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Background:
Systematic Review

Plasma Device Functions and Tissue Effects in the Female Pelvis—A Systematic Review

by
Nick J. van de Berg
1,2,*,
Gatske M. Nieuwenhuyzen-de Boer
1,3,
Xu Shan Gao
4,
L. Lucia Rijstenberg
5 and
Heleen J. van Beekhuizen
1
1
Department of Gynaecological Oncology, Erasmus MC Cancer Institute, 3015 GD Rotterdam, The Netherlands
2
Department of Biomechanical Engineering, Delft University of Technology, 2628 CD Delft, The Netherlands
3
Department of Obstetrics and Gynaecology, Albert Schweitzer Hospital, 3318 AT Dordrecht, The Netherlands
4
Division of Reproductive Endocrinology and Infertility, Department of Obstetrics and Gynaecology, Erasmus University Medical Center, 3015 GD Rotterdam, The Netherlands
5
Department of Pathology, Erasmus University Medical Center, 3015 GD Rotterdam, The Netherlands
*
Author to whom correspondence should be addressed.
Cancers 2023, 15(8), 2386; https://doi.org/10.3390/cancers15082386
Submission received: 7 March 2023 / Revised: 7 April 2023 / Accepted: 18 April 2023 / Published: 20 April 2023
(This article belongs to the Special Issue Gynecologic Oncology: Prevention, Screening and Treatment Innovations)
Browse Figure
Versions Notes

Abstract

:

Simple Summary

Plasmas are used in various forms and with various functions in gynaecology. Knowledge on plasma–tissue effects and target coverage is crucial to achieve complete treatment, reduce recurrence, and limit damage to healthy tissues. In this review, historical and future plasma applications are summarized, and the depths of (non-)thermal effects are evaluated in tissues of the female pelvis. A literature search was performed in the Medline Ovid, Embase, Cochrane, Web of Science, and Google Scholar databases. Fourteen articles were found with data on thermal effects depth. For plasma-assisted electrosurgical devices, depths (<2.4 mm) relied on current dispersion in tissue. In turn, for electrically neutral argon plasma, depths remained superficial (<1.0 mm). The depth and uniformity of cold atmospheric plasma effects requires further investigation. This review identifies upcoming and potentially high-gain applications of plasma in the field of gynaecology, of which the therapeutic effectiveness must be examined in translational and clinical studies.

Abstract

Medical use of (non-)thermal plasmas is an emerging field in gynaecology. However, data on plasma energy dispersion remain limited. This systematic review presents an overview of plasma devices, fields of effective application, and impact of use factors and device settings on tissues in the female pelvis, including the uterus, ovaries, cervix, vagina, vulva, colon, omentum, mesenterium, and peritoneum. A search of the literature was performed on 4 January 2023 in the Medline Ovid, Embase, Cochrane, Web of Science, and Google Scholar databases. Devices were classified as plasma-assisted electrosurgery (ES) using electrothermal energy, neutral argon plasma (NAP) using kinetic particle energy, or cold atmospheric plasma (CAP) using non-thermal biochemical reactions. In total, 8958 articles were identified, of which 310 were scanned, and 14 were included due to containing quantitative data on depths or volumes of tissues reached. Plasma-assisted ES devices produce a thermal effects depth of <2.4 mm. In turn, NAP effects remained superficial, <1.0 mm. So far, the depth and uniformity of CAP effects are insufficiently understood. These data are crucial to achieve complete treatment, reduce recurrence, and limit damage to healthy tissues (e.g., prevent perforations or preserve parenchyma). Upcoming and potentially high-gain applications are discussed, and deficits in current evidence are identified.

1. Introduction

Plasma is an energetic state of matter consisting of ions and free electrons, typically created by electric discharges in a plasma medium. In the early 1990s, plasma-based devices were first used in the management of ovarian cancers, because of the improved control of thermal depth of injury compared to monopolar electrosurgery (ES) [1]. This controllability makes the devices suitable for complete cytoreductive surgery and for producing haemostasis on the colon, mesenterium, ureters and diaphragm [1,2]. Over the years, many other applications of plasma-based devices have been proposed, evaluated, and used in gynaecology.
Current plasma-based devices are summarized in Table 1 and include the Argon Beam Coagulator (ABC), Argon Plasma Coagulation (APC), J-Plasma, Helica Thermal Coagulator (HTC), Martin Argon-Beamer System (MABS), PlasmaBlade, PlasmaJet (PJ), kINPen, and PlasmaDerm. Most of these devices (ABC, APC, J-Plasma, HTC, MABS, PlasmaBlade) rely on ES. Typically, they do not use plasma-tissue effects directly, but the plasma does help achieve a more even dispersion of electrical energy in tissue. The PJ uses kinetic plasma particle energy to thermally treat tissue. To emphasize the difference with the former group, this device is sometimes referred to as electrically neutral argon plasma (NAP). The kINPen and PlasmaDerm use cold atmospheric plasmas (CAP) and rely on biochemical plasma-tissue effects. Cold plasmas can be administered to tissue through atmospheric pressure plasma jets (APPJ), beams, torches, or plumes; via dielectric barrier discharges (DBD); or via plasma-activated media (PAM), e.g., gases or liquids (PAL).
Definitions for the terms hot and cold in plasma medicine deviate from those in basic plasma sciences. Hot refers to the ability to cause thermal damage to tissue. This can include coagulation, desiccation, ablation, or charring. Irreversible thermal damage in tissue starts at temperatures as low as 43 °C and is a function of temperature and exposure time [3,4]. In turn, cold plasma effects are dominated by non-thermal biochemical responses with reactive oxygen and nitrogen species. The terminology becomes somewhat confusing in plasma-assisted ES, for which cold plasmas may be used to control electrothermal (ohmic) heating of tissue [5].
The aim of this review of the literature is to compare medical applications and tissue effects of plasma devices used in the female pelvis and in gynaecology. This is needed to stay up-to-date with evidence-based and upcoming practices in plasma medicine, to stimulate research to address deficits in current evidence, and to guide technologies towards their most effective clinical use. This review focuses on plasma-applications on tissues of the uterus, ovaries, cervix, vagina, vulva, colon, omentum, mesenterium, and peritoneum.

2. Materials and Methods

A search for literature on quantitative (thermal) effects of plasma-based devices in gynaecological and pelvic tissues was performed in Medline Ovid, Embase, Cochrane, Web of Science, and Google Scholar. This review was not registered on PROSPERO. Search methods and results are illustrated in the PRISMA diagram in Figure 1. Full-text manuscripts published before 4 January 2023 were included. The search was undertaken using key terms, including: “argon plasma coagulation”, “plasmajet”, “cytoreductive surgery” and “tissue damage”. Article titles and texts were scanned independently by X.S.G. and N.J.v.d.B., followed by a discussion to reach consensus on inclusions. Article titles, abstracts, and full texts were reviewed to extract data on the extent of tissue effects. For all studies, the following data were obtained: tissue type, number of lesions, power, exposure time, device–tissue distance, and quantitative values of tissue effects reported.

3. Results

In total, 8958 articles were identified. After removing duplicates, an initial pool of 6069 articles remained, of which the titles and abstracts were scanned. Of the remaining 310 records, full texts were retrieved and checked for the description of (thermal) effect data on the tissue types included. In total, 14 articles were identified with new quantitative data on energy dispersion of plasma devices.

3.1. Depth of Tissue Effects

An overview of the depth of tissue effects of plasma-based devices is shown in Table 2. These include thermal effects for plasma-assisted ES and NAP devices. Thermal effects are typically measured in formalin-fixed and haematoxylin- and eosin-stained specimens. Metrics included the total depth of damage (TDD), or its constituents: the “depth of the crater”, ablation depth or vaporization depth (VD), and the thermal effects depth (TED). The latter group may again be divided in layers of carbonized eschar and coagulative necrosis [6]. Few articles also measured the width or lateral spread of thermal effects. The spread of non-thermal effects of CAP effects is discussed briefly.

