Oxygen Saturation and Blood Volume Analysis by Photoacoustic Imaging to Identify Pre and Post-PDT Vascular Changes

Overview

Journal Saudi J Biol Sci

Specialty Biology

Date 2022 May 16

PMID 35574285

Authors

M Atif

Atif Hanif

M S AlSalhi

S Devanesan

Haya Abdulaziz Altamimi

Affiliations

Soon will be listed here.

Abstract

In this study, the blood volume and oxygen saturation of tumors were measured after photoacoustic imaging (PAI) under conditions of pre-photodynamic therapy (PDT), post-PDT, and 4 hrs, and 24 hrs post-PDT. PDTs with aminolevulinic acid (ALA) and low and high doses of benzoporphyrin derivative (BPD) were conducted to observe oxygen saturation changes, and the rapid oxygen consumption in the blood detected due to the action of BPD at the vascular level resulted in the recovery of PDT completion. Likewise, blood volume changes followed by ALA-PDT and BPD-PDT at low and high doses depicted a fast expansion of the blood volume after treatment. The tumor subjected to a high dose of ALA-PDT showed a partial alteration of Hb-pO in the first 24 hrs, as did the tumors treated with two ALA- and BPD-mediated PDTs. The Hb-pO started reducing immediately post-PDT and was less than 30% after 4 hrs until 24 hrs post-PDT. Reduced vascular demand was possibly due to tumor necrosis, as shown by the permanent damage in the cancer cells' bioluminescence signal. The ALA-mediated PDT-subjected tumor showed a 50% drop in BV at 24 hrs post-PDT, which is suggestive of vascular pruning. The studied data of blood volume against BLI showed the blood volume and oxygenation variations validating the cells' metabolic activity, including cell death.

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