作者感谢Aqua-Aerobic Systems，Inc.（美国伊利诺伊州罗克福德）提供本文研究的颗粒状生物膜。作者还感谢美国国家科学基金会通过奖项#210047和#193729的支持。

1. 系统设置
<ol><li>收集系统组件，包括商用 OCT 系统（基本单元、支架、成像头和计算机）、波形发生器、传感器、延迟/脉冲发生器、带 BNC 连接的开关、BNC 电缆和适配器、光学柱和夹具。</li>
	<li>将函数发生器的同步信号连接到交换机。将交换机的另一个端口连接到延迟发生器。</li>
	<li>将函数发生器的输出连接到换能器引线。</li>
	<li>将延迟发生器的输出连接到 OCT 基本单元背面的触发通道。延迟发生器的输出信号是一个触发脉冲，用于启动OCT系统中扫描光学器件的运动。</li>
	<li>打开系统组件（OCT 基本单元、计算机、函数发生器和延迟发生器）并启动 OCT 软件。</li>
	<li>配置延迟发生器以将晶体管-晶体管逻辑触发信号发送到 OCT 基本单元。有关触发信号要求，请参阅 OCT 系统手册。</li>
	<li>将换能器放置在 OCT 镜头下方。换能器的一端粘有一个3D打印的楔形尖端，用作弹性波的线源。</li>
</ol>2. 图像采集
<ol><li>在 OCT 软件上，选择 多普勒采集模式 并启用外部触发器。</li>
	<li>将颗粒状生物膜放在样品架中的透镜下方，并使用平移台将其移向换能器的尖端。确保传感器与样品表面轻轻接触，如 图 2 所示。我们使用了两种具有不同公称直径（4.3 mm和3.3 mm）的颗粒状生物膜（也称为颗粒状污泥）。这一选择是为了研究生物膜尺寸对其机械性能的影响。这些都是商业上获得的。 注意：本研究中使用的样品架由具有多个半球形压痕的 3D 打印塑料板组成。该支架不允许在天然条件下进行测量。因此，我们在测量过程中引入了自然环境中的水，以防止样品干燥。</li>
	<li>通过单击示例监视器窗口中目标线（波传播路径） 的起点和终点 来指定扫描区域。将这条线相对于换能器尖端居中，并确保它垂直于尖端的边缘。</li>
	<li>指定沿扫描区域的像素数和样品深度，并增加要记录的B扫描（2D横截面图像）的数量，以提高OCE图像的信噪比。所呈现的结果使用沿扫描路径的 1523 像素和沿深度的 1024 像素获得。共进行了 50 次 B 扫描。</li>
	<li>单击 “扫描 ”按钮并打开开关。OCT 和 OCE 图像应显示在屏幕上。在触发超时时间和扫描准备时间内激活交换机。</li>
	<li>确保参考强度在最佳范围内，并将样品放置在OCT显微镜物镜的焦点区域内。正确聚焦的样品的顶部边缘应靠近图像的顶部。</li>
	<li>通过增加左侧颜色条的较高值并减小右侧颜色条的较低值，调整显示工具栏上 OCE 图像中的相位等值。这将增加边缘对比度。</li>
	<li>通过按下前面板上的 正弦 按钮，将函数发生器配置为产生单频正弦电压，并指定测量的起始激励频率。本研究中的测量从 4 kHz 开始，到 9.6 kHz 结束。按输出键启用输出连接器。</li>
	<li>为测量设置可接受的电压。该值应最大限度地提高条纹可见性，但也应避免相位环绕。对于本研究中的生物膜和测量的频率范围，5 到 10 V 之间的电压通常会产生具有良好对比度的相图。</li>
	<li>通过单击 “录制 ”按钮获取 OCT 和 OCE 映像。</li>
	<li>在不同频率下重复测量，以获得不同波长（或条纹周期）的弹性波场的截面图像。</li>
</ol>3. 图像分析
<ol><li>获取像素的物理大小。x 中的物理像素大小是通过将 x 方向的视野除以 x 方向的图像大小，然后乘以 2 倍来获得的。z 中的物理像素大小是通过将 z 方向的视场除以 z 方向的图像大小来获得的。视场和图像大小值与图像信息一起存储在结构数组中，可以使用 ThorImageOCT 包中 MATLAB SDK 中提供的 OCTFileOpen 函数进行访问。</li>
	<li>分别使用 OCTFileGetIntensity 和 OCTFileGetPhase 函数获取 OCT 和 OCE 矩阵，并取记录帧的平均值。这些函数在 MATLAB SDK 的 ThorImageOCT 包中提供。</li>
	<li>通过对图像进行二值化并从上到下检测每列的白色像素，获得样品顶部边缘的像素位置。</li>
	<li>使用 improfile 函数提取 OCE 图像沿该边的相位分布，并计算实际尺寸的累积弧长。通过取 x 和 z 方向上连续点之间缩放差异范数的累积和来计算弧长。</li>
	<li>使用 plomb 函数计算测量的 OCT 相位分布（即从 OCE 图像）相对于累积弧长的空间快速傅里叶变换。</li>
	<li>确定峰在光谱中的位置。此位置表示波的空间频率。根据换能器激励频率（Hz单位）和空间频率（反长度单位）的比值计算波速（或相速度）。</li>
</ol>