3.1.1. Electrosurgical Devices

Electrosurgical devices (ABC, APC, HTC, J-plasma) use beams of ionized argon or helium for a diffuse conduction of electricity to tissue. The prime tissue effects depend not on interactions with plasma but on ohmic heating. For the ABC, TDD was related to power setting (60–100 W) and tissue interaction time (1–5 s) and ranged between 1.7–5.6 mm in a series of 144 epithelial ovarian carcinoma specimens collected from a single patient [6]. Power and time had a high impact on VD and a lower impact on TED. Notably, the depth ratios of eschar and necrosis layers were highly consistent. The depth and width of necrosis caused by the ABC device were also assessed in porcine uterine horn and colon tissues [7]. Tissue type had a large effect on the extent of damage. Therefore, the authors stress that safe use of ABC requires an understanding of thermal effects in target tissues. In porcine small bowel and colon serosa, the TTD was compared for ABC and PJ devices [8]. The depth was more variable and power-dependent during the use of ABC (0.7–1.9 mm) compared to PJ (0.6–1.0 mm) devices. Predominant effects were coagulation and desiccation for the ABC and ablation for the PJ device.
APC (ARCO-MC, Söring) power setting and application time resulted in an increased TED in stomach, small intestines, and colon tissues [9]. Here, an effect of tissue type was not found. Changes in the probe angle (45°/90°) resulted in a change of the coagulation zone (oval/round) but did not alter the depth of thermal damage. In turn, APC (VIO 300D, ERBE) lesions were evaluated in rat peritoneum when rats were sacrificed 10 days after trauma induction [10,11,12,13]. Power setting affected the average lesion and inflammation depth, which ranged between 0.6–1.7 mm (10 W vs. 25 W, Student’s t-tests, p < 0.0001) [10]. In a pulsed APC setting (25 W), this was 1.3 mm [11]. The depth of tissue damage increased with pulse duration [14]. To reduce peritoneal adhesion formation, the peritoneum may be elevated with a water jet before applying APC (HybridAPC) [13]. The layer of water also acts as a heat sink, reducing the average lesion depth to 0.3 mm. Similarly, submucosal saline injections in porcine gastrointestinal tract tissues may be used to limit the depth of injury caused by APC [14,15,16].
The J-Plasma (20% power) TED was evaluated in vivo in porcine ovaries (0.11 ± 0.04 mm) and uterine horns (0.42 ± 0.13) [17]. The injury was smaller than that created with monopolar and bipolar ES devices. Furthermore, it was observed that the J-Plasma device (40% power, 4.0 l/min gas flow, 80 pulse setting) enabled the collection of peritoneal biopsies with cleaner edges compared to monopolar ES [18].
In short, tissue heating by ES devices decreases with depth along the current density, which is governed by device power. Plasma assistance may achieve a more uniform energy delivery to tissue. Thermal effects also depend on electrical resistivity and tissue geometry, introducing tissue type dependencies [7,17]. Finally, the extent of damage relies on exposure time [6]. In gynaecological tissues, the TED was found to range between 0.1–2.4 mm. This may be reduced or controlled with submucosal saline injections [13].
Table
Table 2. Depth of tissue effects are reported in literature with either a range or mean ± std notation. Experimental models are annotated as: H = human, P = porcine, R = rodent, 1 = in-vivo, 2 = in-vitro/ex-vivo, O = ovary, U = uterus, F = fallopian tube, I = intestines, S = sigmoid colon, E = endometrium, Pe = peritoneum, M = intestinal mesentery and Om = omentum. Tissue effects are measured as total depth of damage (TDD), vaporization depth (VD), or thermal effect depth (TED).
Table 2. Depth of tissue effects are reported in literature with either a range or mean ± std notation. Experimental models are annotated as: H = human, P = porcine, R = rodent, 1 = in-vivo, 2 = in-vitro/ex-vivo, O = ovary, U = uterus, F = fallopian tube, I = intestines, S = sigmoid colon, E = endometrium, Pe = peritoneum, M = intestinal mesentery and Om = omentum. Tissue effects are measured as total depth of damage (TDD), vaporization depth (VD), or thermal effect depth (TED).
Author, Year [Ref.]Experimental SettingDevice Use ParametersThermal Tissue Effect Metrics
Tissue ModelsPatients/
Samples		Type aPowerTime (s)Dist. (mm)Flow (L/min)TDD (mm)VD (mm)TED (mm)
EscharNecrosis
Electrosurgical (plasma-assisted) devices
Bristow, 2001 [6]H2-O b1/16
1/16
1/16
1/16
1/16
1/16		ABC60 W
60 W
80 W
80 W
100 W
100 W		1
5
1
5
1
5		<10
<10
<10
<10
<10
<10		7
7
7
7
8
8		1.7 ± 0.3
2.4 ± 0.4
2.2 ± 0.3
3.7 ± 0.7
3.2 ± 0.4
5.6 ± 0.5		0.6 ± 0.2
-
-
-
-
3.2 ± 0.3		0.5 ± 0.1
-
-
-
-
1.1 ± 0.2		0.6 ± 0.2
-
-
-
-
1.3 ± 0.3
Gale,
1998 [7]		P1-U
P1-I		2/15
2/24		ABC60–80 W
40–80 W		1–5
1–5		5–10
5–10		4
4		-
-		-
-		-
-		0.5–1.0
0.4–2.1
Tanner, 2017 [8]P1-I1/16ABC30–90 W15–10-0.7–1.9---
Johanns,
1997 [9]		H2-I-/10APC40–155 W1–1052–7--0.1–2.4
Kraemer, 2011 [10]R1-Pe9/36
9/36		APC10 W
25 W		4
4		2–3
2–3		0.3
0.3		-
-		-
-		0.6 ± 0.4 e
1.7 ± 1.2 e
Kraemer, 2014 [11]R1-Pe16/62APC25 W42–30.3--1.3 ± 1.1 e
Kraemer, 2014 [12]R1-Pe16/64APC25 W42–30.4--2.2 ± 0.7 e
Kraemer, 2018 [13]R1-Pe24/48Hybrid APC25 W-30.4--0.3 ± 0.1 e
Llarena,
2019 [17]		P1-O
P1-U		8/15
8/32		J-Plasma20%
20%		5
5		5
5		-
-		-
-		-
-		0.11 ± 0.04
0.42 ± 0.13
Deb,
2012 [19]		H1-U
H1-O
H1-F		15/15
10/10
10/10		HTC4 W
4 W
4 W		-
-
-		5
5
5		-
-
-		0.7 ± 0.2 f
0.7 ± 0.2 f
0.6 ± 0.1 f
Neutral argon plasma devices
Tanner,
2017 [8]		P1-I1/24PJ10–30%15-0.6–1.0---
Deb,
2012 [19]		H1-U
H1-O
H1-F		15/15
10/10
10/10		PJ20%
20%
20%		5
5
5		5–10
5–10
5–10		-
-
-		0.6 ± 0.2 f
0.6 ± 0.1 f
0.6 ± 0.2 f
Madhuri, 2014 [20]H1-U c
H1-S b		3/48
3/48		PJ10–60%
10–80%		1–9
1–4		10
10		-
-		-
-		0.2–3.5
0.2–3.5		0.2–1.0
0.1–0.4
Sonoda,
2010 [21]		H2-O
H2-Pe b		4/48
4/48		PJ70–85%
70–85%		2
4		10
10		-
-		-
-		1.6–2.2
2.7–4.0		0.11–0.12
0.13–0.15
Roman,
2011 [22]		H1-O d8/10PJ40%15----0.1 ± 0.1
Nieuwenhuyzen-de Boer, 2022 [23]H1-U/O/
I/Pe/Om/M		17/106PJ10%3–45–10---0.15
a Device type abbreviations include: ABC (Argon Beam Coagulator), APC (Argon Plasma Coagulation), HTC (Helica Thermal Coagulator), and PJ (PlasmaJet). b Serous carcinoma, c Leiomyoma, d Endometrioma. e Evaluated 10 days after trauma induction. f Unclear histological definition of thermal damage.

3.1.2. Neutral Argon Plasma Devices

The PJ relies on collisions of energetic particles with tissue. Transfer of kinetic energy into heat happens directly at the plasma–tissue interface. Thermal effects of the PJ were assessed in uterine leiomyomas and sigmoid bowel serous carcinoma samples [20]. Increasing the power and exposure time resulted in more tissue vaporization (0.2–3.5 mm), whereas the depth of the eschar remained relatively constant (<1 mm). In a similar approach, tumours were harvested during ovarian and peritoneal cancer surgery in four women [21]. Exposure time had a larger effect on vaporization depth than power. In addition, the PJ and HTC were compared in uterine, ovarian and fallopian tube tissues in 15 women undergoing hysterectomy [19]. The PJ and HTC resulted in a similar TDD between 0.6–0.7 mm. However, the width of the thermally affected zone did differ and was between 4.1–4.7 mm and 5.9–7.7 mm, respectively (Student’s t-test, uterus: p < 0.001, ovary: p < 0.001, fallopian tube: p = 0.034). The PJ device caused coagulation, desiccation and vaporization, whereas the HTC device caused coagulation and haemostasis. In a series of 10 samples collected from 8 women with ovarian endometriomas, a mean depth of necrosis of 145 µm was found [22]. Finally, thermal effects of PJ and electrosurgical devices were compared in a series of 106 tissue samples of 17 ovarian cancer patients undergoing cytoreductive surgery [23]. Devices were used in vivo on to-be-resected tissues of reproductive organs, and intestines as well as on membranes. The mean TED of the PJ (0.15 mm, range 0.03–0.60 mm) was lower than that of the electrosurgical unit (0.33 mm, range 0.08–1.80 mm) (Mann–Whitney U test, p < 0.001).
In short, the PJ TED remains below 1.0 mm, and VD depends on application time, and to a lesser extent power [21]. For divergent plasma beams, particle density is higher close to the device tip. Energy delivered to the tissue surface may therefore also depend on distance to tissue. Tissue dependencies may be caused by variations in biomechanical tissue properties. However, so far, there are no indications that these effects can become clinically relevant [19].

3.1.3. Cold Atmospheric Plasma Devices

CAP (kINPen) devices aim to trigger biological redox reactions that cause cancer-specific apoptosis or inhibit spread of disease. Furthermore, PAM is under evaluation to reduce post-operative peritoneal adhesions [24]. It appears that oxygen species are less capable of penetrating tissue than nitrogen species [25]. Some species can penetrate 1.25 mm of biological tissue. However, in absence of thermal injury, quantifying the effects of remaining species on tissues is complex. In a pancreatic cancer model (Colo-357 chorio-allantoic membrane assay), the reported effect of kINPen APPJ exposure (20 s) was cell death induced in the upper 3–5 cell layers, reaching approx. 50 µm [26]. By means of Raman imaging, differences in DNA and lipids in the superficial and basal cell layers were identified over an average thickness of 270 µm, in a series of 10 cervix uteri tissue samples treated with the kINPen [27]. Raman data suggest that reactive species can cross the full thickness of human mucosa [28]. However, the completeness of treatment in these layers remains unclear. As a concept, it is often suggested that PAM can facilitate dose delivery via needle injection [29]. Although the direct reach of plasma particles may be limited, tissue effects may be more extensive [30]. It is theorized that cell-to-cell communication plays a role in the spread of plasma effects [30,31].
In short, very few data on affected depths or volumes of tissue are available for CAP devices. In absence of thermal effects, it is complex to (histologically) identify and assess these zones. Current estimates rest on computer models and gelatine or agarose gel models, while in vivo mechanics and CAP effectiveness need to be better understood [32,33].

