Translational Impact Statement

We report that ultrasound-mediated mechanical forces cause selective killing of cancer cells without significant damage to normal cells. This protocol is a dramatic improvement over previous attempts to thermally ablate tumors with ultrasound heating since our ultrasound treatment causes no heating in animal models and cell culture experiments while promoting killing. Thus, our results suggest that it is practical to develop ultrasound-based therapies that could aid cancer treatment.

INTRODUCTION

Although mechanical perturbations of tissues benefit the organism and inhibit many disease processes, relatively little is known about how mechanical stresses affect cellular processes such as cancer. For example, exercise or stretching of tumors inhibits tumor growth in the mouse model.^1,2 Further, mechanically active muscle tissue has a low risk of tumor formation. In fact, muscle-associated tumors do not even make it to the list of the most commonly occurring 36 tumors worldwide.³ At the cellular level, physiologically relevant fluid shear forces caused apoptosis in circulating and adherent tumor cells.^4,5 Further, our earlier studies show inhibition of growth and apoptosis of many different adherent tumor cells after mechanical stretching at a physiological level.⁶ The stretch-mediated apoptosis depends on the mechanosensitive Piezo1 channel activity that enables calcium entry upon mechanical activation, initiating a process of calpain-dependent apoptosis. In a broader context, normal cells can become transformed like tumor cells upon the depletion of rigidity sensing activity through the depletion of protein components of the rigidity sensor.^7,8 Surprisingly, such transformed normal cells from several tissues become mechanosensitive and apoptotic after stretching.⁶ Since most, if not all, tumor cells are depleted of rigidity sensors; mechanosensitivity appears to be a general feature of the tumor cells irrespective of tissue origin.^9,10 A much more flexible way to mechanically perturb cells is a low-frequency ultrasound that can penetrate tissue easily. Here, we show that it provides a flexible way to inhibit tumor cell growth even in an organism.

In the past, ultrasound was used to sensitize tumor cells in combination with different strategies such as sonodynamic therapy,¹¹ chemotherapy,¹² and hyperthermia.¹³ In addition, different ultrasound modes have been tested individually to treat tumors using high-intensity focused ultrasound (HIFU),¹⁴ high-intensity pulsed ultrasound,¹⁵ and low-intensity pulsed ultrasound.¹⁶ However, concerns were raised about healthy tissue damage surrounding the target area; hence, these methods found limited clinical use. Since many tumor cells appear mechanically vulnerable, we tested the effects of relatively low-level ultrasound-mediated mechanical forces that do not heat or otherwise damage healthy cells.

In this study, we find significant tumor cell killing by ultrasound-mediated mechanical forces under conditions that do not damage the normal cells but penetrate tissue and apply mechanical stresses at the nanoscale on subcellular organelles.¹⁷ Many ultrasound applications have been approved for human use, and there is little evidence of damage to normal tissues by ultrasound.^18–20 Because ultrasound-mediated forces kill tumor cells, tumors and tumor organoids from many different tissues in a frequency range and at power levels approved for human use, ultrasound provides a potentially feasible way to attack tumor growth.^19–21

RESULTS

Ultrasound induces tumor cell apoptosis

First, we tested the efficacy of ultrasound in inducing tumor cell apoptosis in vitro. Tumor cells were grown on matrigel and subjected to low-frequency ultrasound (33 kHz) for 2 h, having a power level of 39 mW/cm². A significant increase in apoptosis (46% for MDA-MB-231, 58% for A375p, and 32% HT1080) as measured by annexin V binding was observed with a 50% duty cycle in comparison to the non-treated tumor cells (9% for MDA-MB-231, 4% for A375p, and 5% HT1080) (Figure 1a,b). In contrast, when normal cells from the same tissue of origin as the tumor cells were subjected to similar ultrasound treatment, negligible apoptosis was observed (16% for MCF10A and 3% for HFF after ultrasonication vs. 15% for MCF10A and 4% for HFF for non-treated controls).

