Real-time analysis of magnetic nanoparticle clustering effects by inline-magnetic particle spectroscopy

“…The present study identifies key input parameters contributing to FMMD signal generation from isolated parameter variation; however, the following limitations are faced, which we will directly turn into potential improvements for future investigations: As identified in Section 4.1 (discussing the -dependence), the present simulation framework does not consider particle agglomeration/clustering. However, it is becoming more and more evident that agglomerations (or clusters) play a significant role in MNP systems, either globally (non-directional) [ 62 , 63 ] or as a precondition by purposeful alignment of MNP [ 64 , 65 ]. Recently, it has been demonstrated that agglomeration in a similar simulation framework can be included [ 66 ].…”

“…As identified in Section 4.1 (discussing the -dependence), the present simulation framework does not consider particle agglomeration/clustering. However, it is becoming more and more evident that agglomerations (or clusters) play a significant role in MNP systems, either globally (non-directional) [ 62 , 63 ] or as a precondition by purposeful alignment of MNP [ 64 , 65 ]. Recently, it has been demonstrated that agglomeration in a similar simulation framework can be included [ 66 ].…”

Key Contributors to Signal Generation in Frequency Mixing Magnetic Detection (FMMD): An In Silico Study

“…The present study identifies key input parameters contributing to FMMD signal generation from isolated parameter variation; however, the following limitations are faced, which we will directly turn into potential improvements for future investigations: As identified in Section 4.1 (discussing the -dependence), the present simulation framework does not consider particle agglomeration/clustering. However, it is becoming more and more evident that agglomerations (or clusters) play a significant role in MNP systems, either globally (non-directional) [ 62 , 63 ] or as a precondition by purposeful alignment of MNP [ 64 , 65 ]. Recently, it has been demonstrated that agglomeration in a similar simulation framework can be included [ 66 ].…”

“…As identified in Section 4.1 (discussing the -dependence), the present simulation framework does not consider particle agglomeration/clustering. However, it is becoming more and more evident that agglomerations (or clusters) play a significant role in MNP systems, either globally (non-directional) [ 62 , 63 ] or as a precondition by purposeful alignment of MNP [ 64 , 65 ]. Recently, it has been demonstrated that agglomeration in a similar simulation framework can be included [ 66 ].…”

Key Contributors to Signal Generation in Frequency Mixing Magnetic Detection (FMMD): An In Silico Study

“…Owing to their large specific surface area, abundant active centers, high catalytic efficiency, and good adsorption capacity, magnetic nano-materials have been thoroughly investigated and widely applied. 125–127 Fe 3 O 4 is one of the most widely used magnetic nano-materials because MOF/Fe 3 O 4 composites exhibit the synergistic effect of MOF and Fe 3 O 4 , and can effectively prevent agglomeration of these composites. Consequently, MOF/Fe 3 O 4 composites show excellent potential for electrochemical sensing.…”

“…Owing to their large specic surface area, abundant active centers, high catalytic efficiency, and good adsorption capacity, magnetic nano-materials have been thoroughly investigated and widely applied. [125][126][127] Chang et al 128 polymerized DA onto the surface of Fe 3 O 4 nanoparticles, and then combined it with CuSO 4 and H 3 BTC to prepare magnetic Fe 3 O 4 @PDA@MOF material, which was applied to construct Fe 3 O 4 @PDA@MOF@MIP electrochemical sensor for detecting oxytetracycline. The introduction of MOF can increase the surface area of Fe 3 O 4 nanoparticles, thus increasing the number of pores and effective binding sites of MIP, so that the sensor has an obvious electrochemical response to tetracycline.…”

Progress and opportunities for metal–organic framework composites in electrochemical sensors

Design and characterisation of casein coated and drug loaded magnetic nanoparticles for theranostic applications