3.2. Device Function: Type of Tissue Effects

3.2.1. Cutting, Incision and Dissection

The PlasmaBlade is an electrosurgical soft tissue dissection tool with a plasma rim generated around the blade. It operates at a lower temperature than traditional ES devices and causes less thermal damage [34]. The device is mostly investigated in plastic and reconstructive surgery. It was used to create incisions for caesarean section in a randomized study in 40 women [35]. Cosmetic outcomes were compared to those of traditional scalpels and rated after six months by patients and dermatologists using Patient and Observer Scar Assessment Scale scores. The PlasmaBlade resulted in a more favourable score (30.9 ± 11.9) than the scalpel (48.9 ± 18.6). The Canadian Agency for Drugs and Technologies in Health filed a review of literature on the PlasmaBlade in 2019, identifying the need for more rigorous comparative research and determining its cost-effectiveness [36].
The ABC was used for laparoscopic dissection of pelvic (n = 61), pelvic and aortic (n = 35), and aortic (n = 18) lymph nodes [37]. Rates for complications and conversions to laparotomy were 7% and 8%, respectively. Furthermore, the PJ device has been used for groin node dissection (n = 3), wide local excision of vulva (n = 1), ovarian cyst removal (n = 22), myomectomy (n = 2), and tubal surgery—salpingectomy or salpingotomy (n = 6) [38]. However, detailed clinical processes or outcomes were not reported.
In short, comparative data of plasma-based devices used for cutting of gynaecological tissues are currently insufficient to assess their effectiveness relative to that of conventional devices.

3.2.2. Coagulation

Gynaecological cancer management can include radiotherapeutic components. In this context, the American Society of Colon and Rectal Surgeons advises endoscopic APC for the treatment of rectal bleeding induced by chronic radiation proctitis, as it leads to a meaningful decrease in bleeding in 79–100% of patients [39]. They advise power settings of 40–60 W, gas flow rates of 1–2 L/min, and applications in 1–2 s pulses. The treatment is considered safe, with 19–35% of patients experiencing self-limiting early complications (e.g., proctalgia, rectal mucous discharge, incontinence, gas emphysema) and 0–3% of patients experience late complications (rectal stenosis) [40,41,42]. A pooled analysis of 33 studies (957 patients) showed an overall clinical success rate of 87% and a serious adverse event (colonic fistula, perforation, explosion, or stricture) rate of 4% [43]. Abdominal, rectal, and anal pain were the most common APC-related adverse events. To prevent excessive bowel distention, alleviate pain, and reduce the risk of post-procedural discomfort, it is advised to periodically remove the argon gas flow.
The European Society of Gastrointestinal Endoscopy considers APC the treatment of choice for angioectasia in the gastrointestinal tract [44]. The perforation incidence after APC (Söring) treatment of the colon was 0.3% (1/373 patients) [45]. After APC (ERBE) treatment of 100 patients with angiodysplasia, the probability of remaining free of rebleeding was high: 98% after 1 year and 90% after 2 years [46]. In a group of 94 patients with angiodysplasia, 234 visible lesions were coagulated successfully with APC (ERBE, PRECISE mode) [47]. After the procedure, no perforation, active bleeding, or tissue carbonization was reported. At 6 months follow-up, rebleeding was seen in 19% of patients, and new lesions in the same area were seen in 16% of patients.
In short, coagulation with plasma-based devices largely rests on APC, and the device is used mostly on tissues of the colon and rectum. Other plasma-based devices may induce coagulation, but their clinical effectiveness is less well studied. APC is the modality of choice in clinical guidelines for the management of rectal bleeding caused by radiation proctitis [39] as well as in the treatment of angioectasia [44]. Clinical outcomes were studied with decent patient cohorts and follow-up times. Comparative studies with other devices that may induce coagulation remain limited.

3.2.3. Ablation I: Endometriosis

The National Institute for Health and Care Excellence reviewed the use of laparoscopic helium plasma coagulation for the treatment of endometriosis in 2006. At the time, no major safety concerns were found, yet evidence of the procedural efficacy was still insufficient. The same year, the results of a series of 1060 women treated laparoscopically with HTC were reported [48]. The complication rate was low at 0.1%, and satisfactory pain relief was seen in 70% of patients [49,50]. In a recent randomized controlled trial, HTC and traditional ES devices were used in 192 women with mild-to-moderate endometriosis [51]. Cyclical pain and dyspareunia were assessed with visual analogue scales (VAS) at 6, 12 and 36 weeks after surgery. VAS scores were significantly lower (better) for electrosurgical than for HTC treatments. However, it was pointed out that treatment groups differed, i.e., the electrosurgical group involved excisions in 99% of cases compared to 60% in the HTC group [52].
The PJ is also being studied for endometriosis treatment. The depth of thermal effects is comparable to that of HTC [19], and is typically < 1 mm [53]. In a group of 34 patients, PJ treatment was considered safe and did not result in postoperative complications, problems with healing of the wound, long-lasting postoperative pain, or disease recurrence [54]. Using a 3D ultrasound-based assessment of ovarian volumes and antral follicle counts in 30 women, the PJ was compared to cystectomy. With counts of 5.5 ± 3.9 and 2.9 ± 2.4, the PJ was considered a tissue-sparing alternative [55]. In a follow-up study in 104 women treated with the PJ or cystectomy, no differences were found in pregnancy probability at 36 months (84.4% and 78.3%) after surgery [56]. It should be noted that both values are high. Finally, quality of life was compared using the Endometriosis Health Profile 5 questionnaire in 52 women with deep endometriosis treated with shaving, shaving with PJ use, and resections [57]. Both the PJ and resection methods resulted in better quality of life outcomes compared to shaving.
In short, there is an ongoing debate on the need for ablation or deep excision of endometriosis to achieve pain and dyspareunia management. This debate extends to the optimal devices for treatment. A competing factor for deep excisions is the preservation of ovarian parenchyma in women with a wish to conceive.

3.2.4. Ablation II: Carcinomatosis

One of the first gynaecological applications of plasma-based devices was cytoreductive surgery or debulking of advanced ovarian cancer [1]. In this study, seven patients were treated with ABC, of which four were left with no visible remaining disease. At a mean follow-up time of 33 months, 5 patients survived of which 4 disease-free. In a group of 45 patients, ABC improved the rate of achieving complete cytoreduction to 74% [58]. Furthermore, using ABC and the ES loop excision procedure, laparoscopic debulking was performed in 36 patients with stage III or IV ovarian cancer. The approach was considered feasible (two conversions to laparotomy, 6%), successful (complete cytoreductive surgery, 94%) and safe (two complications, 6%: 1 epigastric hematoma, 1 cystotomy) [59].
As an alternative, the PJ has been used to treat advanced-stage ovarian cancer in groups of 19 patients [60], 51 patients [61], and 87 patients [62]. Carcinomatosis was removed from the peritoneum, bowel serosa, intestinal mesentery, diaphragm, and liver surface. In these studies, complete cytoreductive surgery was achieved in 100%, 78%, and 99% of patients, respectively. Surgical complications were limited. Most often reported was the need for blood transfusions. In a multicentre randomized controlled clinical trial with 327 patients (intervention group with PJ: 157, control group without PJ: 170), per-protocol complete cytoreductive surgery was achieved in 85.6% and 71.5% of patients (chi-squared test, p = 0.005), respectively [2]. There were no significant differences in blood perfusion, hospital time, number of colostomies (9 vs. 20, p = 0.169), or surgical complication rates. In case of peritoneal carcinomatosis (≥50 lesions on peritoneum, diaphragm, or mesentery), complete cytoreductive surgery was achieved in 72.2% and 51.5% in intervention and control groups, respectively. Six months after surgery, patients in the intervention group reported a better perceived health score compared to the control group (EQ-VAS: 73.4 vs. 69.0, p = 0.029, mean EQ-5D-5L health state: 0.80 vs. 0.76, p = 0.049).
In short, early studies with the ABC and recent studies with the PJ have addressed plasma use for cytoreductive surgery for ovarian cancer patients. A recent randomized controlled clinical trial showed that PJ treatment may increase surgical completeness. Currently, there is still a need for long-term follow-up to assess overall and disease-free survival after these treatments.

3.2.5. Topical Therapy I: Gynaecological Intraepithelial Neoplasia

The ABC was evaluated for the local treatment of vulvar intraepithelial neoplasia (VIN) in 29 patients [63]. Human papillomavirus status was known for 10 patients (9 positive, 1 negative). After a mean follow-up of 35 months, 52% of patients had no recurrence, with a mean time to recurrence in the other 48% of 23 months. ABC was considered an alternative treatment that may improve cosmesis and organ and form conservation. Alternatively, the PJ was used in a series of eight patients with recurrent and multifocal uVIN or perianal intraepithelial neoplasia [64]. Of this group, six patients required repeat PJ treatment. At a median follow-up of 269 days, excellent macroscopic and symptomatic improvements were reported. Furthermore, there are indications that cervical intraepithelial neoplasia (CIN) can be treated with CAP. In a study in 48 premenopausal women with histologically confirmed CIN I (37%) and II (63%), CAP induced a remission of CIN after 3 months in 81% of patients, with 93% sustainability after 6 months [65,66]. The treatment also resulted in a normalization of high-risk HPV (71% to 11%) and PAP smear testing. Finally, CAP has also been tested for the treatment of chronic vulvar pruritus in 3 patients [67]. After three 90 s sessions per week, for six weeks, a significant reduction of itch was reported, whereas clinical signs improved only slightly.
In short, plasma-based treatment of vulvar, anal and cervical intraepithelial neoplasia has been tested with a view to preservation of tissue form and function. So far, different plasma-based devices (ABC, PJ, and CAP) were used. However, the application field is new, and there is a need for randomized controlled trials and elaborate comparative studies to address cost-effectiveness as well as risks of disease recurrence.