[IMAGE OMITTED. SEE PDF]

Since the ultrasound could also cause necrosis, we measured the level of necrosis. About 8%–9% of tumor cells (MDA-MB-231 and A375p) displayed both apoptosis plus necrosis upon treatment in comparison to 32%–35% of cells showing only apoptosis (Figure S1). To understand the role of ultrasound frequency in promoting apoptosis, experiments were repeated using another ultrasound frequency (120 kHz) with the same power level settings. However, there was no increase in tumor cell apoptosis upon treatment, unlike with 33 kHz frequency (Figure S2). To test the generality of apoptosis, tumor cells from another tissue (SKOV3 ovarian adenocarcinoma) were treated with ultrasound. An increase in apoptosis (32%) was seen in comparison to the non-treated tumor cells (7%) (Figure S3). Thus, results showed that low-frequency ultrasound-mediated mechanical forces caused tumor cell apoptosis compared to relatively high-frequency ultrasound in many tumor cell lines, which was reminiscent of the effects of cyclic mechanical stretch.⁶

Next, to measure the apoptosis levels and to test the differential killing of tumor cells at different power levels, we treated cells using a low-power dose (1.5 W total output) and a high-power dose (15 W total output) for 2 h (Figure S4a). A significant increase in tumor cell apoptosis was yet again observed at low power (13% for MDA-MB-231 and 12% for HT1080 after treatment vs. 7% for MDA-MB-231 and 3% HT1080 without treatment) (Figure S4b). As expected, matched tissue normal cells showed negligible apoptosis levels after similar treatment (14% for MCF10A and 2% for HFF after treatment vs. 10% for MCF10A and 2% for HFF without treatment). However, massive apoptosis was observed at high power in both cancer and normal cells (72% for MDA-MB-231, 63% for HT1080 vs. 80% MCF10A, and 61% HFF), highlighting the importance of power level while preserving differential killing cancer cells without damaging normal cells.

Repetitive ultrasound exposure results in a similar level of apoptosis each time

To test if an ultrasound-resistant population of tumor cells could be produced by repeated ultrasound treatments, cells were treated with ultrasound (33 kHz) for 2 h/day for three consecutive days, having a power level of 39 mW/cm². Viable cells were followed with calcein AM dye. A marked decrease in the tumor cell population (MDA-MB-231 or A375p) was observed after each round of treatment with no indication of a plateau. Further, the number of remaining viable cells decreased exponentially (Figure 2a). In contrast, non-treated tumor cells showed progressive growth with time. Treatment of normal cells (MCF10A and HFF) caused no significant change in growth rate compared to non-treated cells (Figure 2a). Further, fluorescence intensity measurements showed a significant decrease in the tumor cell population after treatment compared to the non-treated tumor cells (Figure 2b). Thus, successive ultrasound treatment showed a similar level of tumor cell apoptosis each time, producing a dramatic overall decrease in tumor cell number.

[IMAGE OMITTED. SEE PDF]

Piezo1 channel mediated-calcium influx is required for tumor cell apoptosis

The stretch-induced tumor cell apoptosis (mechanoptosis) relied upon the mechanosensitive Piezo1 channels that catalyzed calcium entry,²² and we postulated that ultrasound-induced apoptosis involved a similar mechanism.⁶ To test the role of Piezo1 in ultrasound-mediated apoptosis, Piezo1 knock-down (KD) cells were treated with ultrasound, and the apoptosis level was measured (Figure 3a,b). Interestingly, the apoptosis level was low in Piezo1 KD cells compared to control siRNA cells upon ultrasound treatment (33 kHz) for 2 h, having a power level of 39 mW/cm² (Figure 3c). Thus, as found for stretch-induced apoptosis, Piezo1 was also required for ultrasound-based mechanoptosis.