生物膜弹性特性的快速无损表征

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作者声明没有利益冲突。

OCT系统中可达到的成像深度由光源的光穿透程度决定，这取决于光源的波长。此外，波长决定了轴向分辨率。较长的波长可以更深入地穿透样品，但与较短的波长相比，轴向分辨率会降低。另一方面，横向分辨率取决于系统的数值孔径和波长，波长越短，分辨率越高。增加数值孔径通过限制景深29 来引入权衡。空间分辨率被限制为以足够的信噪比可以检测到的最短弹性波长。目?...

在废水处理和水资源回收中，越来越多地使用附属生长反应器中的有益生物膜，使微生物能够将不需要的污染物（如有机物、氮和磷酸盐）转化为易于从水中去除的稳定形式1。在这些系统中，生物膜的涌现功能，即生化转化，与居住在其中的微生物的多样性以及这些微生物接受的营养密切相关2。因此，持续的生物膜生长可能会对维持一致的反应器功能构成挑战，因为新的生物膜生长可能会改变生物膜的整体代谢过程、传质特性和群落组成。尽可能稳定生物膜环境可以防止这种变化3.这包括确保营养物质的一致流动，并保持生物膜的结构稳定，厚度稳定4。监测生物膜的硬度和物理结构将使研究人员能够深入了解生物膜的整体健康状况和功能。
生物膜表现出粘弹性 5,6,7。这种粘弹性导致响应外部机械力的瞬时和缓慢、随时间变化的变形的结合。生物膜的一个独特之处在于，当它们发生重大变形时，它们会像粘稠液体一样做出反应。相反，当受到轻微变形时，它们的响应与固体5 相当。此外，在这个小变形区域内，存在一个变形范围，在该范围内，生物膜表现出线性力-位移关系5,6,7。该线性范围内的变形是评估生物膜力学特性的最佳选择，因为这些特性会产生可重复的测量结果。有几种技术可以量化此范围内的弹性响应。光学相干弹性成像 （OCE） 是一种新兴技术，适用于分析该线性范围内的生物膜（菌株量级为 10-4-10-5）8,9。
迄今为止，OCE最成熟的应用是在生物医学领域，该技术已被应用于表征只需要表面光学访问的生物组织。例如，Li 等人使用 OCE 表征皮肤组织的弹性特性10。其他作者描述了猪和人角膜组织的各向异性弹性特性以及它们如何受到眼内压的影响11,12,13,14,15,16。用于研究生物膜的OCE方法的一些优点是它是无损的，并提供中尺度空间分辨率，它不需要任何样品制备，并且该方法本身是快速的;它提供了物理结构和弹性特性（例如孔隙率、表面粗糙度和形态）的共同注册测量值8,9,17,18。
OCE方法使用相敏光学相干断层扫描（OCT）测量样品中传播的弹性波的局部位移。OCT是一种低相干光学干涉仪，可将样品位移的局部变化转换为用光谱仪记录的强度变化。OCT技术还被用于生物膜研究，用于表征中尺度结构、三维孔隙率分布和生物膜变形17,19,20,21。此外，Picioreanu等人使用OCT横截面变形图像的流固耦合逆模型估计了生物膜的力学性能22。
另一方面，OCE测量与逆弹动力波建模相结合，可以产生样品中弹性波的波速，从而能够表征样品的弹性和粘弹性。我们小组将OCE技术用于定量测量生物膜弹性和粘弹性8,9,18，并在琼脂糖凝胶板样品中的剪切流变测量中验证了该技术18。OCE方法提供了对生物膜特性的精确和可靠的估计，因为测量的弹性波速与样品的弹性特性相关。此外，由于材料中的粘性效应，弹性波振幅的空间衰减可以与粘弹性能直接相关。我们已经报告了在旋转环形反应器 （RAR） 中试样上生长的混合培养细菌生物膜和使用弹性动力学波模型18 的具有复杂几何形状的颗粒生物膜的粘弹性特性的 OCE 测量。
OCE 技术也是传统流变测量法18的有力替代方案，传统流变测量法用于粘弹性表征。流变测量方法最适合具有平面几何形状的样品。因此，具有任意形状和表面形态的颗粒状生物膜无法在流变仪上准确表征 8,23。此外，与OCE不同，流变测量方法可能难以适应实时测量，例如，在流通池中的生物膜生长过程中24,25。
在本文中，我们表明，表面波的频率无关波速的OCE测量可用于表征生物膜弹性特性，而无需复杂的模型。这一发展将使更广泛的生物膜社区更容易使用OCE方法来研究生物膜的力学特性。
图 1 显示了本研究中使用的 OCT 系统的示意图。该系统包含多种仪器，包括商用频谱域相敏OCT系统、延迟发生器、函数发生器和压电换能器。OCT 系统采用中心波长为 930 nm 的宽带光源，以干涉测量原理运行。收集到的光强度与样品中复杂的结构细节相关，在后处理单元中进行分析，然后转换为样品的横截面图像 - 通常称为OCT图像。OCT 成像深度取决于样品中光学散射的严重程度，该散射源于折射率的局部变化，并且在生物组织和生物膜中仅限于 1-3 mm。由于样品中的光学相位和干涉强度由运动调制，因此OCT可用于检测局部样品位移。我们利用OCE方法中OCT的位移灵敏度来跟踪样品中弹性波的稳态位移场。具体来说，函数发生器输出正弦电压来驱动压电传感器。反过来，换能器会随着振荡时间历史而拉伸和收缩。换能器的振荡位移通过换能器顶端的 3D 打印楔形尖端在样品表面产生正弦力，从而在样品中产生谐波弹性波。楔形尖端与样品轻微接触，使得在致动器从样品表面缩回后样品保持完整。为了记录样品中的局部位移，在样品中的每个像素处采集由固定时间延迟分隔的相邻深度扫描。每个像素点的连续扫描之间的光学相位差与同一点的局部垂直位移成正比。在OCT系统中，传感器的位移和扫描光学器件之间的同步是通过源自函数发生器并在延迟发生器中延迟的触发脉冲实现的。该同步步骤有助于获取样品中局部光学相位分布的一致横截面图像。这些图像与样品中的局部垂直谐波位移成正比，称为OCE图像。在不同的换能器驱动频率下采集OCE图像，以获得弹性波长和波速随频率的变化。使用弹性动力学模型分析测量的波速，以确定样品的弹性特性。

