Nanorobots could potentially be used to treat HIV/AIDS by sensing and removing HIV-infected white blood cells from the body. The nanorobots would use nanosensors to identify infected cells and remove them, maintaining normal white blood cell counts and strengthening the immune system. This theoretical approach could allow for more targeted treatment of AIDS than current drug therapies and increase lifetimes for those infected. The document outlines how nanotechnology and nanorobots may offer new medical applications like diagnostics, targeted drug delivery, and cellular-level medical interventions.
NANO TECHNOLOGY IN THE FIELD OF MEDICINEsathish sak
Medical Nano Robots (Molecular technology and AI)
Will change medicine at its foundations A system INCLUDING NANO COMPUTERS and molecular scale sensors and tools, programmed to repair damage to cells and tissues A fundamental break through : these machines will free medicine from the reliance of self repair as the only path to healing Selective Destruction : example cancerous cells , recognize and destroy a specific kind of cell
Nature's own cell repair machines are limited in their ability
Biology, genetics, nanotechnology, neuroscience, materials science, biotech, ...Brian Russell
Over the past two years I've done a lot of interesting research which I've decided to aggregate. My research pertains to the following: Biology, Genetics, Nanotechnology, Neuroscience, Materials Science, Biotechnology, Chemical Engineering, All Things 3-D, Super Computing, Quantum Physics, Energy, Design, & Sustainability.
NANO TECHNOLOGY IN THE FIELD OF MEDICINEsathish sak
Medical Nano Robots (Molecular technology and AI)
Will change medicine at its foundations A system INCLUDING NANO COMPUTERS and molecular scale sensors and tools, programmed to repair damage to cells and tissues A fundamental break through : these machines will free medicine from the reliance of self repair as the only path to healing Selective Destruction : example cancerous cells , recognize and destroy a specific kind of cell
Nature's own cell repair machines are limited in their ability
Biology, genetics, nanotechnology, neuroscience, materials science, biotech, ...Brian Russell
Over the past two years I've done a lot of interesting research which I've decided to aggregate. My research pertains to the following: Biology, Genetics, Nanotechnology, Neuroscience, Materials Science, Biotechnology, Chemical Engineering, All Things 3-D, Super Computing, Quantum Physics, Energy, Design, & Sustainability.
Paper Biology 280 S Minireview Advances In Cancer Detection And TherapeuticsJoshua Mendoza-Elias
Abstract:
Nanotechnology is a field that has made significant advances in the engineering of technologies that allow earlier detection and treatment of disease – specifically cancer. In the modern era, these technologies define the emerging field of nanomedicine and seek to redefine detection and treatment with the promise of more effective, sensitive and cost effective high throughput systems. Compared to conventional treatment options, these next generation cancer therapeutics also seek to overcome the invasiveness of surgery, chemotherapy, radiotherapy, immunotherapy, and hormonal therapy. These technologies include nanoshells, quantum-dots, ultraoxide particles, DNA microarrays, liposomes, dendrimers, and fullerines. Highlighted in this paper, microwires and microcantilevers (“biofinger”) show promise in becoming multiplex platforms (“Labs on a chip”) that detect a variety of biological markers at low concentration in real time. In addition, DNA based diagnostic computer constructs (DNAdc) that release therapeutic nucleic acid sequences in a gene expression specific manner will be highlighted as well. The potential for a wide range of clinical applications to disease, including cancer, makes a basic understanding of the field of nanomedicine important to the biomedical sciences. In addition, nanomedicine will have a huge impact in developing a repertoire of nano-based therapeutics for other diseases.
Keywords: “Biofinger”-lab on a chip, DNA diagnostic computer construct (DNAdc), DNA microarrays, nanoshells, quantum-dots, ultraoxide particles, liposomes, dendrimers, fullerines, single wall carbon nanotubes (SWNT).
Advance in technology have increased our ability to manipulate the world around us on an ever –decreasing scale .
Nanotechnologies are rapidly emerging within the realm of medicine , and this subfield has been termed NANO medicine .
Use of nanoparticle technology has become familiar and increasingly commonplace , especially with pharmaceutical technology .
An exciting and promising area of NANO technological development is the building of NANO robots ,which are devices with components manufactured on the NANO scale.
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.
BIOENGINEERED NANOROBOTICS FOR CANCER THERAPY Sivajith007
A person who is diagnosed with cancer will be offered a new alternative to chemotherapy because the traditional treatment of radiation that kills not just cancer cells but healthy human cells as well, causing hair loss, fatigue, nausea, depression, and a host of other symptoms. The application of nanorobotics can be considered as the better solution to this problems. Nanorobots are nanoelectromechanical systems designed to perform a specific task with precision at nanoscale dimensions. This technique involves the development of fully functional nanorobots capable of sensing, decision making, and actuation. From a bio inspired perspective, those in nanorobotics, including core design, propulsion and power generation, sensing, actuation, control, decision making, and system integration. The core of the nanorobots is a polysaccharide based nanoparticle, sensing and actuation ensure that it is capable of sensing and recognizing the cancer cell. These nanorobots may aid in cancer therapy, site-specific drug delivery, circulating diagnostics, advanced surgery, and tissue repair. One of the major advantages of nanorobots is it will not affect healthy cells in human body. Using strategies inspired from microorganisms, potential bioengineered nanorobots can be used for cancer therapy.
