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Nanorobot Hardware Architecture for Medical Defense

View Article: PubMed Central

ABSTRACT

This work presents a new approach with details on the integrated platform and hardware architecture for nanorobots application in epidemic control, which should enable real time in vivo prognosis of biohazard infection. The recent developments in the field of nanoelectronics, with transducers progressively shrinking down to smaller sizes through nanotechnology and carbon nanotubes, are expected to result in innovative biomedical instrumentation possibilities, with new therapies and efficient diagnosis methodologies. The use of integrated systems, smart biosensors, and programmable nanodevices are advancing nanoelectronics, enabling the progressive research and development of molecular machines. It should provide high precision pervasive biomedical monitoring with real time data transmission. The use of nanobioelectronics as embedded systems is the natural pathway towards manufacturing methodology to achieve nanorobot applications out of laboratories sooner as possible. To demonstrate the practical application of medical nanorobotics, a 3D simulation based on clinical data addresses how to integrate communication with nanorobots using RFID, mobile phones, and satellites, applied to long distance ubiquitous surveillance and health monitoring for troops in conflict zones. Therefore, the current model can also be used to prevent and save a population against the case of some targeted epidemic disease.

No MeSH data available.


Military strategic and tactical relay satellites can use ultra high frequency for long distance epidemic monitoring and control, back tracking information from the mobile phone. Communication interface provides person identification and position, using nanorobots with PDA smart cell phone.
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f10-sensors-08-02932: Military strategic and tactical relay satellites can use ultra high frequency for long distance epidemic monitoring and control, back tracking information from the mobile phone. Communication interface provides person identification and position, using nanorobots with PDA smart cell phone.

Mentions: The application of ultra-high frequency satellite communications network can be successfully applied for nanorobot data transmission, using wireless phones for long distance communication [7,68,69,107]. The cell phone PDA (personal digital assistant) system provides also the person's identification with respective position for the moment the nanorobot detected some virus protein profile (Fig. 10).


Nanorobot Hardware Architecture for Medical Defense
Military strategic and tactical relay satellites can use ultra high frequency for long distance epidemic monitoring and control, back tracking information from the mobile phone. Communication interface provides person identification and position, using nanorobots with PDA smart cell phone.
© Copyright Policy
Related In: Results  -  Collection

License
Show All Figures
getmorefigures.php?uid=PMC3675524&req=5

f10-sensors-08-02932: Military strategic and tactical relay satellites can use ultra high frequency for long distance epidemic monitoring and control, back tracking information from the mobile phone. Communication interface provides person identification and position, using nanorobots with PDA smart cell phone.
Mentions: The application of ultra-high frequency satellite communications network can be successfully applied for nanorobot data transmission, using wireless phones for long distance communication [7,68,69,107]. The cell phone PDA (personal digital assistant) system provides also the person's identification with respective position for the moment the nanorobot detected some virus protein profile (Fig. 10).

View Article: PubMed Central

ABSTRACT

This work presents a new approach with details on the integrated platform and hardware architecture for nanorobots application in epidemic control, which should enable real time in vivo prognosis of biohazard infection. The recent developments in the field of nanoelectronics, with transducers progressively shrinking down to smaller sizes through nanotechnology and carbon nanotubes, are expected to result in innovative biomedical instrumentation possibilities, with new therapies and efficient diagnosis methodologies. The use of integrated systems, smart biosensors, and programmable nanodevices are advancing nanoelectronics, enabling the progressive research and development of molecular machines. It should provide high precision pervasive biomedical monitoring with real time data transmission. The use of nanobioelectronics as embedded systems is the natural pathway towards manufacturing methodology to achieve nanorobot applications out of laboratories sooner as possible. To demonstrate the practical application of medical nanorobotics, a 3D simulation based on clinical data addresses how to integrate communication with nanorobots using RFID, mobile phones, and satellites, applied to long distance ubiquitous surveillance and health monitoring for troops in conflict zones. Therefore, the current model can also be used to prevent and save a population against the case of some targeted epidemic disease.

No MeSH data available.