2020/03/24 12:50
阅读:1216
分享:方案摘要:
产品配置单:
APS100高浓度纳米粒度仪
型号: APS-100型
产地: 美国
品牌: 美国MAS
¥100万 - 200万
参考报价
联系电话
方案详情:
Acoustic Particle Sizing of Milk
超声法粒度分析在乳剂行业的应用
Oil/Water, as well as, Water/Oil emulsions can partially degrade or even fully break up upon undergoing dilution. Thus, particle size measurements without dilution are desirable for emulsion characterization.
油/水以及水/油的乳液会在稀释之后部分降解甚至完全分解。因此,在不稀释的情况下直接测量乳液的粒径是一种理想方法。
The APS-100 Acoustic Particle Sizer1 measures -without the need for sample dilution Particle Size Distribution, Longitudinal Viscosity, Percent Solids, pH, Conductivity, and Temperature. Using a patented measurement design2, the APS-100 performs acoustic attenuation spectroscopy measurements in the ultrasonic range of 1-100 MHz.
美国MAS公司生产的APS-100超声法粒度仪《1》可以不用稀释,直接测量粒度分布,纵向粘度,固含量,PH值,电导率及温度。通过测量设计《2》,APS-100可以在1-100MHz的超声波范围内进行声学衰减光谱测量。
The resulting attenuation spectrum of dB/cm vs. Frequency (MHz) is used by a patented first-principle algorithm3 to calculate particle size distribution data without making assumptions regarding the shape of the particle size distribution, e.g. unimodal, bimodal, lognormal, Gaussian, etc. The APS-100 is calibrated with water without the need for particle size calibration standards.
通过使用原理算法使用产生的dB/cm / 频率(MHz)的衰减谱来计算粒径分布数据,而无需对粒径分布的形状进行假设,例如单峰、双峰、对数正态、高斯等。APS-100是用水进行校准的,不需要使用粒度校准标准。
APS measurements are made by low-power (inaudible) short acoustic pulses (about 10 microseconds long) that do not affect the sample’s dispersion state as depicted in figure 1. Another instrument, the Zeta-APS, measures Zeta potential in addition to all these parameters.
APS测量采用低功率(听不清)短声脉冲(约10微秒长),不影响图1所示的样品的分散状态。另外Zeta-APS仪器,除了测量上述所有这些参数外,还测量Zeta电位。
除了测量上述所有这些参数外,还测量Zeta电位。
Fig. 1. Waveforms of the ultrasonic pulses applied and measured during Acoustic Particle Sizing.
图1 - 超声波脉测量粒度的过程中,超声波的脉冲波形。
Fig. 2. Acoustic Attenuation Spectra of 4% wt silica-water sample (3 runs: ♦, ■, ▲) alongside DI water (x).
图2 - 4%wt二氧化硅水样(3次:♦, ■, ▲)和去离子水的声衰减谱。
Fig. 3. Particle Size Distribution overlaid data for three consecutive runs of a 4% wt silica-water sample.
图3 – 三次4%wt二氧化硅水样的粒度分布数据叠加图
Figures 2 and 3 show attenuation spectra and particle size distribution data for three consecutive runs of a silica-water sample at 4% wt percent solids level (Nissan Chemical, Houston, TX). A water (solvent) spectrum is also shown. A solvent spectrum (excluding the particles) is required for particle size computation.
图2和图3显示了连续三次4%wt二氧化硅水样的粒度分布和声衰减谱(Nissan Chemical, Houston, TX)。水样的谱图也有显示。粒径计算需要溶剂谱(不包括微粒)。图3所示的PSD在0.1微米有相当窄的分布,接近MP1040二氧化硅的标称平均粒径。
Emulsion Analysis
乳液测试分析
For this study, five consumer-type dairy samples were characterized as follows:
在本研究中,五种消费型乳液样本的特征如下:
- Half and Half Cream (HHC) 半脂乳
- Whole Milk (WM) 全脂乳
- 1% Low-fat Chocolate Milk (CM) 1% 低脂巧克力乳
- 1% Low-fat Milk (LFM) 1% 低脂乳
– Nonfat Milk (NFM) 脱脂乳
The samples were analyzed without dilution. They were continuously mixed by the APS- 100’s onboard mechanical mixer. Sample temperature was kept at 26 ºC by the APS- 100’s sample heater.
这些样品没有进行稀释。他们是由APS-100的内置机械混合器连续混合。通过APS-100的加热系统,保证样品在26℃。
Acoustic Data
超声数据
Fig. 4. Acoustic Attenuation Spectra for five milk samples.
图4 – 5种乳剂样品的超声衰减波谱。
Figure 4 shows acoustic attenuation spectra, dB/cm vs. Frequency (MHz), for the five milk samples. Attenuation levels decrease in the following order due to each sample’s fat content level as follows (see below about the 1% chocolate milk sample):
HHC > WM > CM > LFM > NFM
图4显示了5种乳的dB/cm / 频率(MHz)的衰减谱。由于每个样品的脂肪含量水平,衰减水平按以下顺序降低(见下文关于1%巧克力牛奶样品):
HHC半脂乳 > WM全脂乳 > CM1% 低脂巧克力乳 > LFM 低脂乳> NFM脱脂乳
Regarding Chocolate vs. Low-fat milk, the difference in attenuation is due to the added chocolate flavor components.