Paper Biology 280 S Minireview Advances In Cancer Detection And TherapeuticsJoshua Mendoza-Elias
Abstract:
Nanotechnology is a field that has made significant advances in the engineering of technologies that allow earlier detection and treatment of disease – specifically cancer. In the modern era, these technologies define the emerging field of nanomedicine and seek to redefine detection and treatment with the promise of more effective, sensitive and cost effective high throughput systems. Compared to conventional treatment options, these next generation cancer therapeutics also seek to overcome the invasiveness of surgery, chemotherapy, radiotherapy, immunotherapy, and hormonal therapy. These technologies include nanoshells, quantum-dots, ultraoxide particles, DNA microarrays, liposomes, dendrimers, and fullerines. Highlighted in this paper, microwires and microcantilevers (“biofinger”) show promise in becoming multiplex platforms (“Labs on a chip”) that detect a variety of biological markers at low concentration in real time. In addition, DNA based diagnostic computer constructs (DNAdc) that release therapeutic nucleic acid sequences in a gene expression specific manner will be highlighted as well. The potential for a wide range of clinical applications to disease, including cancer, makes a basic understanding of the field of nanomedicine important to the biomedical sciences. In addition, nanomedicine will have a huge impact in developing a repertoire of nano-based therapeutics for other diseases.
Keywords: “Biofinger”-lab on a chip, DNA diagnostic computer construct (DNAdc), DNA microarrays, nanoshells, quantum-dots, ultraoxide particles, liposomes, dendrimers, fullerines, single wall carbon nanotubes (SWNT).
Advance in technology have increased our ability to manipulate the world around us on an ever –decreasing scale .
Nanotechnologies are rapidly emerging within the realm of medicine , and this subfield has been termed NANO medicine .
Use of nanoparticle technology has become familiar and increasingly commonplace , especially with pharmaceutical technology .
An exciting and promising area of NANO technological development is the building of NANO robots ,which are devices with components manufactured on the NANO scale.
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.
BIOENGINEERED NANOROBOTICS FOR CANCER THERAPY Sivajith007
A person who is diagnosed with cancer will be offered a new alternative to chemotherapy because the traditional treatment of radiation that kills not just cancer cells but healthy human cells as well, causing hair loss, fatigue, nausea, depression, and a host of other symptoms. The application of nanorobotics can be considered as the better solution to this problems. Nanorobots are nanoelectromechanical systems designed to perform a specific task with precision at nanoscale dimensions. This technique involves the development of fully functional nanorobots capable of sensing, decision making, and actuation. From a bio inspired perspective, those in nanorobotics, including core design, propulsion and power generation, sensing, actuation, control, decision making, and system integration. The core of the nanorobots is a polysaccharide based nanoparticle, sensing and actuation ensure that it is capable of sensing and recognizing the cancer cell. These nanorobots may aid in cancer therapy, site-specific drug delivery, circulating diagnostics, advanced surgery, and tissue repair. One of the major advantages of nanorobots is it will not affect healthy cells in human body. Using strategies inspired from microorganisms, potential bioengineered nanorobots can be used for cancer therapy.
Bionanotechnology and its applications rita martin
Bionanotechnology combination of biotechnology and nanotechnology. Find its applications in various fields Nanotherapeutics, Gene therapy , Immunotherapy, Harmless Viruses, stem cells
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. ANTI – HIV USING NANO ROBOTS
ABSTRACT: disease and it constitutes 10% of the total
Nanorobots are nano devices that will be infected. We are doing research on this paper and
use for the purpose of maintaining and we hope that this theoretical approach can be
protecting the human body against pathogens. made practical in the near future, so that the
Nano is one billionth of one centimeter. killer disease AIDS could also be made in control
Nanotechnology is the technology in which the on the hands of Human with the emerging new
operations are performed on nano metrics. It is technology like NANOTECHONOLOGY which
the application of different technologies has Bio-medical Application.
primarily interested in the reduction of size.
