An implantable MEMS micropump system for drug delivery in small animals

Gensler, Heidi; Sheybani, Roya; Li, Po-Ying; Mann, Ronalee Lo; Meng, Ellis

doi:10.1007/s10544-011-9625-4

Cited by 136 publications

(139 citation statements)

References 52 publications

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“…Such devices usually need an on-board power source (e.g. a battery), which significantly affects the overall size of the device and where it can be implanted in and around the body [20]. On the other hand, an osmotic micropump [21] does not require energy and this means that a drug delivery system based on an osmotic pump is much smaller and simpler than the actively operated mechanical displacement micropumps and electro and magneto-kinetic micropumps [22].…”

Section: Implantable Drug Delivery Systemsmentioning

confidence: 99%

Towards soft robotic devices for site-specific drug delivery

Alici

2015

Expert Review of Medical Devices

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Considerable research efforts have recently been dedicated to the establishment of various drug delivery systems (DDS) that are mechanical/physical, chemical and biological/molecular DDS. In this paper, we report on the recent advances in site-specific drug delivery (site-specific, controlled, targeted or smart drug delivery are terms used interchangeably in the literature, to mean to transport a drug or a therapeutic agent to a desired location within the body and release it as desired with negligibly small toxicity and side effect compared to classical drug administration means such as peroral, parenteral, transmucosal, topical and inhalation) based on mechanical/physical systems consisting of implantable and robotic drug delivery systems. While we specifically focus on the robotic or autonomous DDS, which can be reprogrammable and provide multiple doses of a drug at a required time and rate, we briefly cover the implanted DDS, which are well-developed relative to the robotic DDS, to highlight the design and performance requirements, and investigate issues associated with the robotic DDS. Critical research issues associated with both DDSs are presented to describe the research challenges ahead of us in order to establish soft robotic devices for clinical and biomedical applications. Towards soft robotic devices for site-specific drug delivery Abstract Considerable research efforts have recently been dedicated to the establishment of various drug delivery systems (DDS) which are mechanical / physical, chemical and biological/molecular DDS. In this paper, we report on recent advances in site-specific drug delivery 1 based on mechanical / physical systems consisting of implantable and robotic drug delivery systems. While we specifically focus on the robotic or autonomous DDS, which can be reprogrammable and provide multiple doses of a drug at a required time and rate, we briefly cover the implanted DDS, which are well-developed relative to the robotic DDS, to highlight the design and performance requirements, and investigate issues associated with the robotic DDS. Critical research issues associated with both DDSs are presented to describe the research challenges ahead of us in order to establish really soft robotic devices for clinical and biomedical applications.

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Section: Implantable Drug Delivery Systemsmentioning

confidence: 99%

Towards soft robotic devices for site-specific drug delivery

Alici

2015

Expert Review of Medical Devices

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“…One of the greatest advantages of BioMEMS in the treatment of chronic diseases is that, in addition to localized/targeted delivery, they are able to provide personalized drug delivery in the form of a continuous pulsatile drug release profile [2,39,40]. This personalized drug release profile is specifically designed to maximize the therapeutic effects of the drug while limiting the side effects associated with overdose in conventional drug therapies [40]. In order to perform this mode of treatment with patients, implantable BioMEMS must be able to remain operable for a long period of time such that long term personalized medication can be used to treat these chronic diseases.…”

Section: Long Operation Timementioning

confidence: 99%

“…A responsive drug delivery system would allow the drug dosage to be specifically tuned according to the type and state of the disease within the individual, providing personalized drug delivery, maximizing the therapeutic effects of the drugs and reducing the overdose induced side-effects [40]. These systems have biosensors which allow the BioMEMS drug delivery devices to evaluate the efficiency of the administered drug by monitoring specific marker molecules of the disease being treated [56].…”

Section: Controllabilitymentioning

confidence: 99%

Approaches and Challenges of Engineering Implantable Microelectromechanical Systems (MEMS) Drug Delivery Systems for in Vitro and in Vivo Applications

Tng

Song

et al. 2012

Micromachines

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Despite the advancements made in drug delivery systems over the years, many challenges remain in drug delivery systems for treating chronic diseases at the personalized medicine level. The current urgent need is to develop novel strategies for targeted therapy of chronic diseases. Due to their unique properties, microelectromechanical systems (MEMS) technology has been recently engineered as implantable drug delivery systems for disease therapy. This review examines the challenges faced in implementing implantable MEMS drug delivery systems in vivo and the solutions available to overcome these challenges.

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“…According to Lorentz principle, stimulating these fields lead to the appearance of a force along the fluid path [7,8]. Derived force can be employed for diagnosis and treatment in different ways such as drug delivery to injured organs, drug delivery with nano-particles for invaded cancerous cells, nanorobot navigators in local surgeries and many other applications [8][9][10][11][12]. In fact, in some cases lower velocity in drug delivery to injured locations makes it possible to have a lower drug concentration and lower treatment performance [8,13,14].…”

Section: Introductionmentioning

confidence: 99%

“…In fact, in some cases lower velocity in drug delivery to injured locations makes it possible to have a lower drug concentration and lower treatment performance [8,13,14]. Therefore, by using MHD pumps drug delivers to injured organs in higher speed and more efficiently [11]. Alongside with the application of MHD pumps for simulating, pumping, sorting and mixing fluids in channels, it will be used in industry for heating and circulation, buoyancy, and rotation of liquid metals [3,15].…”

Section: Introductionmentioning

confidence: 99%

Fluctuation in Blood Velocity under Applied Electromagnetic Pulse Fields

Roozbeh¹

2017

IJBSBE

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The definition of the "Lorentz Force" comes from applying electrical and magnetic fields straight to fluid direction. This force is an elemental factor for magnetohydrodynamic pumps. Based on energy and linear momentum conservation laws, we can derive the governing equations for our problem. Accordingly, MHD pump performance is impacted with any small fluctuation in electrically conducting fluid and current density in blood carrying arteries. After implementing constant and transient electromagnetic pulse fields, we were interested to employ finite element approach to study velocity profile and temperature distribution of the flowing blood. The novelty of this work is considering the edge effect, which was not considered in any other previous works. Results show that transient electromagnetic fields with stronger pulses increase the fluid velocity with lower fluctuations in various temperatures. Through defining an allowable criterion for temperature range, these results will be extensively applicable in drug delivery and other biomedical engineering applications.

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An implantable MEMS micropump system for drug delivery in small animals

Cited by 136 publications

References 52 publications

Towards soft robotic devices for site-specific drug delivery

Towards soft robotic devices for site-specific drug delivery

Approaches and Challenges of Engineering Implantable Microelectromechanical Systems (MEMS) Drug Delivery Systems for in Vitro and in Vivo Applications

Fluctuation in Blood Velocity under Applied Electromagnetic Pulse Fields

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