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1. Flexible shape memory structures with low activation temperatures through investigation of the plasticizing effect

   Lazarus, Emily; Liu, Han; Secord, Thomas; Laflamme, Simon; Rivero, Iris V (May 2025, Materials research express)

   Shape memory polymer (SMP) systems exhibiting semicrystalline- elastomer blends, such as thermoplastic polyurethane and polylactic acid have been well studied, but their use in biomedical shape memory applications has been limited by their high activation temperature. SMPs are capable of deformation and recovery through the activation of an external stimuli, such as temperature. Critical criteria for SMPs used in biomedical applications is achieving a stimulus temperature close to 37 °C while still experiencing sufficient shape recovery. A polymer’s glass transition temperature has been well defined as the SMP system’s activation temperature and therefore should be decreased to achieve a decreased activation temperature. In this work, a well-known, biocompatible plasticizer, polyethylene oxide (PEO), was added to thermoplastic polyurethane (TPU)—polylactic acid (PLA) SMP blends to observe the plasticizing effect on the structural, thermal, mechanical, and shape memory properties of the polymer blends. Additionally, the geometry of the fabricated SMP samples was tailored to further enhance the shape memory effect through a bowtie honeycomb structure. Our results suggest that the addition of PEO into theSMPsystem may be an effective method for decreasing the polymer’s glass transition temperature through the alteration of the polymer chain structure. With the addition of 30% PEO, the glass transition temperature of the TPU/PLA blend was successfully decreased from 62.4 °Cto 34.6 °Cwhile achieving 86.5% shape recovery when activated at 37 °C, which is only a5%decrease in shape recovery when activated at 50 °C. These results suggest that the addition of a biocompatible plasticizer may overcome the limitation of employing temperature activated SMP systems in biomedical applications, and enhances the potential of these materials for reconfigurable structures, energy dissipation systems, and structural health monitoring (SHM) in civil engineering applications. 

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2. Development of a Resilience Parameter for 3D-Printable Shape Memory Polymer Blends

   https://doi.org/10.3390/ma16175906  

   Cavender-Word, Truman J.; Roberson, David A. (September 2023, Materials)

   The goal of this paper was to establish a metric, which we refer to as the resilience parameter, to evaluate the ability of a material to retain tensile strength after damage recovery for shape memory polymer (SMP) systems. In this work, three SMP blends created for the additive manufacturing process of fused filament fabrication (FFF) were characterized. The three polymer systems examined in this study were 50/50 by weight binary blends of the following constituents: (1) polylactic acid (PLA) and maleated styrene-ethylene-butylene-styrene (SEBS-g-MA); (2) acrylonitrile butadiene styrene (ABS) and SEBS-g-MA); and (3) PLA and thermoplastic polyurethane (TPU). The blends were melt compounded and specimens were fabricated by way of FFF and injection molding (IM). The effect of shape memory recovery from varying amounts of initial tensile deformation on the mechanical properties of each blend, in both additively manufactured and injection molded forms, was characterized in terms of the change in tensile strength vs. the amount of deformation the specimens recovered from. The findings of this research indicated a sensitivity to manufacturing method for the PLA/TPU blend, which showed an increase in strength with increasing deformation recovery for the injection molded samples, which indicates this blend had excellent resilience. The ABS/SEBS blend showed no change in strength with the amount of deformation recovery, indicating that this blend had good resilience. The PLA/SEBS showed a decrease in strength with an increasing amount of initial deformation, indicating that this blend had poor resilience. The premise behind the development of this parameter is to promote and aid the notion that increased use of shape memory and self-healing polymers could be a strategy for mitigating plastic waste in the environment. 