3.2.6. Topical Therapy II: Selective Cancer Treatment

Although our literature search is focused on clinical studies, a short summary of in-vitro CAP developments is in order due to the fast developments and important prospects of this field. CAP uses the difference in sensitivity to reactive oxygen and nitrogen species to reduce viability or induce apoptosis of specific cell types. Typically, researchers are in search of a sweet spot in plasma conditions at which cancer cells die and nearby healthy cells survive. Detailed biochemical pathways through which CAP (potentially) work have been previously reviewed [29,68]. In vitro studies have been conducted on a wide range of gynaecological cell lines (see also Table 1 in the work of Zubor et al. [68]) of cervical cancer [69,70,71,72], ovarian cancer [73,74,75,76,77,78], and colon cancer [79,80,81], see Table 3. With an aim to increase differences in cell response between healthy and cancer cells, more intricate applications are in development, combining CAP with hyperthermia [82], radiotherapy [72], or photodynamic therapy using targeted polymeric nanoparticles [83].
In addition to curative potential, anti-proliferative effects of CAP on cancer cells have been studied—for instance, on cervical cancer cell lines using the MABS device [84]. With a CAP DBD device, suppressed migration and invasion of cervical cancer HeLa cells was shown [85]. Antiproliferative effects of CAP were also demonstrated in ovarian cancer cell lines [86]. In addition, PAM inhibited dissemination of ovarian cancer (ES2) cells in an in-vivo mouse model of intraperitoneal metastasis, resulting in prolonged survival [87,88].
In short, CAP may enable selective killing or antiproliferation of cancer cells. Definite proof of treatment selectiveness remains scarce, as culture media used for cancerous and non-cancerous cell lines often differ, which can affect the stability of reactive oxygen and nitrogen species [89]. Additionally, it is uncertain whether changes in protein expression realised in cell cultures can be transferred to in vivo treatment [90]. Finally, the CAP-affected zone needs to be better understood, and methods for local CAP delivery may need to be developed. While preclinical cell line studies in the past two decades were abundant, there is a pressing need for translational and clinical studies. These will determine the future role of CAP as a first line or adjuvant treatment for dysplastic tissues.

4. Discussion

Plasma-based devices are increasingly used in gynaecological treatments. The aim of this review was to delineate tissue effects of plasma devices as a function of device settings and parameters of use. This was done for various tissues of the female pelvis, include the uterus, ovaries, cervix, vagina, vulva, colon, omentum, mesenterium, and peritoneum.
Three device classes were identified in this review: electrosurgical (ES, plasma-assisted) devices aim to achieve electrothermal tissue heating; neutral argon plasma (NAP) devices aim to achieve tissue heating by transferring kinetic particle energy; and cold atmospheric plasma (CAP) devices aim to trigger biochemical cell responses. All three classes focus on targeted therapies, albeit creating different tissue effects and being developed for different fields of application.
A critical determinant of plasma applicability is the depth or volume of tissue effects required to achieve complete treatment and limit damage to healthy tissues, e.g., to prevent perforations or limit toxicity. Thermal effects were reported as total depth of damage (TDD), vaporization depth (VD), or thermal effect depth (TED), which includes layers of eschar and necrosis. In practice, VD can be macroscopically inspected, whereas TED is the subsurface damage that is not directly visible. Overall, we found that tissue effects of ES devices depend on device power, exposure time, and tissue type and shape. Plasma-assistance may improve the uniformity of ES energy distributions. The TED of plasma-assisted ES devices in pelvic tissues was found to range between 0.1–2.4 mm. In turn, NAP and CAP devices rely on direct plasma–tissue interactions, and their effects remain more superficial. The TED of NAP devices was <1.0 mm, while the VD increased with application time and to a lesser extent with power settings. Here, tissue dependencies appeared to be limited. Finally, CAP effects are non-thermal. So far, few studies have provided quantitative assessments of affected treatment zones.
When reporting the extent of thermal effects, we advocate adding visual definitions in exemplar histological images. Unambiguous definitions are needed to enable inter-study comparison of results. In particular, it was not always clear whether vaporization effects were included in thermal damage measures. In addition, thermal effects may be reported by describing the (proportion of) tissue layers affected [16,91,92]. This qualitative approach is pragmatic and valuable to construct guidelines for device use in a specific clinical context. However, it prevents a broader and quantitative comparison of device functioning, as tissue layer types and thicknesses differ per organ.
Plasma-based device functions in gynaecology have included coagulation, ablation, and—to a lesser extent—the cutting of tissues. In addition, topical use of plasmas has been explored for non-surgical or adjuvant clinical therapies. Plasma-assisted ES was used mostly for coagulation in colorectal procedures to treat bleeding after radiation proctitis and angioectasia. In these fields, the APC has been an established device advocated in multiple clinical guidelines. In turn, NAP is predominantly investigated for the treatment of endometriosis or carcinomatosis. Evidence of device effectiveness is gradually accumulating, yet there is a need for additional randomized clinical trials, comparison studies, and longitudinal patient follow-up and quality of life studies. Finally, CAP is currently in development for the selective killing of cancer cells. However, its physicochemical and immunomodulatory effects need to be better understood. So far, it remains uncertain whether changes in protein expression in cell cultures can be transferred to in vivo treatment [90]. This stresses the need for clinical and translational studies to assess true effectiveness and selectiveness of CAP treatments in patients.
This systematic literature review has several limitations. We have presented data on the (non-)thermal effects of plasma devices on organs that may be treated by a gynaecologist. However, we did not discriminate between the ways in which these organs were approached. For example, the colon may be approached facing the serosa during cytoreductive surgery or facing the mucosa during endoscopic procedures. Consequently, application fields may have extended beyond those typically performed by a gynaecologist. However, in absence of studies comparing thermal effects after treatment of mucosal and serosal organ sides, we have decided to not let this restrict the search results.
In some hospitals, breast cancer treatment falls in the domain of the gynaecologist. In this field, (non-)thermal plasma devices have also been evaluated. Based on a study with 80 patients undergoing breast-conserving surgery, it was suggested that the ABC may reduce the development of haematomas or seromas [93]. Furthermore, the PlasmaBlade was compared to conventional diathermy in a study with 108 abdominal-based free-flap breast reconstruction patients [94]. The PlasmaBlade resulted in less abdominal seromas at 2-week follow-up. In recovery (day 0), the PlasmaBlade did result in a higher median pain score (4, IQR 1.0–6.0) compared to diathermy (2, IQR 1.0–5.0). Finally, CAP applications for breast cancer therapy were recently reviewed by Chupradit et al. [95].
An important factor that is unaddressed in this review is device costs and cost-effectiveness. Studies on these topics remain scarce [36]. Cost calculations should include procurement (including infrastructural changes) and running costs (including maintenance and consumables) [96], and may involve costs of both inpatient and outpatient care [97]. Most plasma-based devices appear to be made for single-time use. Differences in costs need to be weighed against gains in treatment outcomes, (post-)operative risks, and differences in the patient’s quality of life.

5. Conclusions

Plasmas have been used in various forms and with various functions in gynaecology. Plasma devices can be divided into three classes: making use of electrosurgical energy (plasma-assisted), kinetic energy of neutral argon plasma particles, or biochemical reactions of cold atmospheric plasmas. In this review, historical and potentially future plasma applications are summarized, and the depth of effects is evaluated in tissues of the uterus, ovaries, cervix, vagina, vulva, colon, omentum, mesenterium, and peritoneum. The depth of treatment of electrosurgical devices relies on electric current dispersion in tissue. In turn, direct plasma–tissue interactions tend to remain superficial. In terms of device applications, argon plasma coagulation is used mainly in colorectal procedures, including the treatment of bleeding after radiation proctitis and the treatment of angioectasia. Neutral argon plasma is predominantly evaluated for the treatment of endometriosis and carcinomatosis. Finally, cold plasmas are evaluated for the treatment of intraepithelial neoplasia, and for selective treatment of cancer cells. This review identifies upcoming and potentially high-gain applications of plasma in the field of gynaecology, of which the therapeutic effectiveness needs to be examined in translational and clinical studies.

Author Contributions

N.J.v.d.B.: conceptualization, investigation, methodology, formal analysis, writing—original draft, G.M.N.-d.B.: conceptualization, investigation, methodology, writing—review and editing, X.S.G.: investigation, methodology, writing—review and editing, L.L.R.: validation, writing—review and editing, H.J.v.B.: conceptualization, supervision, writing—review and editing. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Acknowledgments

The authors wish to thank Sabrina Meertens-Gunput and Maarten Engel from the Erasmus MC Medical Library for developing and updating the search strategies.

Conflicts of Interest

The authors declare no conflict of interest.

Abbreviations

ABCArgon Beam Coagulation
APCArgon Plasma Coagulation
APPJAtmospheric Pressure Plasma Jet
CAPCold Atmospheric Plasma
CINCervical Intraepithelial Neoplasia
DBDDielectric Barrier Discharge
ESElectrosurgery
HTCHelica Thermal Coagulator
NAPNeutral Argon Plasma
PAM/PALPlasma Activated Medium/Plasma Activated Liquid
PJPlasmaJet
TDDTotal Depth of Damage
TEDThermal Effects Depth
VDVaporization Depth
VINVulvar Intraepithelial Neoplasia