<table border="1" fo:keep-together.within-page="1" fo:keep-with-next.within-page="always">
	<tbody>
		<tr>
			<td>3D printed sample holder</td>
			<td></td>
			<td></td>
			<td></td>
		</tr>
		<tr>
			<td>3D printed wedge tip</td>
			<td></td>
			<td></td>
			<td>3 mm width</td>
		</tr>
		<tr>
			<td>BNC cables</td>
			<td>Any brand</td>
			<td></td>
			<td></td>
		</tr>
		<tr>
			<td>Delay generator</td>
			<td>Stanford Research Systems</td>
			<td>DG535</td>
			<td>DG535 Digital delay/ Pulse Generator&#160;</td>
		</tr>
		<tr>
			<td>Function generator</td>
			<td>Agilent Technologies</td>
			<td></td>
			<td>33250A 80 MHz Function / Arbitrary Waveform Generator</td>
		</tr>
		<tr>
			<td>Granular biofilm</td>
			<td>Aqua-Aerobic Systems</td>
			<td></td>
			<td>Obtained from an Aerobic Granular Sludge reactor (Aqua-Aerobic Systems, Inc.)</td>
		</tr>
		<tr>
			<td>MATLAB</td>
			<td>MathWorks</td>
			<td></td>
			<td>Release 2022a (MATLAB 9.12)</td>
		</tr>
		<tr>
			<td>Piezoelectric transducer</td>
			<td>Thorlabs</td>
			<td>PK2JUP1</td>
			<td>Discrete Piezo Stack, 75 V, 30.0 &#181;m Displacement</td>
		</tr>
		<tr>
			<td>SD-OCT System</td>
			<td>Thorlabs</td>
			<td></td>
			<td>Ganymede II, LSM03 scan lens</td>
		</tr>
		<tr>
			<td>ThorImageOCT</td>
			<td>Thorlabs</td>
			<td></td>
			<td>Version: 5.5.5</td>
		</tr>
	</tbody>
</table>

quantifying elastic properties of environmental biofilms using optical coherence elastography