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3. Hydrophilic and hydrophobic shape memory polymer networks in high-intensity focused ultrasound fields

   https://doi.org/10.1088/1361-665X/ad1d07  

   Xi, Jiaxin; Sallam, Ahmed; Safranski, David L.; Mirzaeifar, Reza; Shahab, Shima (January 2024, Smart Materials and Structures)

   Abstract High-intensity focused ultrasound (HIFU) has been investigated as a remote and controlled activation method to noninvasively actuate shape memory polymers (SMPs), specifically in biomedical applications. However, the effects of aqueous environment on shape recoverability ofin vivoHIFU-actuated SMPs have yet to be explored. HIFU directs sound waves into a millimeter-sized tightly focused region. In this study, the response of hydrophilic and hydrophobic photopolymerized thermoset SMP networks under HIFU activation in an aqueous environment was investigated. Acrylate-based SMP networks were copolymerized in specific ratios to produce networks with independently adjusted glass transition temperatures ranging from 40 to 80 °C and two distinct water uptake behaviors. The results link the polymer swelling behavior to shape recoverability in various acoustic fields. The presence of absorbed water molecules enhances the performance of SMPs in terms of their shape memory capabilities when activated by HIFU. Overall, understanding the interplay between water uptake and HIFU-actuated shape recovery is essential for optimizing the performance of SMPs in aqueous environments and advancing their use in various medical applications. 

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4. Boron nitride-based shape memory polymers for spatially targeted ultrasound actuation

   https://doi.org/10.1088/1361-665X/adeb1c  

   Xi, Jiaxin; Safranski, David_L; Mirzaeifar, Reza; Shahab, Shima (July 2025, Smart Materials and Structures)

   Abstract Focused ultrasound (FUS) presents unique advantages for noninvasive localized heating, crucial for controlled shape recovery in shape memory polymers (SMPs), especially in biomedical applications. To enhance FUS-driven actuation efficiency, we propose boron nitride (BN)-infused SMP composites (SMPCs) tailored for targeted biomedical interventions. Using tert-butyl acrylate (tBA) and di(ethylene glycol) dimethacrylate as base materials, we integrated BN fillers at varying concentrations (1, 5, and 10 wt.%). A thorough characterization was carried out, including dynamic mechanical analysis, scanning electron microscopy, uniaxial tensile testing, and swelling study. These results show that increasing the BN content improves shape recovery efficiency significantly. Specifically, the 10 wt.% BN composites outperformed plain SMP in terms of shape recovery ratio when activated with FUS, and the highest shape recovery ratio can achieve 75%. However, higher BN content decreases crosslinking density and stiffness, as shown by a lower Young’s modulus and glass transition temperature. This study demonstrates the promise of BN-infused SMPCs for advanced applications in biomedical application, where noninvasive spatiotemporal actuation of SMPs is required. 

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5. Qualifying the contribution of fiber diameter on the acrylate-based electrospun shape memory polymer nano/microfiber properties

   https://doi.org/10.1039/d2ra05019f  

   Xi, Jiaxin; Shahab, Shima; Mirzaeifar, Reza (October 2022, RSC Advances)

   Fibrous shape memory polymers (SMPs) have received growing interest in various applications, especially in biomedical applications, which offer new structures at the microscopic level and the potential of enhanced shape deformation of SMPs. In this paper, we report on the development and investigation of the properties of acrylate-based shape memory polymer fibers, fabricated by electrospinning technology with the addition of polystyrene (PS). Fibers with different diameters are manufactured using four different PS solution concentrations (25, 30, 35, and 40 wt%) and three flow rates (1.0, 2.5, and 5.0 μL min −1 ) with a 25 kV applied voltage and 17 cm electrospinning distance. Scanning electron microscope (SEM) images reveal that the average fiber diameter varies with polymer concentration and flow rates, ranging from 0.655 ± 0.376 to 4.975 ± 1.634 μm. Dynamic mechanical analysis (DMA) and stress–strain testing present that the glass transition temperature and tensile values are affected by fiber diameter distribution. The cyclic bending test directly proves that the electrospun SMP fiber webs are able to fully recover; additionally, the recovery speed is also affected by fiber diameter. With the combination of the SMP material and electrospinning technology, this work paves the way in designing and optimizing future SMP fibers properties by adjusting the fiber diameter. 

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