References

  1. Brand, E.; Pearlman, N. Electrosurgical debulking of ovarian cancer: A new technique using the argon beam coagulator. Gynecol. Oncol. 1990, 39, 115–118. [Google Scholar] [CrossRef]
  2. Nieuwenhuyzen-de Boer, G.M.; Hofhuis, W.; Reesink-Peters, N.; Willemsen, S.; Boere, I.A.; Schoots, I.G.; Piek, J.M.J.; Hofman, L.N.; Beltman, J.J.; van Driel, W.J.; et al. Adjuvant Use of PlasmaJet Device During Cytoreductive Surgery for Advanced-Stage Ovarian Cancer: Results of the PlaComOv-study, a Randomized Controlled Trial in The Netherlands. Ann. Surg. Oncol. 2022, 29, 4833–4843. [Google Scholar] [CrossRef] [PubMed]
  3. Dewhirst, M.W.; Viglianti, B.L.; Lora-Michiels, M.; Hanson, M.; Hoopes, P.J. Basic principles of thermal dosimetry and thermal thresholds for tissue damage from hyperthermia. Int. J. Hyperth. 2003, 19, 267–294. [Google Scholar] [CrossRef] [PubMed]
  4. van de Berg, N.J.; van den Dobbelsteen, J.J.; Jansen, F.W.; Grimbergen, C.A.; Dankelman, J. Energetic soft-tissue treatment technologies: An overview of procedural fundamentals and safety factors. Surg. Endosc. 2013, 27, 3085–3099. [Google Scholar] [CrossRef] [PubMed]
  5. Glowka, T.R.; Standop, J.; Paschenda, P.; Czaplik, M.; Kalff, J.C.; Tolba, R.H. Argon and helium plasma coagulation of porcine liver tissue. J. Int. Med. Res. 2017, 45, 1505–1517. [Google Scholar] [CrossRef] [PubMed]
  6. Bristow, R.E.; Smith Sehdev, A.E.; Kaufman, H.S.; Montz, F.J. Ablation of metastatic ovarian carcinoma with the argon beam coagulator: Pathologic analysis of tumor destruction. Gynecol. Oncol. 2001, 83, 49–55. [Google Scholar] [CrossRef]
  7. Gale, P.; Adeyemi, B.; Ferrer, K.; Ong, A.; Brill, A.I.; Scoccia, B. Histologic characteristics of laparoscopic argon beam coagulation. J. Am. Assoc. Gynecol. Laparosc. 1998, 5, 19–22. [Google Scholar] [CrossRef]
  8. Tanner, E.J.; Dun, E.; Sonoda, Y.; Olawaiye, A.B.; Chi, D.S. A Comparison of Thermal Plasma Energy Versus Argon Beam Coagulator-Induced Intestinal Injury After Vaporization in a Porcine Model. Int. J. Gynecol. Cancer 2017, 27, 177–182. [Google Scholar] [CrossRef]
  9. Johanns, W.; Luis, W.; Janssen, J.; Kahl, S.; Greiner, L. Argon plasma coagulation (APC) in gastroenterology: Experimental and clinical experiences. Eur. J. Gastroenterol. Hepatol. 1997, 9, 581–587. [Google Scholar] [CrossRef]
  10. Kraemer, B.; Rothmund, R.; Fischer, K.; Scharpf, M.; Fend, F.; Smaxwil, L.; Enderle, M.D.; Wallwiener, D.; Neugebauer, A. A prospective, randomized, experimental study to investigate the peritoneal adhesion formation of noncontact argon plasma coagulation in a rat model. Fertil. Steril. 2011, 95, 1328–1332. [Google Scholar] [CrossRef]
  11. Kraemer, B.; Rothmund, R.; Fischer, K.; Scharpf, M.; Smaxwil, L.; Enderle, M.D.; Wallwiener, C.; Neugebauer, A. A prospective experimental study to investigate the peritoneal adhesion formation of argon plasma coagulation (APC) versus a novel aerosol plasma in a rat model. Surg. Innov. 2014, 21, 389–397. [Google Scholar] [CrossRef] [PubMed]
  12. Kraemer, B.; Scharpf, M.; Planck, C.; Tsaousidis, C.; Enderle, M.D.; Neugebauer, A.; Kroeker, K.; Fend, F.; Brucker, S.; Rothmund, R. Randomized experimental study to investigate the peritoneal adhesion formation of conventional monopolar contact coagulation versus noncontact argon plasma coagulation in a rat model. Fertil. Steril. 2014, 102, 1197–1202. [Google Scholar] [CrossRef] [PubMed]
  13. Kraemer, B.; Scharpf, M.; Keckstein, S.; Dippon, J.; Tsaousidis, C.; Brunecker, K.; Enderle, M.D.; Neugebauer, A.; Nuessle, D.; Fend, F.; et al. A prospective randomized experimental study to investigate the peritoneal adhesion formation after waterjet injection and argon plasma coagulation (HybridAPC) in a rat model. Arch. Gynecol. Obstet. 2018, 297, 961–967. [Google Scholar] [CrossRef]
  14. Fujishiro, M.; Yahagi, N.; Nakamura, M.; Kakushima, N.; Kodashima, S.; Ono, S.; Kobayashi, K.; Hashimoto, T.; Yamamichi, N.; Tateishi, A.; et al. Submucosal injection of normal saline may prevent tissue damage from argon plasma coagulation: An experimental study using resected porcine esophagus, stomach, and colon. Surg. Laparosc. Endosc. Percutaneous Tech. 2006, 16, 307–311. [Google Scholar] [CrossRef] [PubMed]
  15. Norton, I.D.; Wang, L.; Levine, S.A.; Burgart, L.J.; Hofmeister, E.K.; Yacavone, R.F.; Gostout, C.J.; Petersen, B.T. In vivo characterization of colonic thermal injury caused by argon plasma coagulation. Gastrointest. Endosc. 2002, 55, 631–636. [Google Scholar] [CrossRef]
  16. Norton, I.D.; Wang, L.; Levine, S.A.; Burgart, L.J.; Hofmeister, E.K.; Rumalla, A.; Gostout, C.J.; Petersen, B.T. Efficacy of colonic submucosal saline solution injection for the reduction of iatrogenic thermal injury. Gastrointest. Endosc. 2002, 56, 95–99. [Google Scholar] [CrossRef]
  17. Llarena, N.C.; Shah, A.B.; Biscotti, C.; Falcone, T.; Uy-Kroh, M.J. Thermal injury to the ovary and uterus in a porcine model: A comparison of four energy sources. Clin. Exp. Obstet. Gynecol. 2019, 46, 964–968. [Google Scholar] [CrossRef]
  18. Alletti, S.G.; Rosati, A.; Capozzi, V.A.; Pavone, M.; Gioe, A.; Cianci, S.; Chiantera, V.; Vizzielli, G.; Scaglione, G.; Fagotti, A.; et al. Use of Laparoscopic and Laparotomic J-Plasma Handpiece in Gynecological Malignancies: Results From A Pilot Study in A Tertiary Care Center. Front. Oncol. 2022, 12, 868390. [Google Scholar]
  19. Deb, S.; Sahu, B.; Deen, S.; Newman, C.; Powell, M. Comparison of tissue effects quantified histologically between PlasmaJet coagulator and Helica thermal coagulator. Arch. Gynecol. Obstet. 2012, 286, 399–402. [Google Scholar] [CrossRef]
  20. Madhuri, T.K.; Haagsma, B.E.N.; Williams, P.; Tailor, A.; Butler-Manuel, S.A. Pathologic analysis of tissue destruction with neutral argon plasma. Int. J. Gynecol. Cancer 2014, 24, 1022–1023. [Google Scholar]
  21. Sonoda, Y.; Olvera, N.; Chi, D.S.; Brown, C.L.; Abu-Rustum, N.R.; Levine, D.A. Pathologic analysis of ex vivo plasma energy tumor destruction in patients with ovarian or peritoneal cancer. Int. J. Gynecol. Cancer 2010, 20, 1326–1330. [Google Scholar] [PubMed]
  22. Roman, H.; Pura, I.; Tarta, O.; Mokdad, C.; Auber, M.; Bourdel, N.; Marpeau, L.; Sabourin, J.C. Vaporization of ovarian endometrioma using plasma energy: Histologic findings of a pilot study. Fertil. Steril. 2011, 95, 1853–1856.e4. [Google Scholar] [CrossRef] [PubMed]
  23. Nieuwenhuyzen-de Boer, G.M.; van de Berg, N.J.; Gao, X.S.; Ewing-Graham, P.C.; van Beekhuizen, H.J. The effects of neutral argon plasma versus electrocoagulation on tissue in advanced-stage ovarian cancer: A case series. J. Ovarian Res. 2022, 15, 140. [Google Scholar] [CrossRef] [PubMed]
  24. Holl, M.; Rasch, M.L.; Becker, L.; Keller, A.L.; Schultze-Rhonhof, L.; Ruoff, F.; Templin, M.; Keller, S.; Neis, F.; Kessler, F.; et al. Cell Type-Specific Anti-Adhesion Properties of Peritoneal Cell Treatment with Plasma-Activated Media (PAM). Biomedicines 2022, 10, 927. [Google Scholar] [CrossRef] [PubMed]
  25. Duan, J.; Lu, X.; He, G. On the penetration depth of reactive oxygen and nitrogen species generated by a plasma jet through real biological tissue. Phys. Plasmas 2017, 24, 073506. [Google Scholar] [CrossRef]
  26. Partecke, L.I.; Evert, K.; Haugk, J.; Doering, F.; Normann, L.; Diedrich, S.; Weiss, F.U.; Evert, M.; Huebner, N.O.; Guenther, C.; et al. Tissue Tolerable Plasma (TTP) induces apoptosis in pancreatic cancer cells in vitro and in vivo. BMC Cancer 2012, 12, 473. [Google Scholar] [CrossRef]
  27. Wenzel, T.; Berrio, D.A.C.; Daum, R.; Reisenauer, C.; Weltmann, K.D.; Wallwiener, D.; Brucker, S.Y.; Schenke-Layland, K.; Brauchle, E.M.; Weiss, M. Molecular Effects and Tissue Penetration Depth of Physical Plasma in Human Mucosa Analyzed by Contact- and Marker-Independent Raman Microspectroscopy. Acs Appl. Mater. Interfaces 2019, 11, 42885–42895. [Google Scholar] [CrossRef] [PubMed]
  28. Wenzel, T.; Berrio, D.A.C.; Reisenauer, C.; Layland, S.; Koch, A.; Wallwiener, D.; Brucker, S.Y.; Schenke-Layland, K.; Brauchle, E.M.; Weiss, M. Trans-mucosal efficacy of non-thermal plasma treatment on cervical cancer tissue and human cervix uteri by a next generation electrosurgical argon plasma device. Cancers 2020, 12, 267. [Google Scholar] [CrossRef]
  29. Dai, X.F.; Bazaka, K.; Richard, D.J.; Thompson, E.W.; Ostrikov, K. The Emerging Role of Gas Plasma in Oncotherapy. Trends Biotechnol. 2018, 36, 1183–1198. [Google Scholar] [CrossRef]
  30. Ranieri, P.; Shrivastav, R.; Wang, M.; Lin, A.; Fridman, G.; Fridman, A.A.; Han, L.H.; Miller, V. Nanosecond-Pulsed Dielectric Barrier Discharge–Induced Antitumor Effects Propagate through Depth of Tissue via Intracellular Signaling. Plasma Med. 2017, 7, 283–297. [Google Scholar] [CrossRef]
  31. Laroussi, M. From Killing Bacteria to Destroying Cancer Cells: 20 Years of Plasma Medicine. Plasma Process. Polym. 2014, 11, 1138–1141. [Google Scholar] [CrossRef]
  32. Szili, E.J.; Hong, S.H.; Oh, J.S.; Gaur, N.; Short, R.D. Tracking the Penetration of Plasma Reactive Species in Tissue Models. Trends Biotechnol. 2018, 36, 594–602. [Google Scholar] [CrossRef] [PubMed]
  33. Weiss, M.; Stope, M.B. Physical plasma: A new treatment option in gynecological oncology. Arch. Gynecol. Obstet. 2018, 298, 853–855. [Google Scholar] [CrossRef]
  34. Ruidiaz, M.E.; Cortes-Mateos, M.J.; Sandoval, S.; Martin, D.T.; Wang-Rodriguez, J.; Hasteh, F.; Wallace, A.; Vose, J.G.; Kummel, A.C.; Blair, S.L. Quantitative Comparison of Surgical Margin Histology Following Excision With Traditional Electrosurgery and a Low-Thermal-Injury Dissection Device. J. Surg. Oncol. 2011, 104, 746–754. [Google Scholar] [CrossRef]