[IMAGE OMITTED. SEE PDF]

Although there was a similar expression level of Piezo1 in different tumor cells and their matched normal counterparts⁶ (Figure S5), it was possible that the Piezo1 level increased with similar ultrasound treatment. To test this possibility, cells (MDA-MB-231 and MCF10A) were treated using ultrasound with identical parameters. Surprisingly, western blot results showed increased Piezo1 expression in tumor cells upon ultrasound treatment but not in normal cells (Figure 3d). Further, to determine if ultrasound caused changes in the spatial distribution of Piezo1, high-resolution imaging was performed. In tumor cells, Piezo1 movement to the plasma membrane was observed following ultrasound treatment from a diffuse distribution in the cytoplasm (Figure 3e). In stark contrast, in normal cells, Piezo1 was predominately located in the nuclear region (especially the nuclear envelope)⁶ with and without ultrasound treatment. In particular, no redistribution of Piezo1 to the plasma membrane was detected in normal cells upon treatment, unlike tumor cells. These observations were further confirmed by wide-field imaging. In particular, a 55% reduction in the nuclear to cytoplasmic intensity ratio was observed in treated tumor cells compared to non-treated ones. In contrast, in normal cells, there was a 29% reduction in the ratio upon treatment (Figure S6). Recent studies have reported the association of Piezo1 with peripheral mature adhesion.^23,24 Hence, we examined if ultrasound treatment (33 kHz) promoted Piezo1 translocation to the peripheral adhesions in the tumor cells' plasma membrane. Cells transiently transfected with mApple-paxillin were used to determine the adhesion distribution. Piezo1 was mostly diffuse in the cytoplasm in control tumor cells with no sign of association with peripheral adhesions (Figure 3f,g). In contrast, ultrasound-treated tumor cells showed a strong association of Piezo1 with the enlarged adhesions at the cell periphery (Figure 3f,h). Thus, results demonstrated that ultrasound treatment promoted Piezo1 expression and its localization to the mature adhesions at the cell periphery in tumor cells. At the same time, it was primarily confined to the nuclear region in normal cells.

Based on the above results, we postulated that ultrasound-mediated forces may trigger calcium influx through Piezo1 in tumor cell plasma membranes. In contrast, the nuclear distribution of Piezo1 in normal cells was consistent with the possibility that Piezo1 may not alter calcium entry through the plasma membrane upon ultrasound treatment. To test our hypothesis, an ultrasound-induced calcium influx assay was performed. Cells were loaded with calcium-sensitive dye Cal-520AM to quantify the intracellular calcium level and subjected to ultrasound treatment (Figure 3i and Video S1). In tumor cells, a significant increase in the fluorescence intensity was observed 3 min after the treatment. In contrast, no such increase in the intensity was observed in normal MCF10A cells (Figure 3j and Video S2).

The role of calpain in mitochondria-dependent apoptosis has been widely established. Hence, we tested the role of the calcium-activated calpain protease in mechanoptosis. To do that, calpain 1 and 2 were knocked down in tumor cells by siRNAs (Figure 3k). Cells treated with scrambled siRNA were used as the control. After ultrasound treatment, calpain 1 and 2 knockdown cells had remarkably low levels of apoptosis compared to the ultrasound-treated tumor cells (Figure 3l,m), indicating that calpain played a significant role in mechanoptosis. Collectively, the results demonstrated that ultrasound-initiated calcium influx through activated Piezo1 channels acted as an upstream activator of mechanoptosis. Calcium activated-calpain subsequently triggered mitochondria-mediated apoptosis through a chain of reactions as described previously.⁶ In stark contrast, normal cells were unaffected by ultrasound-mediated mechanical forces because ultrasound did not cause a dramatic rise in cytosolic calcium levels.

Ultrasound impedes in vivo tumor growth in the CAM tumor model

Since ultrasound killed tumor cells grown on the matrigel, we hypothesized whether ultrasound treatment would promote tumor killing in vivo without causing noticeable damage to healthy tissues. To test the hypothesis, we inoculated chick chorioallantoic membranes (CAM) with stable GFP-transfected MDA-MB-231 tumor cells in a matrigel plug and allowed them to grow for 2 days. After tumors were established (often with vascularization), the embryos were treated with ultrasound (33 kHz) for 2 h/day for two consecutive days, having a power level of 39 mW/cm² (Figures 4a and S7). Consistent with the in vitro results, we found an average two-fold reduction in GFP fluorescence intensity after 2 days, indicating cell killing in the treated tumors. In contrast, non-treated tumors displayed an increase in intensity, indicating normal tumor growth (Figure 4b,c). Next, we performed an annexin V-based apoptosis assay on carefully excised ultrasound-treated and controlled tumors. Consistent with in vitro results, treated tumors had a high fraction of apoptotic cells (Figure 4d,e). However, in the control tumors, few apoptotic cells were observed. In addition, the viability of chick embryos was assessed after every round of ultrasound treatment. There was a 100% survival rate after the first round of ultrasound (Figure 4f). After the second round of ultrasound, chick embryo survivability was reduced to 60%, while it remained at 100% in untreated embryos. Thus, these findings indicated that ultrasound treatment killed tumor cells in the chick embryo while causing less damage to delicate embryonic tissues/organs.

