posted on 2024-01-08, 15:08authored byPaula Enzian, Nina Kleineberg, Elisabeth Kirchert, Christian Schell, Ramtin Rahmanzadeh
The development of targeted drug delivery mechanisms
in the human
body is a matter of growing interest in medical science. The selective
release of therapeutic agents at a specific target site can increase
the therapeutical efficiency and at the same time reduce the side
effects. Light-sensitive liposomes can release a drug by an externally
controlled light trigger. Liposomes containing photosensitizers that
can be activated in the longer wavelength range (650–800 nm)
are particularly intriguing for medical purposes. This is because
light penetration into a tissue is more efficient within this wavelength
range, increasing their potential applications. For this study, liposomes
with an encapsulated amphiphilic photosensitizer, the porphyrin 5,10-DiOH
(5,10-di(4-hydroxyphenyl)-15,20-diphenyl-21,23H-porphyrin),
its chlorin (5,10-DiOH-chlorin) and its bacteriochlorin (5,10-DiOH-bacteriochlorin)
were synthesized. The porphyrin 5,10-DiOH showed previously effective
cargo release after liposomal encapsulation when irradiated at a wavelength
of 420 nm. The new synthesized chlorin and bacteriochlorin photosensitizers
show additional absorption bands in the longer wavelength range, which
would enable excitation in deeper layers of tissue. Effective cargo
release with chlorin at a longer wavelength of 650 nm and bacteriochlorin
at 740 nm was possible. Irradiation of chlorin allowed more than 75%
of the cargo to be released and more than 60% for bacteriochlorin.
The new liposomes would enable selective drug release in deeper tissue
layers and expand the range of possible applications.