New method for measuring luminescence lifetime offers breakthrough in scientific imaging

Ac­cel­er­at­ing the pace of dis­cov­ery in sci­ence and in­dustry

22-Oct-2024
Soeren Ahmerkamp, Max Planck Institute for Marine Microbiology

A specimen of the seaweed Fucus serratus and the oxygen concentrations on its surface.

Re­search­ers at the Max Planck In­sti­tute for Mar­ine Mi­cro­bi­o­logy, Leib­niz-In­sti­tute for Baltic Sea Re­search and Uni­versity of Copen­ha­gen in­tro­duce an in­nov­at­ive ap­proach to im­age lu­min­es­cence life­times. This simple ap­proach uses read­ily-avail­able cost-ef­fect­ive equip­ment, pav­ing the way for ad­vanced stud­ies of chem­ical dy­nam­ics in en­vir­on­mental and bio­lo­gical sys­tems. For ex­ample, it al­lows to re­cord oxy­gen dy­nam­ics with much higher tem­poral and spa­tial pre­ci­sion.

Soeren Ahmerkamp, Max Planck Institute for Marine Microbiology

The setup of the novel approach for imaging the lifetime of luminescent dyes which is based on the frame-straddling technique and allows for an easy implementation.

Take oxy­gen, for ex­ample: Oxy­gen is a key mo­lecule for life, and in or­der to un­der­stand eco­sys­tem dy­nam­ics it can be im­port­ant to fol­low its ways in much de­tail. Op­tical sensors that use lu­min­es­cent dyes have long been used to map oxy­gen levels in mar­ine sys­tems: Oxy­gen re­duces the phos­phor­es­cence life­times of the dyes, which thus in­dic­ate oxy­gen con­cen­tra­tions. However, un­til now, ima­ging lu­min­es­cence life­times has re­quired costly, spe­cial­ized equip­ment, mak­ing the tech­nique out of reach for many re­search and in­dus­trial ap­plic­a­tions. A joint re­search team at the Max Planck In­sti­tute for Mar­ine Mi­cro­bi­o­logy, Leib­niz-In­sti­tute for Baltic Sea Re­search and Uni­versity of Copen­ha­gen, in col­lab­or­a­tion with in­ter­na­tional part­ners, has de­veloped a pi­on­eer­ing method for ima­ging the life­time of lu­min­es­cent sig­nals. The break­through tech­nique en­ables high-speed lu­min­es­cence life­time meas­ure­ments, trans­form­ing fields that rely on op­tical sens­ing and chem­ical ima­ging. The find­ings have been pub­lished in the journal ACS Sensors.

Bring­ing lu­min­es­cence life­time meas­ure­ment to the masses

“Our new in­teg­rated method sim­pli­fies these meas­ure­ments, al­low­ing re­search­ers to de­term­ine lu­min­es­cence life­times us­ing stand­ard cam­era sys­tems”, ex­plains So­eren Ah­merkamp, who car­ried out the re­search at the Max Planck In­sti­tute for Mar­ine Mi­cro­bi­o­logy in Bre­men and at the Leib­niz-In­sti­tute for Baltic Sea Re­search in Warnemünde, both in Ger­many. By syn­chron­iz­ing short bursts of light with pre­cise cam­era tim­ing through a tech­nique called frame-strad­dling, two im­ages are cap­tured: One that re­cords the ini­tial light burst and an­other that meas­ures the ini­tial light burst and the longer-last­ing lu­min­es­cent after-glow. The dif­fer­ence between these im­ages re­veals the in­teg­rated lu­min­es­cence life­time, provid­ing a de­tailed and ac­cur­ate readout at time scales be­low one mil­li­second.

“We of­fer a more ac­cess­ible way to meas­ure lu­min­es­cence life­times, which is of­ten con­sidered the gold stand­ard in op­tical sens­ing”, says Mi­chael Kühl from the Uni­versity of Copen­ha­gen, Den­mark. “By ad­opt­ing the frame-strad­dling tech­nique ori­gin­ally de­veloped for high-speed flow meas­ure­ments, we’ve cre­ated a tech­nique that can be used with a wide range of com­mer­cially avail­able cam­eras. This will make it pos­sible for a wider range of labor­at­or­ies to per­form high-res­ol­u­tion life­time ima­ging.”

Un­lock­ing new pos­sib­il­it­ies in chem­ical ima­ging

The abil­ity to meas­ure lu­min­es­cence life­times with ease and high-speed opens up new pos­sib­il­it­ies for chem­ical ima­ging. Re­search­ers can now re­cord oxy­gen dy­nam­ics with much higher tem­poral and spa­tial pre­ci­sion. “We tracked oxy­gen dy­nam­ics around al­gae within a hun­dredth of a second and visu­al­ized how oxy­gen-con­sum­ing particles move through wa­ter, thereby show­cas­ing the util­ity of the method”, says Ah­merkamp. “The in­teg­rated lu­min­es­cence de­cay method can be used to gain deeper in­sights into how oxy­gen var­ies in mar­ine en­vir­on­ments, from the scale of mi­cro­scopic particles to en­tire eco­sys­tems.”

Ac­cel­er­at­ing the pace of dis­cov­ery in sci­ence and in­dustry

This new ap­proach could stim­u­late more lu­min­es­cence life­time ima­ging ap­plic­a­tions in en­vir­on­mental and bio­med­ical sci­ences and en­gin­eer­ing. By mak­ing high-pre­ci­sion meas­ure­ments more ac­cess­ible, it can stim­u­late novel ex­per­i­mental ap­proaches, ac­cel­er­at­ing the pace of dis­cov­ery in these areas.

“Our goal was to demo­crat­ize ac­cess to a power­ful ana­lyt­ical tool,” adds Ah­merkamp. “We be­lieve this method will en­able re­search­ers to ex­plore com­plex chem­ical in­ter­ac­tions with greater ease and flex­ib­il­ity than ever be­fore.”

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