[IMAGE OMITTED. SEE PDF]

To determine if other transformed cells behaved similarly, we used HEK293T cells stably transformed by SV40 large T antigen. We selected HEK293T cells because these were p53 mutated cells that exhibited transformed growth on soft agar, showed tumorigenic potential (form tumors in nude mice) and had high transfection efficacy.²⁵ Consistent with previous results, there was a significant reduction in GFP fluorescence intensity in ultrasound-treated tumors. In contrast, non-treated tumors showed increased intensity, indicating growth (Figure S8). Thus, the ultrasound mechanosensitivity was not limited to a specific tumor or tumor cell line.

Ultrasound causes apoptosis of patient-derived tumor organoids

To further validate the ultrasound-induced mechanoptosis, human pancreatic tumor organoids were subjected to ultrasound treatment. Organoids were derived from primary tissue/tumor biopsies. They were composed of organ-specific cell-type aggregates capable of self-renewal, self-organization and retained organ functionality.^25,26 Freshly prepared organoids were treated with ultrasound (33 kHz) for 2 h/day for two consecutive days, having a power level of 39 mW/cm² (Figure 5a). On Day 3, there was a marked increase in the apoptosis level in treated tumor organoids compared to the controls (Figure 5b,c). In addition, many organoids were disrupted and had a broken and irregular morphology in the treated samples (Figures 5d and S8). These disrupted organoids were surrounded by many isolated cells/aggregates, which exhibited a high level of apoptosis. The remaining organoids in the treated sample were significantly smaller (~7500 μm²) when compared with the controls (~44,000 μm²) (Figures 5f and S9). It seems that disrupted organoids reorganized to form smaller organoids. Next, F-actin imaging revealed no visible difference in stress fiber assembly in the treated and control groups (Figure 5e). Thus, the results illustrated that the human-derived tumor cells in an organoid that approximated the organization of in vivo tumors were vulnerable to ultrasound-mediated mechanical forces like the established tumor cell lines.

[IMAGE OMITTED. SEE PDF]

Ultrasound causes tumor regression in a mouse model

We tested the efficiency of low-frequency ultrasound in treating in vivo tumors using a mouse model. As the abovementioned findings suggested that the ultrasound power levels significantly affected the apoptosis levels (Figure S4), animals were treated at 39 kHz ultrasound frequency for 1 h/day for 2–3 weeks using different power levels 39 mW/cm² (200 V), 51 mW/cm² (300 V), and 166 mW/cm² (400 V) (Figure 6a,b). Surprisingly, the lowest tumor growth was observed in the group treated with 300 V (2–3 mm²) compared to the 200 V (7–8.5 mm²), 400 V (~10 mm²), and control groups (4–5 mm²) after 2 weeks. However, tumor growth inhibition varied greatly within each treated group and was evident in notable variations during tumor area measurement.

[IMAGE OMITTED. SEE PDF]

Since mice treated with 300 V showed the lowest tumor growth, we further tested the effect of 300 V power level on tumor growth for a more extended period. Interestingly, 300 V treatment caused a significant reduction in tumor growth area (~1 mm²) after 22 days of treatment compared to the untreated control group (7–17 mm²) (Figure 6c,d). These findings suggested that low-frequency ultrasound treatment with optimized parameters can inhibit in vivo tumor growth. Also, these results open up the possibility of combining optimized ultrasound treatment with existing therapies to augment cancer treatment.