INTRODUCTION
The credential part of this paper gives the
AIDS:
theoretical application of nanodevices in the
Acquired Immuno deficiency Syndrome (AIDS),
treatment of AIDS. There is no technology for the human viral disease that ravages the immune system,
treatment of AIDS. Some of the drugs of specific undermining the body’s ability to defend itself from
composition are given to the patients depending infection and disease. Caused by the human
on the intensity of the disease. The drugs using immunodeficiency virus (HIV), AIDS leaves an infected
nowadays are able to increase the lifetime to a few person vulnerable to opportunistic infections. Such
years only. To make the treatment more specific, infections are harmless in healthy people, but in those whose
we use the nanodevices that use nanosensors to immune systems have been greatly weakened, they can prove
fatal. Our paper aims at the removal of the virus to from the
sense the AIDS infected WBC’s. In this we are
RNA of the body using the nanorobots.
using Nanorobots to get back the HIV infected
WBC’s. By doing so constant levels of WBC’s are HIV: Human Immunodeficiency Virus
maintained in the blood stream. Thus the AIDS The human immunodeficiency virus (HIV),
patient is provided with the immune system so which causes acquired immunodeficiency syndrome
that he can defend himself from diseases. (AIDS), principally attacks CD4 T-cells, a vital part of
the human immune system.
In this paper only a theoretical analysis
is given and all the information provided are
specifically organized by us. In India more than
50 lakhs of people are infected by this dreaded
2. cells within a living body. Miniaturization will allow the
tools for many different tests to be situated together on the
same small device. This means that nanotechnology could
make it possible to run many diagnostic tests
simultaneously as well as with more sensitivity. In
general, nanotechnology may offer a faster and more
efficient means for us to do much of what we do now.
NANOMEDICINE:
The emerging field of nanorobotics is aimed at
overcoming the shortcomings present in the traditional
way of treatment of patients. Our bodies are filled with
intricate, active molecular structures. When those
structures are damaged, health suffers. Modern medicine
can affect the work of the body in many ways, but from a
molecular viewpoint it remains crude. Molecular
manufacturing can construct a range of medical
instruments and devices with greater abilities. The human
body can be seen as a work yard, construction site, and
battleground form molecular machines. It works
remarkably well; using systems so complex that medical
science still doesn’t understand many of them.
BIOMEDICAL APPILICATIONS OF NANOROBOTS:
The enormous potential in the biomedical
capabilities of nanorobots and the imprecision and side
effects of medical treatments today make nanorobots very
desirable. But today, in this revolutionary era we propose
for Nonomedical robots, since they will have no difficulty
in identifying the target site cells even at the very early
stages which cannot be done in the traditional treatment
and will ultimately be able to track them down and destroy
them wherever they may be growing. By having these
Robots, we can refine the treatment of diseases by using
biomedical, nanotechnological engineering.
Nanorobot designed to perform cell surgery
NANOTECHNOLOGY:
Nano is one billionth of one centimeter. Now we
have the so-called microprocessors and microarray
technology that would reach the Nano level within a
few decades, we suppose. Some call this technology to
be nanotechnology and some Others name it the
molecular nanotechnology, to be specific.
REASONS FOR APPLYING NANOTECH TO
BIOLOGICAL SYSTEMS:
Most animal cells are 10,000 to 20,000 nanometers WHAT IS A MEDICINAL NANOROBOT?
in diameter. This means that nanoscale devices (having at
least one dimension less than 100 nanometers) can enter Nanorobots are theoretical microscopic
cells and the organelles inside them to interact with DNA devices measured on the scale of nanometers (1 nm
and proteins. Tools developed through nanotechnology equals one millionth of a millimeter). When fully
may be able to detect disease in a very small amount of realized from the hypothetical stage, they would work
cells or tissue. They may also be able to enter and monitor at the atomic, molecular and cellular level to perform
3. tasks in both the medical and industrial fields that have harmless effluent of amino acids, mononucleotides,
been the stuff of science Nanomedicine’s nanorobots fatty acids and sugars. No matter that a bacterium has
are so tiny that they can easily traverse the human body. acquired multiple drug resistance to antibiotics or to
Scientists report the exterior of a nanorobot will likely any other traditional treatment. The microbivore will
be constructed of carbon atoms in a diamondoid eat it anyway, achieving complete clearance of even
structure because of its inert properties and strength. the most severe septicemic infections in minutes to
Super-smooth surfaces will lessen the likelihood of hours, as compared to weeks or even months for
triggering the body’s immune system, allowing the antibiotic-assisted natural phagocytic defenses,
nanorobots to go about their business unimpeded. without increasing the risk of sepsis or septic shock.
Glucose or natural body sugars and oxygen might be a Related nanorobots could be programmed to
source for propulsion, and the nanorobot will have recognize and digest cancer cells, or to clear
other biochemical or molecular parts depending on its circulatory obstructions within minutes in order to
task. rescue stroke patients from ischemic damage.
