Laser & photonics


Opening page: A highly sensitive plasmonic-fluidic sensor for molecular diagnostics, created by MedPhab.


Equally critical is the optimisation of the filter sets at the detection site. Whether using several individual filters or multi-band sets, they should be optimised with respect to the excitation source. The use of multi-band sets can greatly simplify the optical path, reducing the number of filters and, therefore, the physical space requirements, but they can also compromise optimal signal detection and separation. This is one of the reasons trade-offs exist between cost, efficiency, reliability, precision, and sensitivity. With the increased demand from test labs around the world, companies like Chroma, Iridian, Edmund Optics, Materion and Delta Optical Thin Film readily picked up on the challenge to provide custom optical filters for fluorescence-based instruments in high volumes at low cost.


Miniaturisation of testing and diagnostics devices


While PCR equipment is one of great examples of the power of photonics technologies in medical diagnostics, the pandemic made the acute need to bring testing from the central lab to the point of care more evident, making diagnostics available from the GP’s office and patients’ homes, all the way to remote locations and without easy access to healthcare centres.


Point-of-care (POC) testing devices are not a new idea, but modern technology has enabled a range of new possibilities. Developments within microfluidics, electronics, biochemistry and photonics have allowed for the development of smaller and more accurate tests. Of course, to facilitate the wide adoption of POC devices, they should be easy to use, non- invasive, accurate, user-friendly (for both patients and staff), compact, durable, and sturdy. It’s within these remits that photonics technologies are gaining a dominant role. Due to light-matter interaction, optical sensors allow for non-invasive measurement; in combination with high-sensitivity, quantitative accuracy, and the capacity for multiplexing, this makes them one of the most preferred detection mechanisms. In past years, there were challenges involved in miniaturising technology, while preserving the highest level of performance. But these are being addressed by miniaturised spectrometers, advanced coatings, micro-optics, photonics integrated circuits (PIC) and many other optical technologies that are making their way into POC diagnostics.


Photonics integrated technologies PIC-based biosensors are optical sensors based on guided-wave integrated nanophotonics. The technology is enabling different nanometric-scale elements to guide and control light. The biosensor can be designed on a chip, facilitating high


72


interaction between the optical field and the molecules of interest. The presence of those molecules can be tested by direct detection of the small variations in the refractive index – a measure of how much the path of light is bent, or refracted, when entering a material. The choice of material for PIC-based biosensor depends on the required passive and active elements. SiN is transparent from the visible to the mid-infrared (MIR) spectral range and allows for the measurement of various biomolecules; InP allows for the integration of active elements like high-performance amplifiers, lasers, modulators, and detectors in combination with interferometers within one chip. The integration of SiN PICs with active components based on InP can lead to high- performance systems. Furthermore, PIC technology brings possibilities for miniaturisation, extreme sensitivity, robustness, reliability, the potential for multiplexing and mass production at a low cost. Some companies, like LioniX, already have a PIC- based biosensing platform for the detection of Covid-19 and certain cancer biomarkers in its development pipeline.


Optics and spectroscopy While miniaturisation is one of the central requirements in the development of POC testing and diagnostics devices, the performance quality of all the components must remain high. The complexity of the optical path presents a big challenge. However, micro-optics technologies have demonstrated success when integrated in many medical devices. For instance, companies like Qioptiq, an Excelitas Technology Company have extensive expertise in the design, fabrication and system integration of precision micro-optics for endoscopy, ophthalmology and surgical robotics. There are also alternative solutions for cheap optical components being developed, such as polydimethylsiloxane (PDMS) lenses. PDMS has good optical characteristics and it is heat curable, enabling good control over the curing curvature and the focal length of the lens. PDMS lenses offer sufficient resolution for microscopic imaging. Doped with a silicone dye, PDMS lens can be used as both an emission filter and a lens, negating the need for two separate components and reducing the space required for them. Another way to reduce the space is the development of multi-purpose instruments capable of analysing multiple analytes. Since ultra-compact spectrometers detect a large spectrum – and not only a single wavelength – they are ideal as the optical transducer in multi-purpose instruments. Such spectrometers are developed, for example, by Ibsen Photonics – an OEM supplier of spectrometer modules for instrument integrators. They can deliver


Medical Device Developments / www.nsmedicaldevices.com


Page 1  |  Page 2  |  Page 3  |  Page 4  |  Page 5  |  Page 6  |  Page 7  |  Page 8  |  Page 9  |  Page 10  |  Page 11  |  Page 12  |  Page 13  |  Page 14  |  Page 15  |  Page 16  |  Page 17  |  Page 18  |  Page 19  |  Page 20  |  Page 21  |  Page 22  |  Page 23  |  Page 24  |  Page 25  |  Page 26  |  Page 27  |  Page 28  |  Page 29  |  Page 30  |  Page 31  |  Page 32  |  Page 33  |  Page 34  |  Page 35  |  Page 36  |  Page 37  |  Page 38  |  Page 39  |  Page 40  |  Page 41  |  Page 42  |  Page 43  |  Page 44  |  Page 45  |  Page 46  |  Page 47  |  Page 48  |  Page 49  |  Page 50  |  Page 51  |  Page 52  |  Page 53  |  Page 54  |  Page 55  |  Page 56  |  Page 57  |  Page 58  |  Page 59  |  Page 60  |  Page 61  |  Page 62  |  Page 63  |  Page 64  |  Page 65  |  Page 66  |  Page 67  |  Page 68  |  Page 69  |  Page 70  |  Page 71  |  Page 72  |  Page 73  |  Page 74  |  Page 75  |  Page 76  |  Page 77  |  Page 78  |  Page 79  |  Page 80  |  Page 81  |  Page 82  |  Page 83  |  Page 84  |  Page 85  |  Page 86  |  Page 87  |  Page 88  |  Page 89  |  Page 90  |  Page 91  |  Page 92  |  Page 93  |  Page 94  |  Page 95  |  Page 96  |  Page 97  |  Page 98  |  Page 99  |  Page 100  |  Page 101  |  Page 102  |  Page 103  |  Page 104  |  Page 105  |  Page 106  |  Page 107  |  Page 108  |  Page 109  |  Page 110  |  Page 111  |  Page 112  |  Page 113  |  Page 114  |  Page 115  |  Page 116  |  Page 117  |  Page 118  |  Page 119  |  Page 120  |  Page 121  |  Page 122  |  Page 123  |  Page 124  |  Page 125  |  Page 126  |  Page 127  |  Page 128  |  Page 129  |  Page 130  |  Page 131  |  Page 132  |  Page 133  |  Page 134  |  Page 135  |  Page 136  |  Page 137  |  Page 138  |  Page 139  |  Page 140  |  Page 141  |  Page 142  |  Page 143  |  Page 144  |  Page 145  |  Page 146  |  Page 147  |  Page 148  |  Page 149  |  Page 150  |  Page 151  |  Page 152  |  Page 153  |  Page 154  |  Page 155  |  Page 156  |  Page 157  |  Page 158  |  Page 159  |  Page 160  |  Page 161  |  Page 162  |  Page 163  |  Page 164  |  Page 165  |  Page 166  |  Page 167  |  Page 168  |  Page 169  |  Page 170