  35. Ekin, M.; Dagdeviren, H.; Caypinar, S.S.; Erdogan, B.; Ayag, M.E.; Cengiz, H.; Yasar, L.; Helvacioglu, C. Comparative cosmetic outcome of surgical incisions created by the PEAK Plasma Blade and a scalpel after cesarean section by Patient and Observer Assessment Scale (POSAS): A randomized double blind study. Taiwan. J. Obstet. Gyne 2018, 57, 68–70. [Google Scholar] [CrossRef] [PubMed]
  36. Peprah, K.; Spry, C. Pulsed Electron Avalanche Knife (PEAK) PlasmaBlade versus Traditional Electrocautery for Surgery: A Review of Clinical Effectiveness and Cost-Effectiveness; Canadian Agency for Drugs and Technologies in Health: Ottawa, ON, Canada, 2019. [Google Scholar]
  37. Abu-Rustum, N.R.; Chi, D.S.; Sonoda, Y.; DiClemente, M.J.; Bekker, G.; Gemignani, M.; Poynor, E.; Brown, C.; Barakat, R.R. Transperitoneal laparoscopic pelvic and para-aortic lymph node dissection using the argon-beam coagulator and monopolar instruments: An 8-year study and description of technique. Gynecol. Oncol. 2003, 89, 504–513. [Google Scholar] [CrossRef] [PubMed]
  38. Madhuri, T.K.; Papatheodorou, D.; Tailor, A.; Sutton, C.; Butler-Manuel, S. First clinical experience of argon neutral plasma energy in gynaecological surgery in the UK. Gynecol. Surg. 2010, 7, 423–425. [Google Scholar] [CrossRef]
  39. Paquette, I.M.; Vogel, J.D.; Abbas, M.A.; Feingold, D.L.; Steele, S.R. The American society of colon and rectal surgeons clinical practice guidelines for the treatment of chronic radiation proctitis. Dis. Colon. Rectum 2018, 61, 1135–1140. [Google Scholar] [CrossRef]
  40. Siow, S.L.; Mahendran, H.A.; Seo, C.J. Complication and remission rates after endoscopic argon plasma coagulation in the treatment of haemorrhagic radiation proctitis. Int. J. Color. Dis. 2017, 32, 131–134. [Google Scholar] [CrossRef]
  41. Swan, M.P.; Moore, G.T.C.; Sievert, W.; Devonshire, D.A. Efficacy and safety of single-session argon plasma coagulation in the management of chronic radiation proctitis. Gastrointest. Endosc. 2010, 72, 150–154. [Google Scholar] [CrossRef]
  42. Sultania, S.; Sarkar, R.; Das, K.; Dhali, G.K. Argon plasma coagulation is an effective treatment for chronic radiation proctitis in gynaecological malignancy: An observational study. Color. Dis. 2019, 21, 465–471. [Google Scholar] [CrossRef] [PubMed]
  43. Lee, J.K.; Agrawal, D.; Thosani, N.; Al-Haddad, M.; Buxbaum, J.L.; Calderwood, A.H.; Fishman, D.S.; Fujii-Lau, L.L.; Jamil, L.H.; Jue, T.L.; et al. ASGE guideline on the role of endoscopy for bleeding from chronic radiation proctopathy. Gastrointest. Endosc. 2019, 90, 171–182. [Google Scholar] [CrossRef] [PubMed]
  44. Triantafyllou, K.; Gkolfakis, P.; Gralnek, I.M.; Oakland, K.; Manes, G.; Radaelli, F.; Awadie, H.; Duboc, M.C.; Christodoulou, D.; Fedorov, E.; et al. Diagnosis and management of acute lower gastrointestinal bleeding: European Society of Gastrointestinal Endoscopy (ESGE) Guideline. Endoscopy 2021, 53, C10. [Google Scholar] [PubMed]
  45. Panos, M.Z.; Koumi, A. Argon plasma coagulation in the right and left colon: Safety-risk profile of the 60W-1.2 l/min setting. Scand. J. Gastroenterol. 2014, 49, 632–641. [Google Scholar] [CrossRef] [PubMed]
  46. Olmos, J.A.; Marcolongo, M.; Pogorelsky, V.; Herrera, L.; Tobal, F.; Davolos, J.R. Long-term outcome of argon plasma ablation therapy for bleeding in 100 consecutive patients with colonic angiodysplasia. Dis. Colon. Rectum 2006, 49, 1507–1516. [Google Scholar] [CrossRef] [PubMed]
  47. Eickhoff, A.; Enderle, M.D.; Hartmann, D.; Eickhoff, J.C.; Riemann, J.F.; Jakobs, R. Effectiveness and Safety of PRECISE APC for the Treatment of Bleeding Gastrointestinal Angiodysplasia-A Retrospective Evaluation. Z. Gastroenterol. 2011, 49, 195–200. [Google Scholar] [CrossRef]
  48. Hill, N.; McQueen, J.; Morey, R.; Hanna, L.; Chandakas, S.; El-Toukhy, T.; Erian, J. Over one thousand patients with early stage endometriosis treated with the Helica Thermal Coagulator (HELICA): Safety aspects. Arch. Gynecol. Obstet. 2006, 274, 203–205. [Google Scholar] [CrossRef]
  49. Ai-Inizi, S.; Bamigboye, V. Laparoscopic Helica Thermal Coagulation for the Treatment of Early Endometriosis. J. Gynecol. Surg. 2007, 23, 45–51. [Google Scholar] [CrossRef]
  50. Hill, N.C.; El-Toukhy, T.; Chandakas, S.; Grigoriades, T.; Erian, J. Safety of the Helica Thermal Coagulator in treatment of early stage endometriosis. J. Obstet. Gynaecol. 2005, 25, 52–54. [Google Scholar] [CrossRef]
  51. Misra, G.; Sim, J.; El-Gizawy, Z.; Watts, K.; Jerreat, S.; Coia, T.; Ritchie, J.; O′Brien, S. Laparoscopic ablation or excision with helium thermal coagulator versus electrodiathermy for the treatment of mild-to-moderate endometriosis: Randomised controlled trial. BJOG 2020, 127, 1528–1535. [Google Scholar] [CrossRef]
  52. Al-Inizi, S. Re: Laparoscopic ablation or excision with helium thermal coagulator versus electrodiathermy for the treatment of mild-to-moderate endometriosis: Randomised controlled trial. BJOG 2020, 127, 1715–1716. [Google Scholar] [CrossRef]
  53. Nezhat, C.; Kho, K.A.; Morozov, V. Use of neutral argon plasma in the laparoscopic treatment of endometriosis. J. Soc. Laparoendosc. Surg. 2009, 13, 479–483. [Google Scholar] [CrossRef]
  54. Fuchs, P.; Czech, I.; Fuchs, A.; Sikora, J. Use of neutral argon plasma in the treatment of endometriosis initial findings. Clin. Exp. Obstet. Gynecol. 2019, 46, 434–436. [Google Scholar] [CrossRef]
  55. Roman, H.; Auber, M.; Mokdad, C.; Martin, C.; Diguet, A.; Marpeau, L.; Bourdel, N. Ovarian endometrioma ablation using plasma energy versus cystectomy: A step toward better preservation of the ovarian parenchyma in women wishing to conceive. Fertil. Steril. 2011, 96, 1396–1400. [Google Scholar] [CrossRef]
  56. Mircea, O.; Puscasiu, L.; Resch, B.; Lucas, J.; Collinet, P.; von Theobald, P.; Merviel, P.; Roman, H. Fertility Outcomes After Ablation Using Plasma Energy Versus Cystectomy in Infertile Women with Ovarian Endometrioma: A Multicentric Comparative Study. J. Minim. Invasive Gynecol. 2016, 23, 1138–1145. [Google Scholar] [CrossRef]
  57. Delbos, L.; Bouet, P.E.; Catala, L.; Lefebvre, C.; Teyssedou, C.; Descamps, P.; Legendre, G. Surgery using plasma energy for deep endometriosis: A quality of life assessment. J. Gynecol. Obstet. Hum. Reprod. 2018, 47, 359–364. [Google Scholar] [CrossRef] [PubMed]
  58. Bristow, R.E.; Montz, F.J. Complete surgical cytoreduction of advanced ovarian carcinoma using the argon beam coagulator. Gynecol. Oncol. 2001, 83, 39–48. [Google Scholar] [CrossRef]
  59. Trinh, H.; Ott, C.; Fanning, J. FeasibiLity of laparoscopic debulking with electrosurgical loop excision procedure and argon beam coagulator at recurrence in patients with previous laparotomy debulking. Am. J. Obstet. Gynecol. 2004, 190, 1394–1397. [Google Scholar] [CrossRef] [PubMed]
  60. Panuccio, E.; Leunen, K.; Van Nieuwenhuysen, E.; Neven, P.; Lambrechts, S.; Vergote, I. Use of PlasmaJet for Peritoneal Carcinomatosis in Ovarian Cancer. Int. J. Gynecol. Cancer 2016, 26, 1521–1524. [Google Scholar] [CrossRef] [PubMed]
  61. Vidal, G.C.; Babin, G.; Querleu, D.; Guyon, F. Primary debulking surgery of the upper abdomen and the diaphragm, with a plasma device surgery system, for advanced ovarian cancer. Gynecol. Oncol. 2017, 144, 223–224. [Google Scholar] [CrossRef] [PubMed]
  62. Volcke, A.; Van Nieuwenhuysen, E.; Han, S.; Salihi, R.; Van Gorp, T.; Vergote, I. Experience with PlasmaJet™ in debulking surgery in 87 patients with advanced-stage ovarian cancer. J. Surg. Oncol. 2021, 123, 1109–1114. [Google Scholar] [CrossRef] [PubMed]
  63. Kushnir, C.L.; Fleury, A.C.; Hill, M.C.; Silver, D.F.; Spirtos, N.M. The use of argon beam coagulation in treating vulvar intraepithelial neoplasia III: A retrospective review. Gynecol. Oncol. 2013, 131, 386–388. [Google Scholar] [CrossRef] [PubMed]
  64. Jones, B.; Jeevananthan, P.; Sayasneh, A.; Saso, S.; Chatterjee, J.; Boyle, D.; Smith, J.R. The novel application of plasma energy as a tissue preserving treatment modality for vulval and perianal intraepithelial neoplasia. BJOG Int. J. Obstet. Gynaecol. 2016, 123, 81. [Google Scholar] [CrossRef]
  65. Henes, M.; Bosmuller, H.; Neis, F.; Wallwiener, D.; Brucker, S.; Weiss, M. Non-invasive-physical-plasma treatment of low- and high-grade cervical intraepithelial neoplasia: A non-invasive and anaesthesia-independent treatment procedure evaluated in a prospective, monocentric clinical trial. Geburtsh Frauenheilk 2020, 80, E211. [Google Scholar]
  66. Marzi, J.; Stope, M.B.; Henes, M.; Koch, A.; Wenzel, T.; Holl, M.; Layland, S.L.; Neis, F.; Bosmuller, H.; Ruoff, F.; et al. Noninvasive Physical Plasma as Innovative and Tissue-Preserving Therapy for Women Positive for Cervical Intraepithelial Neoplasia. Cancers 2022, 14, 1933. [Google Scholar] [CrossRef]
  67. Polat, G.; Erni, B.; Navarini, A.; Kind, A.; Mueller, S.M. Three patients with chronic vulvar pruritus successfully treated with cold atmospheric pressure plasma. J. Dtsch. Dermatol. Ges. 2021, 19, 1346–1349. [Google Scholar] [CrossRef]
  68. Zubor, P.; Wang, Y.; Liskova, A.; Samec, M.; Koklesova, L.; Dankova, Z.; Dorum, A.; Kajo, K.; Dvorska, D.; Lucansky, V.; et al. Cold Atmospheric Pressure Plasma (CAP) as a New Tool for the Management of Vulva Cancer and Vulvar Premalignant Lesions in Gynaecological Oncology. Int. J. Mol. Sci. 2020, 21, 7988. [Google Scholar] [CrossRef]
  69. Ahn, H.J.; Kim, K.I.; Kim, G.; Moon, E.; Yang, S.S.; Lee, J.S. Atmospheric-Pressure Plasma Jet Induces Apoptosis Involving Mitochondria via Generation of Free Radicals. PLoS ONE 2011, 6, e28154. [Google Scholar] [CrossRef]
