SBIR/STTR Award attributes
ThisproposalaimstodevelopanewgenerationofhighspeedlowcostmicroelectromechanicalsystemsverticalcavitysurfaceemittinglasersMEMSVCSELsforopticalcoherencetomographyOCTatmultiMHzaxial scanratesTheproposedeffortinvolvesacollaborationbetweenPraeviumResearchwithexpertiseinMEMSVCSELdevelopmentandtheMassachusettsInstituteofTechnologyMITaleaderinOCTsystemintegrationandOCTimagingTheseultrahighspeedimagingsystemsenablenewinvivofundamentalandclinicalimagingapplicationsatlargerfieldsofviewandfinerresolutionsthanwerepreviouslypossibleMultiMHzoperationisparticularlycriticalforadvancingOCTincancerstudieswhichrequirehighspeedforlargevolume imaging of microstructureand dense sampling for angiographic imagingOCTAand optical coherencemicroscopyOCMThe proposed lowcost laser will make these high performance technologies widely availableto the fundamental and clinical cancer research communitiesPraevium Research will focus on the development of the new highspeedlowcost MEMSVCSEL swept lasersourceMEMSVCSELshaverecentlyemergedasanearideallaserforOCTThesedevicesofferauniquecombinationofwidetuningrangehighandvariabletuningspeeddynamicsinglemodeoperationenablingmeterscaleimagingrangeandthepotentialforlowcostenabledbymonolithicwaferscalefabricationandtestingThe proposed work seeks to push MEMSVCSEL technology toMHz axial scan rates in a monolithicdesignwith multiple approaches to actuator design and packaging to optimize laser speedstuning rangeandsweeplinearityTheseeffortswillsignificantlyreducemanufacturingcostprovidingthefirstvolumescalablecommercially available swept source for multiMHz OCTto enable axx speed improvement over existingcommercial OCT instruments at a fraction of the cost of current swept source technologiesMITwillintegratethenewlightsourcewithstateoftheartdataacquisitionandprocessingandwithnewendoscopic probe technology to demonstrate in vivo imaging in patients with gastrointestinal pathologiesNewultrahigh speed OCT system designs involving laser sweep multiplexing and linearizationand low latency OCTprocessinganddisplaywillbeinvestigatedforperformanceandfeasibilityMicromotorprobestetheredcapsulesand piezoelectric scanners will be developed for compact and highprecision optical imagingMIT willdemonstrateendoscopicapplicationsofthesetechnologiesinpreclinicalstudieswhileinvestigatingsystemparametersanddesignsforoptimizedperformancetoestablishworkflowandimagingprotocolsforpotentialfuture clinical applicationsIn an existing collaboration with the Boston Veterans Affairs Medical CenterMIT willfurtherdemonstratestudiesinpatientswithupperandlowergastrointestinaltractpathologiesassessingcapabilities for wide field coverage of mucosal structure and vasculatureand cellular morphologyThese effortswill motivate development in many other endoscopiclaparoscopicor surgical applicationsThiseffortisexpectedtoimpactpublichealthbyadvancinganewhighperformancelowcostclinicaltoolcapableofthreedimensionalimagingoftissueoverlargevolumeswithhighresolutionforassessmentofpathologywithouttheneedfortissueexcisionusingopticalcoherencetomographyOCTTheproposedtechnology will operate at leastxx faster than the imaging speed of existing commercial OCT instrumentsand is enabled by a new compact wavelength tunable semiconductor laser technology coupled with advancedinstrumentation and endoscopic optical probe technologiesThe high performance enables threedimensionalmicroscopic visualization of tissue structureblood vasculatureand cells in gastrointestinal and other systemswhile the low cost will make these capabilities widely available to the fundamental and clinical cancer researchcommunitieswith many cancer applications in endoscopy and surgery
