Portable biosensor for air sample

The invention claimed is: 1. A portable biosensor comprising: a sample filter cartridge comprising a 30 μm pore size mesh filter, a 1.0 μm pore size coarse filter, a 0.5 μm pore size medium filter, and a molecular-sieve bead-column; a first air passage; a filter collector; an optical sphere; an electromagnetic radiation emitter; a photo-detector configured to receive electromagnetic spectrum data; a processor in electrical communication with said photo-detector to receive said electromagnetic spectrum data from said photo-detector; a signal display in electrical communication with said processor and configured to provide an indication of said electromagnetic spectrum data; a second air passage; a vacuum pump for drawing an air sample from said sample filter cartridge, through said first air passage, said filter collector, said optical sphere, and said second air passage and out said vacuum pump; a power supply in electrical communication with said electromagnetic radiation emitter, said photo-detector, said processor, said signal display, and said vacuum pump; and a housing that is sized for portability of said biosensor for field use. 2. The biosensor of claim 1 , wherein said electromagnetic radiation emitter further comprises a Raman spectrometer laser diode. 3. The biosensor of claim 2 , wherein said Raman spectrometer laser diode emits a deep ultra-violet radiation wavelength of 180 nm to 250 nm at a sample collected on said filter collector. 4. The biosensor of claim 3 , wherein said sample collected on said filter collector absorbs said radiation and generates Raman-scattering shifts comprising finger-print spectral peaks that are about 30 nm longer than said emitted radiation in a fluorescence-free spectral region. 5. The biosensor of claim 4 , wherein said optical sphere collects and uniformly distributes said Raman-scattering shifts at a wall of said optical sphere, causes said Raman-scattering shifts to exit said optical sphere and to pass through a spectral filter selected from the group consisting of a notch filter, a band-pass filter, and a long-pass spectral filter to produce spectral filtered scattering, wherein said spectral filter blocks scattering radiation produced by said electromagnetic radiation emitter. 6. The biosensor of claim 5 , wherein said spectral filtered scattering is collected, separated, and reflected by a concave holographic flat-field grating onto said photo-detector. 7. The biosensor of claim 6 , wherein said spectral filtered scattering data is collected from said photo-detector and is displayed graphically by said signal display to provide an indication of said electromagnetic spectrum data comprising said Raman-scattering shift data. 8. The biosensor of claim 7 , wherein said Raman-scattering shift data is compared with a database for sample identification. 9. A portable biosensor comprising: a sample filter cartridge comprising a 30 μm pore size mesh filter, a 1.0 μm pore size coarse filter, a 0.5 μm pore size medium filter, and a molecular-sieve bead-column; a filter collector; an optical sphere; a Raman spectrometer laser diode; a photo-detector configured to receive electromagnetic spectrum data; a processor in electrical communication with said photo-detector to receive said electromagnetic spectrum data from said photo-detector; a signal display in electrical communication with said processor and configured to provide an indication of said electromagnetic spectrum data; a vacuum pump; and a power supply. 10. The biosensor of claim 9 , wherein said Raman spectrometer laser diode emits a deep ultra-violet radiation wavelength of 180 nm to 250 nm at a sample collected on said filter collector. 11. The biosensor of claim 10 wherein said sample collected on said filter collector absorbs said radiation and generates Raman-scattering shifts comprising finger-print spectral peaks that are about 30 nm longer than said emitted radiation in a fluorescence-free spectral region. 12. The biosensor of claim 11 , wherein said optical sphere collects and uniformly distributes said Raman-scattering shifts at a wall of said optical sphere, causes said Raman-scattering shifts to exit said optical sphere and to pass through a spectral filter selected from the group consisting of a notch filter, a band-pass filter, and a long-pass spectral filter to produce spectral filtered scattering, wherein said spectral filter blocks scattering radiation produced by said electromagnetic radiation emitter. 13. The biosensor of claim 12 , wherein said spectral filtered scattering is collected, separated, and reflected by a concave holographic flat-field grating onto said photo-detector. 14. The biosensor of claim 11 , wherein said spectral filtered scattering data is collected from said photo-detector and is displayed graphically by said signal display to provide an indication of said electromagnetic spectrum data comprising said Raman-scattering shift data. 15. The biosensor of claim 14 , wherein said Raman-scattering shift data is compared with a database for sample identification. 16. A portable biosensor comprising: a sample filter cartridge comprising a 30 μm pore size mesh filter, a 1.0 μm pore size coarse filter, a 0.5 μm pore size medium filter, and a molecular-sieve bead-column; a first air passage; a filter collector; an optical sphere; an electromagnetic radiation emitter; a photo-detector configured to receive electromagnetic spectrum data; a processor in electrical communication with said photo-detector to receive said electromagnetic spectrum data from said photo-detector; a signal display in electrical communication with said processor and configured to provide an indication of said electromagnetic spectrum data; a second air passage; a vacuum pump for drawing an air sample from said sample filter cartridge, through said first air passage, said filter collector, said optical sphere, and said second air passage and out said vacuum pump; a power supply in electrical communication with said electromagnetic radiation emitter, said photo-detector, said processor, said signal display, and said vacuum pump; and a housing that is sized for portability of said biosensor for field use; wherein said electromagnetic radiation emitter further comprises a Raman spectrometer laser diode that emits a deep ultra-violet radiation wavelength of 180 nm to 250 nm at a sample collected on said filter collector; wherein said sample collected on said filter collector absorbs said radiation and generates Raman-scattering shifts comprising finger-print spectral peaks that are about 30 nm longer than said emitted radiation in a fluorescence-free spectral region; wherein said optical sphere collects and uniformly distributes said Raman-scattering shifts at a wall of said optical sphere, causes said Raman-scattering shifts to exit said optical sphere and to pass through a spectral filter selected from the group consisting of a notch filter, a band-pass filter, and a long-pass spectral filter to produce spectral filtered scattering, wherein said spectral filter blocks scattering radiation produced by said electromagnetic radiation emitter; wherein said spectral filtered scattering is collected, separated, and reflected by a concave holographic flat-field grating onto said photo-detector; wherein said spectral filtered scattering data is collected from said photo-detector and is displayed graphically by said signal display to provide an indication of said electromagnetic spectrum data comprising said Raman-scattering shift data; and wherein said Raman-sc