生物膜是复杂的生物材料，由包裹在自产细胞外聚合物物质 （EPS） 中的组织良好的微生物细胞网络组成。本文详细介绍了为生物膜弹性表征量身定制的光学相干弹性成像 （OCE） 测量的实施情况。OCE是一种无损光学技术，能够以高空间和时间分辨率对部分透明软材料的微观结构、形态和粘弹性进行局部映射。我们提供了一个全面的指南，详细介绍了正确实施该技术的基本程序，以及从收集的测量值中估计颗粒生物膜的体积杨氏模量的方法。这些包括系统设置、数据采集和后处理。在讨论中，我们深入研究了OCE中使用的传感器的基本物理特性，并探讨了OCE测量的空间和时间尺度的基本限制。我们总结了推进OCE技术以促进环境生物膜弹性测量的潜在未来方向。

In wastewater treatment and water resource recovery, beneficial biofilms in attached growth reactors are increasingly employed to enable microbes to convert undesirable pollutants, such as organic matter, nitrogen, and phosphate, into stabilized forms that can be easily removed from the water1. In these systems, the biofilm&#39;s emergent function, namely biochemical transformations, is closely associated with the diversity of microbes residing in it and the nutrients these microbes receive2. Accordingly, ongoing biofilm growth can pose a challenge to maintaining consistent reactor functionality because the new biofilm growth may alter the biofilm&#39;s overall metabolic processes, mass transfer characteristics, and community composition. Stabilizing the biofilm environment as much as possible can protect against such changes3. This includes ensuring a consistent flow of nutrients and keeping the structure of the biofilm stable with a steady thickness4. Monitoring the biofilm&#39;s stiffness and physical structure would enable researchers to gain insight into the overall health and functioning of the biofilm.
Biofilms exhibit viscoelastic properties5,6,7. This viscoelastic nature results in a combination of an instantaneous and slow, time-dependent deformation in response to external mechanical forces. One unique aspect of biofilms is that, when they are subjected to substantial deformation, they respond like viscous liquids. Conversely, when subjected to minor deformation, their response is comparable to solids5.&#160;Moreover, within this small-deformation region, there is a deformation range under which biofilms exhibit a linear force-displacement relationship5,6,7. Deformations within this linear range are optimal for assessing biofilm mechanical characteristics because these yield reproducible measurements. Several techniques can quantify the elastic response within this range. Optical coherence elastography (OCE) is an emerging technique that is being adapted for analyzing biofilms in this linear range (strains on the order of 10-4-10-5)8,9.
OCE&#39;s most established application so far is in the biomedical field, where the technique has been applied to characterize biological tissues that only require superficial optical access.&#160;For example, Li et al. used OCE to characterize the elastic properties of skin tissue10. Other authors characterized the anisotropic elastic properties of porcine and human corneal tissues and how they are affected by intraocular pressure11,12,13,14,15,16. Some advantages of the OCE method for studying biofilms are that it is non-destructive and provides mesoscale spatial resolution, it does not require any sample preparation, and the method itself is rapid; it provides co-registered measurements of physical structure&#160;and elastic properties (e.g., porosity, surface roughness, and morphology)8,9,17,18.
The OCE method measures the local displacement of propagating elastic waves in a specimen using phase-sensitive optical coherence tomography (OCT). OCT is a low-coherence optical interferometer that transforms local changes in the sample displacement into an intensity change that is recorded with an optical spectrometer. The OCT technique has also been utilized in biofilm research for the characterization of mesoscale structure, porosity distribution in three dimensions, and biofilm deformation17,19,20,21. In addition, Picioreanu et al. estimated biofilm mechanical properties using fluid-structure interaction inverse modeling of OCT cross-sectional deformation images22.
On the other hand, OCE measurements, coupled with inverse elastodynamic wave modeling, yield the wave speed of elastic waves in the sample, which enables the characterization of the elastic and viscoelastic properties of the sample. Our group adapted the OCE technique for quantitative measurement of biofilm elastic and viscoelastic properties8,9,18 and validated the technique against shear rheometry measurements in agarose gel plate samples18. The OCE approach provides precise and reliable estimates of the biofilm properties since the measured elastic wave speed is correlated with the elastic properties of the sample. Furthermore, the spatial decay of the elastic wave amplitude can be directly correlated with the viscoelastic properties due to viscous effects in the material. We have reported OCE measurements of viscoelastic properties of mixed culture bacterial biofilms grown on coupons in a rotating annular reactor (RAR) and granular biofilms with complex geometries using elastodynamic wave models18.