DISCUSSION

This study finds that ultrasound-mediated mechanical forces kill tumor cells under conditions that do not damage normal cells/tissues. The tissue origin of the cells does not significantly affect the level of apoptosis caused by ultrasound treatment. Apoptosis requires the presence of Piezo1 at the cell periphery and appears to be mediated by mechanically-dependent calcium entry that activates calpain to cause an apoptotic cascade. The effects of ultrasound on chick CAM tumors, patient-derived tumor organoids and a tumor mouse model are dramatic, with significant killing of tumor cells in physiologically relevant tissue forms and in vivo. Thus, we suggest that ultrasound acts at a subcellular level that is relatively insensitive to the cell microenvironment but depends upon the transformed state of the tumor cells.⁹ Repetitive ultrasound treatment caused a substantial reduction in several in vitro models and animal studies, indicating that ultrasound treatment did not develop mechanically primed resistant cells in the time frame we used. In-depth in vivo studies are required to check the development of mechanically primed resistant cells and their role in metastasis upon ultrasound treatment. The fact that the higher powers did cause increased tumor growth indicates that the range power level for the killing of tumor cells is relatively narrow.

This selective killing correlates with differences in the mechanical properties of tumors and normal cells.¹⁹ For example, all tumor cell lines we have tested lack rigidity sensors (e.g., tropomyosin 2.1 and myosin IIA), enabling them to grow on soft surfaces while making them sensitive to apoptosis upon cyclic stretching.^6,8,10 In contrast, normal cells with rigidity sensors show apoptosis on soft surfaces but are not killed by cyclic stretching.⁷ Interestingly, restoration of rigidity sensors in tumor cells promotes rigidity-dependent growth, improves cell stiffness, and even grows when subjected to cyclic stretching.^6,8 In contrast, the depletion of rigidity sensors in normal cells initiates transformed growth and apoptosis upon cyclic stretching. Since we have tested cells from different tissues, these findings indicate that tumor cells from many tissues are vulnerable to mechanical forces irrespective of their microenvironment. In contrast, normal cells withstand mechanical treatments and continue to grow in a proper environment.^1,5,27

In the past, several attempts have been made to cause tumor cell killing with ultrasound. However, those were based on either micro/nanobubble-generated thermal cavitation, thermal ablation or focused high-energy waves, often associated with a high risk of local healthy tissue damage due to overheating.²⁸ For instance, high-intensity focused ultrasound (HIFU) has been used clinically to ablate tumors located within the body, but its application is limited due to severe thermal side effects and limited ability to treat metastatic tumors.^29,30 In stark contrast, ultrasound-mediated mechanical forces used in these studies did not cause temperature to rise above 37°C during in vitro or in vivo conditions. To minimize thermal heating, degassed water was used in the tank to remove water microbubbles and prevent thermal heat generated by the microbubble cavitation effect.³¹ In addition, a 50% duty cycle was used during the treatment to ensure the system was ON for 1 s and OFF for 1 s. This periodic ON–OFF functioning provides a cool-off time and prevents excessive heat generation. Hence, after optimized ultrasound treatment, normal cells (MCF10A and HFF) remain unharmed (Figures 1 and 2). More importantly, in the CAM model, tumor cells were killed with a lower risk to the chick embryo, which is highly vulnerable to ultrasound treatment (Figure 5f).³² Similarly, tumor growth was effectively inhibited in mice with ultrasound treatment without causing significant damage to animals (Figure 6). Thus, optimized ultrasound-mediated mechanical forces preferentially promote tumor cell apoptosis in vitro and in vivo (Table S1). However, further studies are required to optimize the ultrasound parameters to maximize the selective killing of tumor cells in vivo and examine the combined effect of ultrasound treatment and chemotherapeutic drugs on tumor suppression.

