Sage Journals: Discover world-class research

Abstract

The gold standard treatment for bladder cancer is radical cystectomy that implies bladder removal coupled to urinary diversions. Despite the serious complications and the impossibility of controlled active voiding, bladder substitution with artificial systems is a challenge and cannot represent a real option, yet. In this article, we present hydraulic artificial detrusor prototypes to control and drive the voiding of an artificial bladder (AB). These prototypes rely on two actuator designs (origami and bellows) based either on negative or positive operating pressure, to be combined with an AB structure. Based on the bladder geometry and size, we optimized the actuators in terms of contraction/expansion performances, minimizing the liquid volume required for actuation and exploring different actuator arrangements to maximize the voiding efficiency. To operate the actuators, an ad hoc electrohydraulic circuit was developed for transferring liquid between the actuators and a reservoir, both of them intended to be implanted. The AB, actuators, and reservoir were fabricated with biocompatible flexible thermoplastic materials by a heat-sealing process. We assessed the voiding efficiency with benchtop experiments by varying the actuator type and arrangement at different simulated patient positions (horizontal, 45° tilted, and vertical) to identify the optimal configuration and actuation strategy. The most efficient solution relies on two bellows actuators anchored to the AB. This artificial detrusor design resulted in a voiding efficiency of about 99%, 99%, and 89%, in the vertical, 45° tilted, and horizontal positions, respectively. The relative voiding time was reduced by about 17, 24, and 55 s compared with the unactuated bladder.

Get full access to this article

View all access options for this article.

References

Richters

, Aben

, Kiemeney

. The global burden of urinary bladder cancer: an update. World J Urol, 2020; 38:1895–1904.

Stein

, Hohenfellner

, Pahernik

, et al. Urinary diversion—approaches and consequences. Dtsch Arztebl Int, 2012; 109:617–622.

Herdiman

, Ong

, Johnson

. Orthotopic bladder substitution (neobladder): part II postoperative complications, management, and long-term follow-up. J Wound Ostomy Continence Nurs, 2013; 40:171–180.

Chang

DTS

, Lawrentschuk

. Orthotopic neobladder reconstruction. Urol Ann, 2015; 7:1–7.

El-Taji

, Khattak

, Hussain

. Bladder reconstruction: the past, present and future (Review). Oncol Lett, 2015; 10:3–10.

Adamowicz

, Pokrywczynska

, Van Breda

, et al. Concise review: tissue engineering of urinary bladder; we still have a long way to go?. Stem Cells Transl Med, 2017; 6:2033–2043.

Barrett

, O'sullivan

, Parulkar

, et al. Artificial bladder replacement: a new design concept. Mayo Clin Proc, 1992; 67:215–220.

Rohrmann

, Albrecht

, Hannappel

, et al. Alloplastic replacement of the urinary bladder. J Urol, 1996; 156:2094–2097.

Gürpinar

, Griffith

. The prosthetic bladder. World J Urol, 1996; 14:47–52.

10.

Cosentino

, Gaya

, Breda

, et al. Alloplastic bladder substitution: are we making progress?. Int Urol Nephrol, 2012; 44:1295–1303.

11.

Mazzocchi

, Ricotti

, Pinzi

, et al. Magnetically controlled endourethral artificial urinary sphincter. Ann Biomed Eng, 2017; 45:1181–1193.

12.

AMS 800, Boston Scientific. Available at: www.bostonscientific.com/en-US/products/artificial-urinary-sphincter/ams-800-artificial-urinary-sphincter.html (Accessed May 03, 2021).

13.

Hached

, Saadaoui

, Loutochin

, et al. Novel, wirelessly controlled, and adaptive artificial urinary sphincter. IEEE/ASME Trans Mech, 2015; 20:3040–3052.

14.

Marziale

, Lucarini

, Mazzocchi

, et al. Comparative analysis of occlusion methods for artificial sphincters. Artif Organs, 2020; 44:995–1005.

15.

Marziale

, Lucarini

, Mazzocchi

, et al. Artificial sphincters to manage urinary incontinence: a review. Artif Organs, 2018; 42:E215–E233.

16.

Yang

, An

, Liu

, et al. Soft artificial bladder detrusor. Adv Healthc Mater, 2018; 7:1701014.

17.

Hassani

, Peh

WYX

, Gammad

GGL

, et al. A 3D printed implantable device for voiding the bladder using shape memory alloy (SMA) actuators. Adv Sci, 2017; 4:1700143.

18.

Hassani

, Gammad

GGL

, Mogan

, et al. Design and anchorage dependence of shape memory alloy actuators on enhanced voiding of a bladder. Adv Mater Technol, 2018; 3:1700184.

19.

Hassani

, Mogan

, Gammad

GGL

, et al. Toward self-control systems for neurogenic underactive bladder: a triboelectric nanogenerator sensor integrated with a bistable micro-actuator. ACS Nano, 2018; 12:3487–3501.

20.

Hassani

, Jin

, Yokota

, et al. Soft sensors for a sensing-actuation system with high bladder voiding efficiency. Sci Adv, 2020; 6:eaba0412.

21.

Zhuo

, Dan

, Gensong

, et al. Design of a mechatronics model of urinary bladder and realization and evaluation of its prototype. Appl Bionics Biomech, 2019; 2019:9431781.

22.