The OCE technique is also a powerful alternative to traditional rheometry18which is used for viscoelastic characterization. Rheometry methods are best suited for samples with planar geometry. As such, granular biofilms, which have arbitrary shapes and surface morphologies, cannot be accurately characterized on a rheometer8,23. In addition, unlike OCE, rheometry methods may be challenging to adapt for real-time measurements, for example, during biofilm growth in flow cells24,25.
In this paper, we show that OCE measurements of the frequency-independent wave speed of surface waves can be used to characterize the biofilm elastic properties without the need for complicated models. This development will make the OCE approach more accessible to the broader biofilm community for studying the biofilm mechanical properties.
Figure 1 shows a schematic illustration of the OCT system used in this study. The system incorporates several instruments, including a commercial spectral-domain phase-sensitive OCT system, a delay generator, a function generator, and a piezoelectric transducer. The OCT system operates on the principle of interferometry by employing a broadband light source with a center wavelength of 930 nm. The collected light intensity, which is correlated with intricate structural details in the sample, is analyzed in the postprocessing unit and then converted to a cross-sectional image of the sample - commonly referred to as an OCT image. The OCT imaging depth depends on the severity of the optical scattering in the sample that stems from local variation in the refractive index and is limited to 1- 3 mm in biological tissues and biofilms. Since the optical phase in the sample and the interference intensity are modulated by motion, the OCT can be used to detect the local sample displacement. We leverage the displacement sensitivity of the OCT in the OCE method to track the steady state displacement field of elastic waves in the sample. Specifically, the function generator outputs a sinusoidal voltage to drive the piezoelectric transducer. The transducer, in turn, stretches and contracts with an oscillatory time history. The oscillatory displacement of the transducer imparts a sinusoidal force on the sample surface through a 3D-printed wedge tip at the apex of the transducer, leading to the generation of harmonic elastic waves in the sample. The wedge tip makes light contact with the sample, such that the sample remains intact after the actuator is retracted from the sample surface. To record the local displacement in the sample, adjacent depth scans separated by a fixed time delay are acquired at each pixel in the sample. The optical phase difference between consecutive scans at each pixel point is proportional to the local vertical displacement at the same point. Synchronization between the displacement of the transducer and the scanning optics in the OCT system is achieved through a trigger pulse that originates from the function generator and is delayed in the delay generator. This synchronization step facilitates the acquisition of consistent cross-sectional images of the local optical phase distribution in the sample. These images are directly proportional to the local vertical harmonic displacement in the sample and are known as the OCE image. OCE images are acquired at different transducer actuation frequencies to obtain the elastic wavelength and wave speed as a function of frequency. The wave speeds measured are analyzed with an elastodynamic model to determine the elastic properties of the sample.

作者聚焦：使用光学相干弹性成像表征环境生物膜力学及其在废水处理中的应用

使用光学相干弹性成像量化环境生物膜的弹性特性

Our research consists of characterizing the mechanical properties of environmental biofilms using the optical coherence and elastography technique. We aim to understand and predict how biofilm composition and structure correlate to mechanical properties. Ultimately, this knowledge will be leveraged to enhance or eliminate different biofilms, depending on the application.Okay, for the specific focus of characterizing the mechanical properties of biofilms, we have Rheometry, we have non-indentation, atomic force microscopy. We also have some new developmental techniques, for example, like optical tweezers, magnetic tweezers, digital image correlation, and a host of others. Most of the previously used techniques either focus on overall mechanical property measurements, overlooking those at the mesoscale, or highly localized measurements that are not relevant at the mesoscale.And the mesoscale is crucial because that is the level that is relevant to the physical attributes of biofilms. First, we've adapted the optical clearance elastography technique to characterize the mechanical properties of environmental biofilms. In this context, we've developed the methods, we've also developed inverse modeling tools to be able to deal with layered viscoelastic properties and also to analyze the complex microstructure of biofilms.Our group is interested in quantifying the mechanical properties of biofilms from wastewater treatment plants, so we're interested in learning what factors impact the stability and performance of biofilms. For example, does the stiffness of a biofilm impact the rate of sloughing?