CONCLUSION

In summary, we showed that ultrasound-mediated mechanical forces caused selective killing of tumor cells in vivo and in vitro without significant damage to normal cells. At a mechanistic level, ultrasound-induced mechanoptosis appears to act similarly to mechanical stretch-induced mechanoptosis.⁶ The ultrasound-mediated forces activate Piezo1 channels that allow calcium entry, activating calpain and subsequently initiating a mitochondrial apoptotic pathway (Figure 7). This calcium-induced apoptosis is similar to calcium-dependent apoptosis of tumor cells through the ER-mitochondrial stress pathway activated by several natural compounds.^33,34 With a more detailed understanding of the mechanism of tumor cell death, many possible cancer therapies would enhance the effect of low-frequency ultrasound treatment. Because ultrasound has been approved for human exposure at power levels 10–100-fold higher than the levels used in this study,²⁸ we suggest that it is practical to develop mechano-based therapies using ultrasound that could augment tumor treatments.

[IMAGE OMITTED. SEE PDF]

MATERIALS AND METHODS

Cell culture

Cell lines MDA-MB-231 (gift from Dr. Jay Groves, UC Berkeley), A375p (gift from Dr. Chris Bakal, ICR UK) and primary human foreskin fibroblasts (HFF, ATCC), HT1080 (ATCC), and SKOV3 (gift from Dr. Ruby Huang, CSI, NUS) were cultured in high glucose DMEM (ThermoFisher) supplemented with 10% FBS and 1% penicillin and streptomycin at 37°C in 5% CO₂ environment. MCF10A, human breast epithelial cells (ATCC) were grown in a specialized culture medium, as mentioned previously.⁷ For cell experiments, high-glucose DMEM containing 10% FBS and 1% penicillin and streptomycin were utilized. TrypLE (ThermoFisher) was used for cell trypsinization and cells were cultured on matrigel (Corning) coated surfaces.

Surface coating with matrigel

The 96-well plate surface was coated with a thin matrigel (Corning) layer per the manufacturer's protocol. Briefly, after thawing matrigel at 4°C, 33 μL of matrigel solution was quickly added onto the pre-chilled surface of a single well of the 96-well plate. The well plates were incubated at 37°C for 24–48 h to solidify matrigel before performing a cell seeding.

Plasmids and transfection

GFP tagged-stable MDA-MB-231 cell line was a gift from Pan Meng (MBI, NUS) and used for in vivo study. For transient transfection of GFP and mApple-paxillin plasmid, Lipofectamine 3000 reagent (ThermoFisher) was used according to the manufacturer's protocol.

siRNA assay

Cells were plated in a six-well plate to perform assays. Calpain1, calpain2, Piezo1, and scramble siRNA (Sigma) transfections were done the next day using lipofectamine RNAiMAX (Invitrogen) according to the manufacturer's protocol. Calpain siRNAs were prepared by Protein Cloning Expression Facility, MBI, NUS as described previously.⁶

Western blot study

The cells were incubated with siRNA for 48 h, pelleted, and washed with PBS. RIPA buffer (Sigma) supplemented with 1× complete protease inhibitor (Roche, No. 4693116001) was used for cell lysis. The cell mixture was centrifuged at 15,000 rpm, 4°C for 20 min. The supernatant was transferred to Eppendorf and mixed with 2× loading dye (2× Lammeli buffer, Bio-Rad, No. 1610737) + beta-Mercaptoethanol (Sigma). Samples were denatured for 5 min at 95°C and gel was run using 4%–20% Mini-PROTEAN® TGX precast protein gels (Bio-Rad, No. 4561094). Next, gels were then transferred onto blot paper and blocked with 5% BSA solution in 1× TBST (Tris-Buffered Saline with Tween-20) for 1 h. The membrane was then incubated with primary antibody overnight at 4°C on a shaker. Membranes were washed with TBST three times (10 min per wash) and incubated with secondary antibodies in 1× TBST (horse radish peroxidase, HRP) for 1 h. The chemiluminescence of the membranes was developed using Super Signal Femto Substrate Kit (Pierce) and developed using ChemiDoc Touch Imager (Bio-Rad). Primary antibodies and conditions used are as follows: Calpain 1 (rabbit, 1:1000, Abcam, ab39170), Calpain 2 (rabbit, 1:1000, Abcam, ab39165), Piezo1 (rabbit, 1:500, Novus Biologicals, NBP1-78446), and alpha-tubulin (mouse, 1:3000, Sigma T9026). The secondary antibodies HRP–conjugated goat anti-rabbit IgG (1:2000, Bio-Rad, 170-6515) and goat anti-mouse IgG (1:2000, Bio-Rad, 170-6516).

