Innovative fragmentation technology

 Introduction of neutral radicals in positive and negative modes





 The OAD-TOF system is equipped with an OAD RADICAL SOURCE I, which enables Oxygen Attachment Dissociation
 (OAD) analysis, an innovative fragmentation that utilizes Shimadzu’s proprietary radical reaction. It can measure
 fragment ions that cannot be obtained by conventional collision-induced dissociation (CID), where ions are fragment -
 ed by collision with an inert gas such as argon or nitrogen. The irradiating oxygen radicals specifically oxidize/dissoci -
 ate double bonds between carbons, which is useful for structure estimation of organic compounds such as lipids. The
 technique can be applied to monovalent ions and negative ions, which have been difficult to fragment using radical
 reactions by electrons and anions, and provides completely new structural information.


 Radical source

 Neutral radicals such as O/OH/H radicals are generated by microwave
 discharge of raw material gases (water vapor and hydrogen gas) in a
 vacuum. The neutral radicals are introduced into the OAD cell   UFaccumulation ™
 through a quartz tube.  UFgrating ™  MCP

 OAD cell
 Precursor ions are reacted with neutral   DL (Desolvation Line)
 radicals generated in a radical source and   UF-Qarray ™
                 What is OAD  (oxygen attachment dissociation)?
 fragmented. A collision gas (argon) can be
 introduced, and conventional CID   CID preferentially dissociates weak chemical bonds. In the case of lipids, CID can determine the basic structure of lipids and
 UF-Lens ™
 fragmentation is also possible by setting   polar groups, and the carbon composition of side chains (number of carbons and double bonds). With OAD, oxygen
 the collision energy (CE).  radicals react specifically with the double bonds between carbons, causing dissociation. By measuring fragment ions
                 specific to the double bond, the position of the double bond can be determined.
 UF-FlightTube ™
 Quadrupole                                       O                  PC 16:0_20:4(n-6, 9, 12, 15)
 Precise temperature control is achieved                      O
 due to an optimized heater and heater   Sub-Interface  N +  O  P  − O  O
 sensor layout and a robust control system.   Heated ESI Probe  O  H  O
 This minimizes the effects of any room                     O
                 OAD ON
 temperature variations to enable stable                                                       [M + H] +
                    100
 mass accuracy over long periods. It also                                                     782.5682
 reduces the time and trouble required for   75
                                                608.3922   648.4234   688.4549   728.4861
 mass calibration.                               n-15       n-12        n-9        n-6
                   % 50
 iRef TOF ™         25                566.3823
 The unique electrode shape achieves an   500  525  550  575  600  625  650  675  700  725  750  775  m/z
 ideal electric potential distribution that
                 OAD OFF
 increases energy-focusing, while also                                                         [M + H] +
 inhibiting trajectory divergence and flight   100                                             782.5702
 time lengthening during ion reflection.  75
                   % 50
 For LCMS-9050, click the button below.  25

 Product             500    525   550    575    600   625    650    675    700   725    750    775  m/z





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