  70. Li, Y.; Kang, M.H.; Uhm, H.S.; Lee, G.J.; Choi, E.H.; Han, I. Effects of atmospheric-pressure non-thermal bio-compatible plasma and plasma activated nitric oxide water on cervical cancer cells. Sci. Rep. 2017, 7, 45781. [Google Scholar] [CrossRef]
  71. Jezeh, M.A.; Tayebi, T.; Khani, M.R.; Niknejad, H.; Shokri, B. Direct cold atmospheric plasma and plasma-activated medium effects on breast and cervix cancer cells. Plasma Process. Polym. 2020, 17, 1900241. [Google Scholar] [CrossRef]
  72. Kenari, A.J.; Siadati, S.N.; Abedian, Z.; Sohbatzadeh, F.; Amiri, M.; Gorji, K.E.; Babapour, H.; Zabihi, E.; Ghoreishi, S.M.; Mehraeen, R.; et al. Therapeutic effect of cold atmospheric plasma and its combination with radiation as a novel approach on inhibiting cervical cancer cell growth (HeLa cells). Bioorg. Chem. 2021, 111, 104892. [Google Scholar] [CrossRef] [PubMed]
  73. Iseki, S.; Nakamura, K.; Hayashi, M.; Tanaka, H.; Kondo, H.; Kajiyama, H.; Kano, H.; Kikkawa, F.; Hori, M. Selective killing of ovarian cancer cells through induction of apoptosis by nonequilibrium atmospheric pressure plasma. Appl. Phys. Lett. 2012, 100, 113702. [Google Scholar] [CrossRef]
  74. Utsumi, F.; Kajiyama, H.; Nakamura, K.; Tanaka, H.; Mizuno, M.; Ishikawa, K.; Kondo, H.; Kano, H.; Hori, M.; Kikkawa, F. Effect of Indirect Nonequilibrium Atmospheric Pressure Plasma on Anti-Proliferative Activity against Chronic Chemo-Resistant Ovarian Cancer Cells In Vitro and In Vivo. PLoS ONE 2013, 8, e81576. [Google Scholar] [CrossRef] [PubMed]
  75. Utsumi, F.; Kajiyama, H.; Nakamura, K.; Tanaka, H.; Hori, M.; Kikkawa, F. Selective cytotoxicity of indirect nonequilibrium atmospheric pressure plasma against ovarian clear-cell carcinoma. Springerplus 2014, 3, 1–9. [Google Scholar] [CrossRef]
  76. Bekeschus, S.; Wulf, C.P.; Freund, E.; Koensgen, D.; Mustea, A.; Weltmann, K.D.; Stope, M.B. Plasma Treatment of Ovarian Cancer Cells Mitigates Their Immuno-Modulatory Products Active on THP-1 Monocytes. Plasma 2018, 1, 201–217. [Google Scholar] [CrossRef]
  77. Bisag, A.; Bucci, C.; Coluccelli, S.; Girolimetti, G.; Laurita, R.; De Iaco, P.; Perrone, A.M.; Gherardi, M.; Marchio, L.; Porcelli, A.M.; et al. Plasma-activated Ringer’s Lactate Solution Displays a Selective Cytotoxic Effect on Ovarian Cancer Cells. Cancers 2020, 12, 476. [Google Scholar] [CrossRef]
  78. Rasouli, M.; Mehdian, H.; Hajisharifi, K.; Amini, E.; Ostrikov, K.; Robert, E. Plasma-activated medium induces apoptosis in chemotherapy-resistant ovarian cancer cells: High selectivity and synergy with carboplatin. Plasma Process. Polym. 2021, 18, e2100074. [Google Scholar] [CrossRef]
  79. Tuhvatulin, A.I.; Sysolyatina, E.V.; Scheblyakov, D.V.; Logunov, D.Y.; Vasiliev, M.M.; Yurova, M.A.; Danilova, M.A.; Petrov, O.F.; Naroditsky, B.S.; Morfill, G.E.; et al. Non-thermal Plasma Causes p53-Dependent Apoptosis in Human Colon Carcinoma Cells. Acta Nat. 2012, 4, 82–87. [Google Scholar] [CrossRef]
  80. Kumara, M.H.S.R.; Piao, M.J.; Kang, K.A.; Ryu, Y.S.; Park, J.E.; Shilnikova, K.; Jo, J.O.; Mok, Y.S.; Shin, J.H.; Park, Y.; et al. Non-thermal gas plasma-induced endoplasmic reticulum stress mediates apoptosis in human colon cancer cells. Oncol. Rep. 2016, 36, 2268–2274. [Google Scholar] [CrossRef]
  81. Choi, J.S.; Kim, J.; Hong, Y.J.; Bae, W.Y.; Choi, E.H.; Jeong, J.W.; Park, H.K. Evaluation of non-thermal plasma-induced anticancer effects on human colon cancer cells. Biomed. Opt. Express 2017, 8, 2649–2659. [Google Scholar] [CrossRef]
  82. Zhang, H.; Zhang, J.S.; Xu, S.D.; Wang, Z.F.; Xu, D.H.; Guo, L.; Liu, D.X.; Kong, M.G.; Rong, M.Z. Antitumor effects of hyperthermia with plasma-treated solutions on 3D bladder tumor spheroids. Plasma Process. Polym. 2021, 18, 2100070. [Google Scholar] [CrossRef]
  83. Ha, J.H.; Kim, Y.J. Photodynamic and Cold Atmospheric Plasma Combination Therapy Using Polymeric Nanoparticles for the Synergistic Treatment of Cervical Cancer. Int. J. Mol. Sci. 2021, 22, 1172. [Google Scholar] [CrossRef] [PubMed]
  84. Feil, L.; Koch, A.; Utz, R.; Ackermann, M.; Barz, J.; Stope, M.; Kramer, B.; Wallwiener, D.; Brucker, S.Y.; Weiss, M. Cancer-Selective Treatment of Cancerous and Non-Cancerous Human Cervical Cell Models by a Non-Thermally Operated Electrosurgical Argon Plasma Device. Cancers 2020, 12, 1037. [Google Scholar] [CrossRef] [PubMed]
  85. Li, W.; Yu, K.N.; Bao, L.Z.; Shen, J.; Cheng, C.; Han, W. Non-thermal plasma inhibits human cervical cancer HeLa cells invasiveness by suppressing the MAPK pathway and decreasing matrix metalloproteinase-9 expression. Sci. Rep. 2016, 6, 19720. [Google Scholar] [CrossRef] [PubMed]
  86. Koensgen, D.; Besic, I.; Gumbel, D.; Kaul, A.; Weiss, M.; Diesing, K.; Kramer, A.; Bekeschus, S.; Mustea, A.; Stope, M.B. Cold Atmospheric Plasma (CAP) and CAP-Stimulated Cell Culture Media Suppress Ovarian Cancer Cell Growth-A Putative Treatment Option in Ovarian Cancer Therapy. Anticancer. Res. 2017, 37, 6739–6744. [Google Scholar]
  87. Nakamura, K.; Peng, Y.; Utsumi, F.; Tanaka, H.; Mizuno, M.; Toyokuni, S.; Hori, M.; Kikkawa, F.; Kajiyama, H. Novel Intraperitoneal Treatment With Non-Thermal Plasma-Activated Medium Inhibits Metastatic Potential of Ovarian Cancer Cells. Sci. Rep. 2017, 7, 6085. [Google Scholar] [CrossRef]
  88. Nakamura, K.; Yoshikawa, N.; Mizuno, Y.; Ito, M.; Tanaka, H.; Mizuno, M.; Toyokuni, S.; Hori, M.; Kikkawa, F.; Kajiyama, H. Preclinical Verification of the Efficacy and Safety of Aqueous Plasma for Ovarian Cancer Therapy. Cancers 2021, 13, 1141. [Google Scholar] [CrossRef]
  89. Biscop, E.; Lin, A.; Van Boxem, W.; Van Loenhout, J.; De Backer, J.; Deben, C.; Dewilde, S.; Smits, E.; Bogaerts, A. The Influence of Cell Type and Culture Medium on Determining Cancer Selectivity of Cold Atmospheric Plasma Treatment. Cancers 2019, 11, 1287. [Google Scholar] [CrossRef]
  90. Ruoff, F.; Henes, M.; Templin, M.; Enderle, M.; Boesmueller, H.; Wallwiener, D.; Brucker, S.Y.; Schenke-Layland, K.; Weiss, M. Targeted Protein Profiling of In Vivo NIPP-Treated Tissues Using DigiWest Technology. Appl. Sci. 2021, 11, 11238. [Google Scholar] [CrossRef]
  91. Garrido, T.; Baba, E.R.; Wodak, S.; Sakai, P.; Cecconello, I.; Maluf-Filho, F. Histology assessment of bipolar coagulation and argon plasma coagulation on digestive tract. World J. Gastrointest. Endosc. 2014, 6, 304–311. [Google Scholar] [CrossRef]
  92. Whitfield, A.M.; Burgess, N.G.; Bahin, F.F.; Kabir, S.; Pellisé, M.; Sonson, R.; Subramanian, V.; Mahajan, H.; McLeod, D.; Byth, K.; et al. Histopathological effects of electrosurgical interventions in an in vivo porcine model of colonic endoscopic mucosal resection. Gut 2021, 71, 864–870. [Google Scholar] [CrossRef] [PubMed]
  93. Ridings, P.; Bailey, C.; Bucknall, T.E. Argon beam coagulation as an adjunct in breast-conserving surgery. Ann. R. Coll. Surg. Engl. 1998, 80, 61–62. [Google Scholar] [PubMed]
  94. Friebel, T.R.; Narayan, N.; Ramakrishnan, V.; Morgan, M.; Cellek, S.; Griffiths, M. Comparison of PEAK PlasmaBlade (TM) to conventional diathermy in abdominal-based free-flap breast reconstruction surgery-A single-centre double-blinded randomised controlled trial. J. Plast. Reconstr. Aes. 2021, 74, 1731–1742. [Google Scholar] [CrossRef] [PubMed]
  95. Chupradit, S.; Widjaja, G.; Majeed, B.R.; Kuznetsova, M.; Ansari, M.J.; Suksatan, W.; Jalil, A.T.; Esfahani, B.G. Recent advances in cold atmospheric plasma (CAP) for breast cancer therapy. Cell Biol. Int. 2023, 47, 327–340. [Google Scholar] [CrossRef]
  96. Tarricone, R.; Torbica, A.; Drummond, M. Challenges in the Assessment of Medical Devices: The MedtecHTA Project. Health Econ. 2017, 26 (Suppl. 1), 5–12. [Google Scholar] [CrossRef] [PubMed]
  97. Nieuwenhuyzen-de Boer, G.M.; Geraerds, A.J.L.M.; van der Linden, M.H.; van Doorn, H.C.; Polinder, S.; van Beekhuizen, H.J. Cost Study of the PlasmaJet Surgical Device Versus Conventional Cytoreductive Surgery in Patients With Advanced-Stage Ovarian Cancer. JCO Clin. Cancer Inform. 2022, 6, e2200076. [Google Scholar] [CrossRef] [PubMed]
Cancers 15 02386 g001 550
Figure 1. PRISMA flowchart indicating the selection of articles for this systematic review.
Figure 1. PRISMA flowchart indicating the selection of articles for this systematic review.
Cancers 15 02386 g001
Table
Table 1. An overview of clinically (gyn.) tested plasma-based devices, grouped by plasma type.
Table 1. An overview of clinically (gyn.) tested plasma-based devices, grouped by plasma type.
TypeFormBrand
Electrosurgery (plasma-assisted)BeamABC, ConMed, Largo, FL, USA.
APC, ARCO series, Söring GmbH, Quickborn, DE.
APC, ERBE GmbH, Tübingen, DE.
HTC, Helica Instruments Ltd., Currie, UK.
HybridAPC, ERBE GmbH, Tübingen, DE.
J-Plasma, Apyx Medical, Clearwater, FL, USA.
MABS, KLS Martin Group, Tuttlingen, DE.
RimPlasmaBlade (PEAK), Medtronic, Dublin, IE.
NAP Neutral argon plasmaBeamPlasmaJet, Plasma Surgical, Atlanta, GA, USA.
CAP 1 Cold atmospheric plasmaBeam (APPJ)kINPen, Neoplas med GmbH, Greifswald, DE.
Surface (DBD)PlasmaDerm, CINOGY System GmbH, Duderstadt, DE.
Medium (PAM/PAL)All non-commercial or not clinically (gyn.) tested
1 Or LTP (low-temperature plasma), NEAPP (non-equilibrium atmospheric pressure plasma).
Table
Table 3. Overview of CAP devices and experimental models, annotated as: C = cancer cell line, R = rodent, 1 = in vivo, 2 = in vitro, O = ovary, Ce = cervix, Co = colon.
Table 3. Overview of CAP devices and experimental models, annotated as: C = cancer cell line, R = rodent, 1 = in vivo, 2 = in vitro, O = ovary, Ce = cervix, Co = colon.
Author, Year [Ref.]Experimental SettingDevice Type
Tissue
Models		Pelvic Organ (Cancer) Cell Lines
Reduced viability/apoptosis
Ahn, 2011 [69]
Li, 2017 [70]
Wenzel, 2020 [28]
Jezeh, 2020 [71]
Kenari, 2021 [72]		C2-Ce



