聚合物納米顆粒（NPs）由于其生物降解性，生物相容性以及高度可定制的藥物加載和釋放能力而被廣泛用于生物醫學應用。盡管有許多關于NP力學對納米生物相互作用（例如內在化，吸收，運輸和降解）影響的報道，但在與聚合物NP利用率相對應的條件下，還沒有系統地表征聚合物NP力學。

Polymer nanoparticles (NPS) are widely used in biomedical applications because of their biodegradability, biocompatibility and highly customizable drug loading and release capabilities. Although there are many reports on the effects of NP mechanics on nano biological interactions (such as internalization, absorption, transport and degradation), there is no systematic characterization of polymer NP mechanics under the conditions corresponding to the utilization of polymer NP.

這種缺陷的根源在于，盡管原子力顯微鏡（AFM）非常適合表征納米級材料（即NP），但在生理條件下（例如，緩沖液中的37°C）進行的實驗具有挑戰性，需要專用設備。雖然可以使用大量測量值來推斷NP的機械性質以了解生物學功能，但這種推斷所依據的假設是，懸浮在緩沖液中并加熱生理溫度不會顯著改變NP的力學。

The root of this defect is that although atomic force microscopy (AFM) is very suitable for characterizing nanoscale materials (i.e. NP), experiments under physiological conditions (e.g. 37 ° C in buffer) are challenging and require special equipment. Although a large number of measurements can be used to infer the mechanical properties of NP to understand its biological function, this inference is based on the assumption that suspension in buffer and heating to physiological temperature will not significantly change the mechanics of NP.

這種假設適用于某些無機NP，例如由金屬和氧化物組成的那些。此外，對具有不同機械性能的二氧化硅納米膠囊的系統研究發現，吞噬作用和靶向腫瘤的過程對納米顆粒的硬度有很強的依賴性。

This assumption applies to some inorganic NPs, such as those composed of metals and oxides. In addition, the systematic study of silica nanocapsules with different mechanical properties found that the processes of phagocytosis and tumor targeting were strongly dependent on the hardness of nanoparticles.

生物降解顆粒研究人員認為，盡管可生物降解的聚酯納米粒子廣泛用于藥物遞送，并且有報道稱納米粒子力學對納米生物相互作用具有強大的影響，但在生理相關條件下，對這些納米粒子的力學卻缺乏系統的研究。近年來有研究團隊報告使用原子力顯微鏡對聚乳酸和聚丙交酯乙交酯納米顆粒的壓痕實驗。雖然發現干燥的納米顆粒在室溫下是剛性的，但是發現它們的彈性模量在模擬的生理條件下（即在37℃的水中）降低了多達30倍。

Biodegradable particle researchers believe that although biodegradable polyester nanoparticles are widely used in drug delivery, and it is reported that nano particle mechanics has a strong impact on nano biological interactions, there is a lack of systematic research on the mechanics of these nanoparticles under physiological related conditions. In recent years, a research team has reported the indentation experiment of polylactic acid and polylactide glycolide nanoparticles using atomic force microscope. Although the dried nanoparticles were found to be rigid at room temperature, their elastic modulus was found to be reduced by up to 30 times under simulated physiological conditions (i.e. in 37 ℃ water).

差示掃描量熱法證實該軟化可歸因于納米顆粒的玻璃化轉變。結合機械和熱分析特性，研究了微型化，分子量和浸入水中的塑化效果。總的來說，這些實驗為實驗家們探索聚合物納米粒子力學與體內行為之間的關系提供了見識。

Differential scanning calorimetry confirmed that the softening could be attributed to the glass transition of nanoparticles. The miniaturization, molecular weight and plasticizing effect in water were studied by combining the mechanical and thermal analysis characteristics. In general, these experiments provide insights for experimenters to explore the relationship between the mechanics of polymer nanoparticles and their behavior in vivo.

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