在这项研究中，我们使用了商业上获得的颗粒状生物膜（也称为颗粒状污泥）。颗粒是通过自聚集形成的球形生物膜，这意味着它们不需要在其上生长的载体或表面26。 图3A 显示了由于颗粒生物膜中局部折射率的空间变化而产生的具有代表性的横截面OCT图像。生物膜的标称直径为 3 毫米。在图像中可以看到一些内部特征，包括靠近样品表面的?...

Watch this Scientific Journal Video about Quantifying Elastic Properties of Environmental Biofilms using Optical Coherence Elastography at JoVE.com

本文重点介绍了光学相干弹性成像（OCE）技术在快速、无损地表征生物膜弹性特性方面的功效。我们阐明了用于精确测量的关键OCE实施程序，并提出了两种颗粒生物膜的杨氏模量值。

Biofilms are complex biomaterials comprising a well-organized network of microbial cells encased in self-produced extracellular polymeric substances ...

我们的研究包括使用光学相干性和弹性成像技术表征环境生物膜的机械性能。我们旨在了解和预测生物膜的组成和结构与机械性能的关系。最终，这些知识将用于增强或消除不同的生物膜，具体取决于应用。好的，对于表征生物膜机械性能的具体重点，我们有流变测量法，我们有无压痕原子力显微镜。我们也有一些新的开发技术，例如，光学镊子、磁镊子、数字图像相关等等。以前使用的大多数技术要么专注于整体机械性能测量，而忽略了中尺度上的测量，要么专注于与中尺度无关的高度局部测量。中尺度至关重要，因为这是与生物膜的物理属性相关的水平。首先，我们采用了光学间隙弹性成像技术来表征环境生物膜的机械性能。在这种情况下，我们开发了这些方法，我们还开发了逆建模工具，以便能够处理层状粘弹性特性，并分析生物膜的复杂微观结构。我们小组对量化废水处理厂生物膜的机械性能感兴趣，因此我们有兴趣了解哪些因素会影响生物膜的稳定性和性能。例如，生物膜的刚度会影响脱落率吗？

quantifying-elastic-properties-environmental-biofilms-using-optical

Research

JoVE Journal

Environment

Quantifying Elastic Properties of Environmental Biofilms using Optical Coherence Elastography

723 次观看.  Northwestern University. 我们的研究包括使用光学相干性和弹性成像技术表征环境生物膜的机械性能。我们旨在了解和预测生物膜的组成和结构与机械性能的关系。最终，这些知识将用于增强或消除不同的生物膜，具体取决于应用。好的，对于表征生物膜机械性能的具体重点，我们有流变测量法，我们有无压痕原子力显微镜。我们也有一些新的开发技术，例如，光学镊子、磁镊子、数字图像相?...

视频: 作者聚焦：使用光学相干弹性成像表征环境生物膜力学及其在废水处理中的应用

Biofilms are complex biomaterials comprising a well-organized network of microbial cells encased in self-produced extracellular polymeric substances (EPS). This paper presents a detailed account of the implementation of optical coherence elastography (OCE) measurements tailored for the elastic characterization of biofilms. OCE is a non-destructive optical technique that enables the local mapping of the microstructure, morphology, and viscoelastic properties of partially transparent soft materials with high spatial and temporal resolution. We provide a comprehensive guide detailing the essential procedures for the correct implementation of this technique, along with a methodology to estimate the bulk Young's modulus of granular biofilms from the collected measurements. These consist of the system setup, data acquisition, and postprocessing. In the discussion, we delve into the underlying physics of the sensors used in OCE and explore the fundamental limitations regarding the spatial and temporal scales of OCE measurements. We conclude with potential future directions for advancing the OCE technique to facilitate elastic measurements of environmental biofilms.

This paper highlights the optical coherence elastography (OCE) technique's efficacy in rapidly and non-destructively characterizing biofilm elastic properties. We elucidate critical OCE implementation procedures for accurate measurements and present Young's modulus values for two granular biofilms.