Weiss

, Deyhle

, Kovacs

, et al. Designing micro- and nanostructures for artificial urinary sphincters. In: Bar-Cohen Y (Ed). Electroactive Polymer Actuators and Devices (EAPAD) 2012. United States: The International Society for Optical Engineering,, 2012:8340.

23.

Roche

, Horvath

, Wamala

, et al. Soft robotic sleeve supports heart function. Sci Transl Med, 2017; 9:eaaf3925.

24.

Payne

, Wamala

, Abah

, et al. An implantable extracardiac soft robotic device for the failing heart: mechanical coupling and synchronization. Soft Robot, 2017; 4:241–250.

25.

Sales

, McCarthy

. Understanding the C-pulse device and its potential to treat heart failure. Curr Heart Fail Rep, 2010; 7:27–34.

26.

Gregorcyk

. The current status of the Acticon Neosphincter. Clin Colon Rectal Surg, 2005; 18:32–37.

27.

Volder

, Reynaerts

. Pneumatic and hydraulic microactuators: a review. J Micromech Microeng, 2010; 20:043001.

28.

Paternò

, Tortora

, Menciassi

. Hybrid soft-rigid actuators for minimally invasive surgery. Soft Robot, 2018; 5:783–799.

29.

Pinzi

, Ricotti

, Mazzocchi

, et al. Artificial bladder. WO2017145128A1, 2017.

30.

Cardona

, Iacovacci

, Mazzocchi

, et al. Novel nanostructured coating on PDMS substrates featuring high resistance to urine. ACS Appl Bio Mater, 2019; 2:255–265.

31.

Lukacz

, Sampselle

, Gray

, et al. A healthy bladder: a consensus statement. Int J Clin Pract, 2011; 65:1026–1036.

32.

Pane

, Mazzocchi

, Iacovacci

, et al. Smart implantable artificial bladder: an integrated design for organ replacement. IEEE Trans Biomed Eng, 2021; 68:2088–2097.

33.

, Vogt

, Rus

, et al. Fluid-driven origami-inspired artificial muscles. Proc Natl Acad Sci USA, 2017; 114:13132.

34.

Yang

, Greczek

, Asbeck

. Modeling and analysis of a high-displacement pneumatic artificial muscle with integrated sensing. Front Robot AI, 2019; 5:136.

35.

Becker

, Ranzani

, Russo

, et al. Pop-up tissue retraction mechanism for endoscopic surgery. In: Zhang H (Ed). 2017 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). United States:, 2017:920–927.

36.

Kelly

, Macdougall

, Olabisi

, et al. In vivo response to polypropylene following implantation in animal models: a review of biocompatibility. Int Urogynecol J, 2017; 28:171–180.

37.

Baylón

, Rodríguez-Camarillo

, Elías-Zúñiga

, et al. Past, present and future of surgical meshes: a review. Membranes (Basel), 2017; 7:47.

38.

Torregrossa

, Anyanwu

, Zucchetta

, et al. SynCardia: the total artificial heart. Ann Cardiothorac Surg, 2014; 3:612–620.

39.

The AMS Conceal Reservoir. Boston Scientific, 2016. Available at: https://www.amsmenshealth.com/content/dam/bostonscientific/uro-wh/general/ams/Resources/MH-402906-AA_Conceal%20Physician%20Sell%20Sheet-final.pdf (Accessed: May 19, 2021).

40.

Devreese

, Nuyens

, Staes

, et al. Do posture and straining influence urinary-flow parameters in normal women?. Neurourol Urodyn, 2000; 19:3–8.

41.

Yang

, Chen

, et al. Female voiding postures and their effects on micturition. Int Urogynecol J, 2010; 21:1371–1376.

42.

Tam

, Wong

, Bs

, et al. Prevalence of incomplete bladder emptying among elderly in convalescent wards: a pilot study. Asian J Gerontol Geriatr, 2006; 1:66–71.

43.

, Bhatia

. Lower urinary tract disorders in postmenopausal women. In: Lobo RA, ed. Treatment of the Postmenopausal Woman basic and clinical aspects. Academic Press;, 2007:693–737.

44.

Menciassi

, Iacovacci

. Implantable biorobotic organs. APL Bioeng, 2020; 4:040402.

45.

, Lee

. Evolving flexible sensors, wearable and implantable technologies towards BodyNET for advanced healthcare and reinforced life quality. IEEE Open J Circuits Syst, 2021; 2:702–720.

46.

Arab Hassani

, Shi

, Wen

, et al. Smart materials for smart healthcare—moving from sensors and actuators to self-sustained nanoenergy nanosystems. Smart Mater Med, 2020; 1:92–124.

47.

Wang

, He

, Lee

. Development of neural interfaces and energy harvesters towards self-powered implantable systems for healthcare monitoring and rehabilitation purposes. Nano Energy, 2019; 65:104039.

48.

Dai

, Li

, Shi

, et al. Recent progress of self-powered respiration monitoring systems. Biosens Bioelectron, 2021; 194:113609.

49.

Zou

, Bo

, Li

. Recent progress in human body energy harvesting for smart bioelectronic system. Fundam Res, 2021; 1:364–382.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.56 MB

0.00 MB

Hydraulic Detrusor for Artificial Bladder Active Voiding

Abstract

Get full access to this article

References

Supplementary Material