Department of BME, REC


               OUT COMES:
               On completion of the course the students will be able to
                  •  Obtain domain knowledge in understanding various Medical Imaging techniques
                  •  Design various tomography units taking into consideration the various safety
                  •  procedures
                  •  Analyze medical images
                  •  Apply various segmentation techniques for medical image classification
                  •  Design suitable algorithm for classification

               REFERENCES:
                   1.  Chesney  D.N~  and  Chesney  M.O., X-Ray  Equipments for  Students  Radiographer,
                       Blackwell Scientific Publications, Oxford, 1971
                   2.  Alexander,  Kalender  and  Linke,  Computer  Tomography,  John  Wiley,  Chich~ster,
                       1986.
                   3.  Steve Webb, The Physics of Medical Imaging, Adam Hilger, Philadelpia, 1988.
                   4.  Peggy.  W,  Roger.D.Ferimarch,  MRI  for  Technologists,  Mc  Graw  Hill  Publications,
                       New York, 1995.
                   5.  Wolfgang  Birkfellner,  ‘Applied  Medical  Image  Processing  –  A  Basic  course’,  CRC
                       Press, 2011.
                   6.  Atam P. Dhawan, ‘Medical Image Analysis’, Wiley Interscience Publication, NJ, USA
                       2003.
                   7.  R.C.Gonzalez and R.E.Woods, ‘Digital Image Processing’, Second Edition, Pearson
                       Education, 2002.



               MX19202                                        BIOPHOTONICS                         L T P C

                                                                                                   3  0  0  3
               OBJECTIVES
                   •  To understand optical properties of tissues
                   •  Learn fluorescence application in biomedical engineering
                   •  Learn optoelectronic technique for diagnosis and treatment

               UNIT I          BASICS OF LIGHT-MATTER INTERACTION                                     9
               Nature of light and matter, Refraction, reflection, interference, diffraction, intensity, phase,
               polarization,  scattering,  Raman  effect,  fluorescence,    Light  transport  inside  the  tissue,
               Optical microscopy – fluorescence, confocal and multi photon.

               UNIT II        FLUORESCENCE TECHNIQUES                                                 9
               Fluorescence  Spectroscope,  Fluorescence  Resonance  Energy  Transfer  (FRET)  Imaging,
               Fluorescence  Lifetime  Imaging  Microscopy  (FLIM),  Fluorophores  as  Bioimaging  probes  –
               endogenous  fluorophores,  exogenous  fluorophores,    two-photo  fluorophores,    Tissue
               imaging,

               UNIT III       LASERS IN MEDICINE                                                      9
               Introduction,  Laser  physics,  medical  lasers,  Laser  interaction  with  tissue,  photoabalative
               process, application of Lasers in Diagnosis and Imaging, Laser surgery and therapy, thermal
               interaction between laser and Tissue. Integrated laser-fiber systems and their applications in
               medicine -  cardiovascular disease, Gastroenterology, thoracic surgery, Neurosurgery and
               Oncology,  Laser safety fundamentals




               R 2019 - Curriculum and Syllabus/ M.E Medical Electronics                          Page 17