关于巧克力和低脂乳,衰减的差异是由于添加了巧克力风味成分。
These samples were analyzed at 26 ºC, kept constant by the APS-100’s onboard heater. Also, the samples were continuously mixed during these measurements by the APS-100’s mechanical mixer.
这些样品在分析过程中通过APS的加热系统保持温度在26℃。此外,在这些测量过程中,由APS-100的机械混合器连续混合样品。
Fig. 5. Particle size distribution data for a whole milk sample by Acoustic Particle Sizing (APS-100).
图5 – APS-100测量的全脂乳的粒度分布数据。
Figure 5 below presents the particle size distribution for a whole milk sample analyzed without dilution. The fat-free milk sample was used to represent the intrinsic attenuation required by the acoustic particle sizing computations4.
图5显示了未经稀释而分析的全脂乳的粒度分布。脱脂乳样品用于表示声学颗粒尺寸计算所需的固有衰减《4》。
Intrinsic attenuation corresponds to the solvent attenuation, i.e. attenuation excluding the discrete phase (particles/droplets) of the sample. The particle and solvent physical properties required by the particle size computations were obtained from published data5.
固有衰减对应于溶剂衰减,即不包括样品的离散相(颗粒/液滴)的衰减。颗粒尺寸计算所需的颗粒和溶剂物理性质是从已发表的数据中获得的《5》。
Some of the corresponding particle size data for the whole milk sample are as follows:
全脂乳样品的相应粒度数据如下
Mean particle size, Volume weighted: 1.8 µm, 25th, 75th percentiles: 0.9, 2.5 µm
Mean particle size, Area weighted: 1.1 µm, 25th, 75th percentiles: 1.46, 1.5 µm
体积平均粒径:1.8μm,D25 为0.9μm,D75为2.5μm
面积平均粒径:1.1μm,D25 为1.46μm,D75为1.5μm
Figure 6 above corresponds to a sample of half and half creamer measured by an APS- 100 instrument without dilution. The particle size data is as follows:
Mean particle size, Volume weighted: 1.45 µm, 25th, 75th percentiles: 0.53, 2.6 µm
Mean particle size, Area weighted: 0.65 µm, 25th, 75th percentiles: 0.2, 0.68 µm
图6对应的是用APS- 100仪器测量的没有稀释半脂乳样品的测试数据:
体积平均粒径:1.45μm,D25 为0.53μm,D75为2.6μm
面积平均粒径:0.65μm,D25 为0.20μm,D75为0.68μm
REFERENCES
1. Matec Applied Sciences, Northborough, MA USA, www.matecappliedsciences。。com)
2. US Patent 6,604,408
3. US Patent 6,119,510
4. McClements, D. J., and Povey, J. W., Ultrasonic analysis of edible fats and oils, Ultrasonics, vol 30, 6, 1992.
5. Lopez, C., Briard-Bion, V., Camier, B., Gassi, J. Y., Milk Fat Thermal Properties and Solid Fat Content in Emmental Cheese: A Differential Scanning Calorimetry Study, J. Dairy Sci., 89:2894-2910, 2006/
下载本篇解决方案:
更多
药用辅料不溶性微粒检测-关注辅料蔗糖不溶性微粒超标的危害
药用辅料蔗糖在生物技术药物的冻干工艺中常用作保护剂,它既能在冷冻过程中充当低温保护剂,又能在干燥脱水过程中起到脱水保护剂的作用,并且不含还原基不会使得生物制品发生蛋白质褐变反应从而变质失活。在生物技术药物的冷冻干燥配方中,蔗糖是最常用、用量最大的保护剂,因此在其质量控制过程中安全性应予以足够的重视。 王珏等学者在《基于小鼠腘窝淋巴结模型对疫苗用辅料蔗糖中不溶性微粒激发免疫应答风险的评估》中对比了部分不同厂家蔗糖产品中不溶性微粒在大小和数量上的差异,实验结果表明不同厂家的蔗糖产品显示出对小鼠脾淋巴细胞增殖不同程度的影响,作用程度与产品中的不溶性微粒数目有关。
制药/生物制药
2022/08/22
不溶性微粒检查专题介绍9-不溶性微粒检查的QA
不溶性微粒检查需要多少样品测试? 不溶性微粒检查样品前处理的方法有哪些? 不溶性微粒检查怎么消除气泡? 不溶性微粒检查样品能不能稀释?
制药/生物制药
2023/11/12
不溶性微粒检查专题介绍8-不溶性微粒定性分析介绍
不溶性微粒的定性分析,这个是接下来很多用户关注的重要领域,在USP1788上面有介绍到在我们之前专题不溶性微粒发展趋势里面也有讲到,对于不溶性微粒的研究,不只是大小,还需要知道微粒是什么,然后去溯源和改进。当然不知道是不溶性微粒,可见异物的溯源和定性分析也是关注的热点。
制药/生物制药
2023/11/05
不溶性微粒检查专题介绍6-不溶性微粒检查的应用领域
我们介绍了不溶性微粒的定义、检查原理和发展趋势等,结合前面的介绍,不溶性微粒的检查在生物医药领域目前应用的三个主要领域是:制剂的不溶性微粒检查、 药用包材的不溶性检查、医疗器械的不溶性微粒检查。
制药/生物制药
2023/10/17