Apoptosis and necrosis assay

To identify cell apoptosis, Annexin V-Alexa Fluor 488 or Annexin V-Alexa Fluor 594 conjugates (Thermofisher Scientific) were used according to the manufacturer's protocol. To check cell necrosis, propidium iodide from a live/dead cell double staining kit (Sigma Aldrich) was used according to the manufacturer's protocol. Assay was performed 12 h after ultrasound treatment.

Live cell assay

Calcein AM (Sigma Aldrich) dye was used to check the cell viability according to the manufacturer's protocol. Cells were incubated with dye every day for 15 min before imaging.

Calcium indicator dye-based assay

Cell samples were incubated with the calcium indicator dye (4 mM of Cal-520AM, AAT Bioquest) for 1 h. Samples were then replenished with fresh culture medium and stabilized for 30 min before ultrasound treatment.

Immunocytochemistry and fluorescence microscopy

Samples were fixed with 4% paraformaldehyde (Thermofisher Scientific) solution for 10 min and permeabilized with 0.2% Triton X-100 for 5 min. Normal goat serum (2%) was used as a blocking buffer and samples were treated with serum for 1 h. Samples were then incubated with primary antibodies of rabbit polyclonal anti-Piezo1 (1:200, Novus Biologicals, catalog no. NBP1-78446) overnight at 4°C followed by treatment with Alexa Fluor-594 secondary antibodies (Thermofisher Scientific). Hoechst dye (1:1000, Thermofisher Scientific) was used to stain the cell nucleus.

For in vitro study, fluorescence and bright field images were acquired using a wide-field Olympus live-EZ microscope equipped with a photometric CoolSNAP K4 camera and W1 live-SR spinning disk microscope equipped with a photometric Prime 95B sCMOS camera. For in vivo tumor imaging, a wide-field Zeiss stereomicroscope was used.

In vitro ultrasound treatment

The custom-made ultrasound device was developed in the lab for ultrasound treatment (Figure S10) as mentioned previously.³⁵ Briefly, we used ring transducers with diameters of 16 and 25 mm made of PZT4 material (Beijing Ultrasonics 25 × 10 × 4 and 16 × 8 × 4 piezoceramic rings).³⁶ An aluminum cone is mounted on the rings to widen the field to some 5 cm diameter and attenuate the amplitude to form plane waves. Epoxy and silicon rubberized coats were added to transducers to improve the wave emission. The transducer was fixed to the bottom of the ultrasound water tanks. The water tank was placed in an incubator to maintain 37°C and moisture. The cell well plates/dishes were sealed with parafilm to avoid water entry inside samples during US treatment. Sealed samples were then placed 8 cm above the transducer top. The tank was filled with degassed DI water to immerse the cell samples partially. All primary signals and sequences were generated by Arduino's microcontrollers. This allowed for the swift alteration of duty cycles, sequences, and duration. Cell samples were treated with 33 or 120 kHz frequency with a 50% duty cycle for 2 h. The cell samples were returned to the incubator for overnight incubation to determine the apoptosis level on the following day. The speed of ultrasound in soft tissues is considered as 1540 m/s. Hence, the ultrasound wavelengths at 33 and 120 kHz frequency are 4.6 and 1.2 cm, respectively. The penetration depth for both frequencies is up to 6 cm depending on tissue complexity.

Tumor organoid formation

Pancreatic tumor tissue was obtained from patients undergoing endoscopic surgical resection or tissue biopsy at National University Hospital, Singapore. All tissue donations and experiments were reviewed and approved by the Institutional Review Board. Tissue samples were collected in Hank's Balanced Salt Solution and transferred from the hospital at 4°C. Tissues were minced and plated in Matrigel (Corning). The cell culture medium used is as follows: advanced DMEM/F12, HEPES 10 mM, Glutamax 1×, A8301 500 nM, hEGF 50 ng/mL, mNoggin 100 ng/mL, hFGF10 100 ng/mL, hGastrin I 0.01 μM, N-acetylcysteine 1.25 mM, Nicotinamide 10 mM, PGE2 1 μM, B27 supplement 1× final, R-spondin1, and Wnt3A.