HeLa
HeLa, HFB
SiHa
HeLa, HFB
HeLa		Custom APPJ (N2/air)
Custom DBD (N2) and PAL (NO)
Custom APPJ VIO3 APC ERBE (Ar)
Custom APPJ (He) and PAM (He/He + O2)
Custom APPJ and DBD (Ar + air)
Iseki, 2012 [73]
Utsumi, 2013 [74]
Utsumi, 2014 [75]
Bekeschus, 2018 [76]
Bisag, 2020 [77]
Rasouli, 2021 [78]		C2-O




SKOV-3, HRA, WI-38, MRC-5
NOS2, NOS3
TOV21G, SKOV-3, ES-2, NOS2, OHFC, HPMC
SKOV-3, OVCAR-3
SKOV-3, OV-90, HOSE, F1, F2
SKOV-3, A2780 CP, GC 		Custom APPJ (Ar)
Custom PAM (Ar)
Custom PAM (Ar)
kINPen MED, APPJ (Ar)
Custom/AlmaPlasma PAL (air)
Custom APPJ (He) and PAM (He)
Tuhvatulin, 2012 [79]
Kumara, 2016 [80]
Choi, 2017 [81]		C2-Co

HCT116
SNUC5
HCT116		MicroPlaSter β, APPJ (Ar)
Custom DBD (O2 + Ar)
Custom DBD (N2)
Reduced proliferation/growth
Feil, 2020 [84]
Li, 2016 [85]		C2-Ce
SiHa, CaSki, C-33-A, DoTc2 4510, NCCT
HeLa		MABS, APPJ (Ar)
Custom DBD (He)
Koensgen, 2017 [86]
Nakamura, 2017 [87]
Nakamura, 2021 [88]		C2-O

SKOV-3, OVCAR-3, TOV-21G, TOV-112D
ES2, SKOV3, HPMC
ES2, SKOV3, OV90, OVCAR3, CAOV3		kINPen MED, APPJ (Ar)
Custom PAM (Ar)
Custom/Tough Plasma PAM/PAL (Ar)
Utsumi, 2013 [74]
Nakamura, 2017 [87]
Nakamura, 2021 [88]		R1-O

NOS2
ES2
ES2		Custom PAM (Ar)
Custom PAM (Ar)
Custom PAM (Ar)
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van de Berg, N.J.; Nieuwenhuyzen-de Boer, G.M.; Gao, X.S.; Rijstenberg, L.L.; van Beekhuizen, H.J. Plasma Device Functions and Tissue Effects in the Female Pelvis—A Systematic Review. Cancers 2023, 15, 2386. https://doi.org/10.3390/cancers15082386

AMA Style

van de Berg NJ, Nieuwenhuyzen-de Boer GM, Gao XS, Rijstenberg LL, van Beekhuizen HJ. Plasma Device Functions and Tissue Effects in the Female Pelvis—A Systematic Review. Cancers. 2023; 15(8):2386. https://doi.org/10.3390/cancers15082386

Chicago/Turabian Style

van de Berg, Nick J., Gatske M. Nieuwenhuyzen-de Boer, Xu Shan Gao, L. Lucia Rijstenberg, and Heleen J. van Beekhuizen. 2023. "Plasma Device Functions and Tissue Effects in the Female Pelvis—A Systematic Review" Cancers 15, no. 8: 2386. https://doi.org/10.3390/cancers15082386

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