NANOROBOT IN NANOSCALE
More sophisticated medical nanorobots will be able
to intervene at the cellular level, performing surgery
within cells. Physician-controlled nanorobots could
extract existing chromosomes from a diseased cell and
insert newly manufactured ones in their place, a process
called chromosome replacement therapy. This would
allow a permanent cure of any pre-existing genetic
disease, and permit cancerous cells to be reprogrammed
to a healthy state
IMPLEMENTATION:
ANTI - HIV USING NANOTECHNOLOGY:
According to current theories, nanorobots will possess AIDS:
at least rudimentary two-way communication; will
respond to acoustic signals; and will be able to receive The virus responsible for the condition known as
power or even re-programming instructions from an AIDS (Acquired Immunodeficiency Syndrome), is named
external source via sound waves. A network of special HIV (Human Immunodeficiency Virus). AIDS is the
stationary nanorobots might be strategically positioned condition whereby the body's specific defense system
throughout the body, logging each active nanorobot as against all infectious agents no longer functions properly.
it passes, and then reporting those results, allowing an
interface to keep track of all of the devices in the body.
There is a focused loss over time of immune cell
A doctor could not only monitor a patient’s progress but
function, which allows intrusion by several different
change the instructions of the nanorobots in vivo to
infectious agents, the result of which is loss of the ability
progress to another stage of healing. When the task is
of the body to fight infection and the subsequent
completed, the nanorobots would be flushed from the
acquisition of diseases such as pneumonia.
body.
The immune system is a system within all vertebrates
Nanorobots performing operations on blood cells
(animals with a backbone) which in general terms, is
comprised of two important cell types: the B-cell and the
T-cell.
Nanorobotic phagocytes called microbivores could
patrol in the bloodstream, seeking out and digesting The B-cell is responsible for the production of
unwanted pathogens including bacteria, viruses or antibodies (proteins which can bind to specific molecular
fungi. Each nanorobot could completely destroy one shapes), and the T-cell (two types) is responsible either for
pathogen in just 30 seconds - about 100 times faster helping the B-cell to make antibodies, or for the killing of
than natural leukocytes or macrophages - releasing a
4. damaged or "different" cells (all foreign cells except Th2 helperT-cellsub-populations.
bacteria) within the body. The two main types of T-cells
are the "helper"T-cell and the cytotoxic T-cell. The T- OPERATION OF HIV:
helper population is further divided into those which help
B-cells (Th2) and those which help cytotoxic T-cells
How HIV Specifically Affects the Immune System
(Th1). Therefore, in order for a B-cell to do its job
Remember about the proteins, which are part of the
requires the biochemical help of Th2 helper T-cells; and,
envelope of HIV? Well, one of these proteins, named gp
for a cytotoxic T-cell to be able to eliminate a damaged
120, (a sugar-containing protein called a glycoprotein, of
cell (say, a virally-infected cell), requires the biochemical
approximately 120,000 molecular weight), "recognizes" a
help of a Th1 helper T-cell.
protein on helper T-cells named CD4, and physically
associates with it. The CD4 [Cluster of Differentiation
Antigen No. 4] protein is a normal part of a helper (both
Th1 and Th2) T-cell's membrane.
METHOD OF INFECTION OF HIV:
Thus, CD4 is a specific receptor for HIV. This
virus however, can also infect other cells which include
IMMUNESYSTEM: macrophages and certain other kinds of cells which can
engulf substances through a process known as
Whenever any foreign substance or agent enters phagocytes. As a consequence of the interaction with CD4
our body, the immune system is activated. Both B- and T- on helper T-cells, HIV specifically infects the very cells
cell members respond to the threat, which eventually necessary to activate both B-cell and cytotoxic T-cell
results in the elimination of the substance or agent from immune responses. Without helper T-cells, the body
our bodies. If the agent is one which goes inside one of cannot make antibodies properly, nor can infected cells
our cells and remains there most of the time (intracellular containing HIV (an intracellular pathogen) be properly
pathogens like viruses or certain bacteria which require eliminated. Consequently, the virus can: multiply, kill the
the inside of one of our cells in order to live), the "best" helper T-cell in which it lives, infect adjacent helper T-
response is the activation of cytotoxic T-cells (circulate in cells, repeat the cycle, and on and on, until eventually
the bloodstream and lymph), which eliminate the agent there is a substantial loss of helper T-cells.
through killing of the cell which contains the agent (agent
is otherwise "hidden"). Both of these kinds of responses The fight between the virus and the immune
(B-cell or cytotoxic T-cell) of course require specific system for supremacy is continuous. Our body responds
helper T-cell biochemical information as described above. to this onslaught through production of more T-cells, some
Usually, both B-cell and cytotoxic T-cell responses occur of which mature to become helper T-cells. The virus
against intracellular agents which provide a two-pronged eventually infects these targets and eliminates them, too.
attack. Normally, these actions are wonderfully protective
of us. The effect of HIV on the immune system is the More T-cells are produced; these too become
result of a gradual (usually) elimination of the Th1 and infected, and are killed by the virus. This fight may