CAM tumor treatment with ultrasound

Fertilized chicken eggs were incubated at 37°C with 70% humidity starting from embryonic day 0 (ED 0). A window was made on eggs on ED 3 to prevent the CAM from sticking onto the shell during development. Under sterile conditions, a small incision was made at the pointed end of the egg using a sharp surgical rod or needle, and 4–5 mL of albumin was removed through the hole to lower the CAM. The eggshell was then cut to form an approximate 1 cm diameter window, exposing the CAM. This window was sealed with Tegaderm transparent film dressing (3 M). Eggs were further incubated to ED7 until they were ready for tumor grafting. GFP-transfected stable MDA-MB-231 and GFP-transfected (transiently expressed) transformed HEK293T cells were used for grafting purposes. For grafting onto CAM, tumor cells were trypsinized, washed by PBS, and re-suspended in pre-chilled Matrigel (Corning). Next, the eggshell was further cut to form a larger window. A slightly bruised area was developed by gently touching the upper periderm layer of the CAM with an autoclaved glass rod, and one million cells in 50 μL Matrigel were inoculated drop-wise onto the bruised area. After inoculation, the window was sealed again with a film dressing. On ED10, tumors formed were imaged using a stereomicroscope (optical and fluorescence) before being treated with an ultrasound. Fertilized eggs containing tumors were subjected to ultrasound for 2 h. The procedure was done for two consecutive days, ED10 and ED11. Tumor imaging was again performed on ED12 to compare the tumor growth. Only tumors with viable embryos were included in the data analysis.

Animal studies

A 7 months old BALB/cJ mice were used for the in vivo experiments. Animal experiments were done as per IACUC guidelines of UTMB, Galveston (protocol number 1910084A). Subcutaneous injections of 50,000 cells of CT26 (murine colorectal carcinoma) mixed with 80% Matrigel were injected in each mouse. The baseline tumor area was measured by performing an ultrasound scan the next day (Day 1) after the injecting cells. Mice were placed in a chamber filled with degassed water on a 1.5 cm thick gel pad directly placed on the transducer. The ultrasound treatment was initiated from Day 5 post-injection and given every day for 2 weeks. Animals were treated at 39 kHz for 1 h at different ultrasound power levels of 200, 300, and 400 V. To monitor the tumor growth, ultrasound scans of the tumor's vertical and horizontal cross-sectional area were captured every 3 days. The change in tumor size was calculated using the following formula.

Change in tumor size = [tumor size on Day X – tumor size on Day 1]/tumor size on Day 1.

AUTHOR CONTRIBUTIONS

A.T., F.M., and M.S. conceived and designed the project; A.T. performed cell and organoid experiments; F.M. fabricated ultrasound devices; A.T. and A.H. performed CAM experiments; A.T., M.Y., and S.P. performed calcium-related experiments; N.D. performed animal experiments; C.A.Z.C. and G.B. developed tumor organoids; A.T., F.M., and M.S. wrote the manuscript. All authors read and commented on the manuscript.

ACKNOWLEDGMENTS

We want to thank all group members of Sheetz lab. A.T. and M.Y are supported by the National Research Foundation of Singapore and the Singapore Ministry of Education Tier 3 (MOE grant no: 2016 T3-1-002). M.S. is supported by NIH grants, NUS grants, and Mechanobiology Institute, the National University of Singapore, and a CPRIT grant from Texas.

CONFLICT OF INTEREST STATEMENT

A.T., F.M., M.Y. and M.S. are inventors of patent applications related to the technology described in this paper. F.M. and M.S. have formed a company, Mechanobiologics Inc., to develop ultrasound therapies for human cancer treatment.

DATA AVAILABILITY STATEMENT

The data that support the findings of this study are available from the corresponding author upon reasonable request.

ETHICS STATEMENT

Animal experiments were done as per IACUC guidelines of UTMB, Galveston (protocol number 1910084A). Humane care and treatment of animals were ensured.