, operating systems, third-party libraries, software versions, input data, compile-time options, and parameters — are subject to variability that exacerbates frictions but is also essential for achieving robust, generalizable results and fostering innovation. I will first review the literature, providing evidence of how the complex variability interactions across these layers affect qualitative and quantitative software properties, thereby complicating the reproduction and replication of scientific studies in various fields.
I will then present some software engineering and AI techniques that can support the strategic exploration of variability spaces. These include the use of abstractions and models (e.g., feature models), sampling strategies (e.g., uniform, random), cost-effective measurements (e.g., incremental build of software configurations), and dimensionality reduction methods (e.g., transfer learning, feature selection, software debloating).
I will finally argue that deep variability is both the problem and solution of frictionless reproducibility, calling the software science community to develop new methods and tools to manage variability and foster reproducibility in software systems.
Exposé invité Journées Nationales du GDR GPL 2024
Current Ms word generated power point presentation covers major details about the micronuclei test. It's significance and assays to conduct it. It is used to detect the micronuclei formation inside the cells of nearly every multicellular organism. It's formation takes place during chromosomal sepration at metaphase.
Phenomics assisted breeding in crop improvementIshaGoswami9
As the population is increasing and will reach about 9 billion upto 2050. Also due to climate change, it is difficult to meet the food requirement of such a large population. Facing the challenges presented by resource shortages, climate
change, and increasing global population, crop yield and quality need to be improved in a sustainable way over the coming decades. Genetic improvement by breeding is the best way to increase crop productivity. With the rapid progression of functional
genomics, an increasing number of crop genomes have been sequenced and dozens of genes influencing key agronomic traits have been identified. However, current genome sequence information has not been adequately exploited for understanding
the complex characteristics of multiple gene, owing to a lack of crop phenotypic data. Efficient, automatic, and accurate technologies and platforms that can capture phenotypic data that can
be linked to genomics information for crop improvement at all growth stages have become as important as genotyping. Thus,
high-throughput phenotyping has become the major bottleneck restricting crop breeding. Plant phenomics has been defined as the high-throughput, accurate acquisition and analysis of multi-dimensional phenotypes
during crop growing stages at the organism level, including the cell, tissue, organ, individual plant, plot, and field levels. With the rapid development of novel sensors, imaging technology,
and analysis methods, numerous infrastructure platforms have been developed for phenotyping.
ESR spectroscopy in liquid food and beverages.pptxPRIYANKA PATEL
With increasing population, people need to rely on packaged food stuffs. Packaging of food materials requires the preservation of food. There are various methods for the treatment of food to preserve them and irradiation treatment of food is one of them. It is the most common and the most harmless method for the food preservation as it does not alter the necessary micronutrients of food materials. Although irradiated food doesn’t cause any harm to the human health but still the quality assessment of food is required to provide consumers with necessary information about the food. ESR spectroscopy is the most sophisticated way to investigate the quality of the food and the free radicals induced during the processing of the food. ESR spin trapping technique is useful for the detection of highly unstable radicals in the food. The antioxidant capability of liquid food and beverages in mainly performed by spin trapping technique.
BREEDING METHODS FOR DISEASE RESISTANCE.pptxRASHMI M G
Plant breeding for disease resistance is a strategy to reduce crop losses caused by disease. Plants have an innate immune system that allows them to recognize pathogens and provide resistance. However, breeding for long-lasting resistance often involves combining multiple resistance genes
Or: Beyond linear.
Abstract: Equivariant neural networks are neural networks that incorporate symmetries. The nonlinear activation functions in these networks result in interesting nonlinear equivariant maps between simple representations, and motivate the key player of this talk: piecewise linear representation theory.
Disclaimer: No one is perfect, so please mind that there might be mistakes and typos.
dtubbenhauer@gmail.com
Corrected slides: dtubbenhauer.com/talks.html
ANAMOLOUS SECONDARY GROWTH IN DICOT ROOTS.pptxRASHMI M G
Abnormal or anomalous secondary growth in plants. It defines secondary growth as an increase in plant girth due to vascular cambium or cork cambium. Anomalous secondary growth does not follow the normal pattern of a single vascular cambium producing xylem internally and phloem externally.
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.
10.
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.