In a groundbreaking advancement at the intersection of bioengineering and sustainable energy, researchers have unveiled a miniaturized, portable bio-battery constructed from living hydrogels embedded with electroactive bacteria. This innovative device promises to revolutionize how bioelectrical stimulation and physiological monitoring are achieved by harnessing the metabolic processes of microorganisms encapsulated within a 3-D printed matrix. Spearheaded by the Shenzhen Institutes of Advanced Technology alongside collaborators from Shenzhen University, this research represents a leap toward sustainable, biocompatible energy solutions capable of integration into implantable medical devices and portable systems.
Traditional bio-batteries have long held appeal due to their inherent biocompatibility, adaptability to physiological environments, and potential for powering implantable devices without toxic byproducts. However, the challenges of miniaturization, portability, and integration with existing technology have stymied broad application. Addressing these limitations, the team designed a bio-battery platform leveraging Shewanella oneidensis MR-1, a bacterium known for its exceptional ability to transfer electrons extracellularly, thereby facilitating electron flow for bioelectric power generation.
Central to their design is the 3-D printing of living hydrogels, a soft, flexible matrix composed predominantly of alginate in which the bacteria are encapsulated. This approach preserves bacterial viability and metabolic function while permitting precise control over the device’s architecture. The hydrogel bio-anode incorporates the metabolically active bacteria, while the complementary bio-cathode consists of a ferricyanide-containing alginate hydrogel. These electrodes are separated by a Nafion ion-exchange membrane, mirroring the structural principles found in advanced lithium-ion battery technologies but adapted for biologically active components.
The bio-battery itself possesses a compact footprint of 20 millimeters in diameter and a height of just over three millimeters, underscoring its suitability for portable and implantable bio-devices. The metabolic activity of the encapsulated bacteria generates electrical current autonomously, enabling the battery to self-charge for up to ten cycles. Furthermore, it demonstrates excellent coulombic efficiency exceeding 99.5% over 50 charge-discharge cycles, indicating minimal energy loss during operation—a hallmark of mature electrochemical energy systems.
Crucially, the viability of Shewanella oneidensis MR-1 within the hydrogel matrix remains remarkably high throughout the battery’s operational lifespan, with over 70% survival maintained during multiple cycles and near-complete viability (97.6%) at the end of use. This preservation of the living components is vital for the bio-battery’s sustained performance and paves the way for longer-lasting bioenergetic devices, unlike conventional batteries that suffer from irreversible chemical degradation.
Although the power and energy densities of this bio-battery—0.4 mAh per gram capacity, approximately 8.31 microwatts per square centimeter of power, and 0.008 watt-hours per liter energy density—do not currently rival those of traditional lithium-ion batteries, the remarkable sustainability advantages are undeniable. By circumventing the need for rare or hazardous materials such as cobalt, lithium, manganese, or organic solvents, this technology positions itself as an environmentally friendly alternative that mitigates ecological and supply risks inherent in current energy storage solutions.
The potential biomedical applications for such a miniaturized bio-battery are wide-ranging and transformative. The team demonstrated its ability to deliver controlled electrical stimulation to biological tissues, particularly focusing on the sciatic and vagus nerves—two critical neural pathways involved in sensory, motor, and autonomic functions. The bio-battery’s capacity for precise modulation of bioelectrical signals introduces new prospects for non-invasive nerve stimulation therapies, potentially aiding conditions such as chronic pain, epilepsy, or cardiac arrhythmias without the drawbacks of conventional electrical stimulators.
Fundamentally, the bio-battery acts not just as a power source but as a biological interface capable of integrating living systems with electronic devices. The ability to 3-D print customized geometries facilitates tailoring to specific anatomical or functional requirements. Such versatility could enable patient-specific implants or wearable therapy devices that dynamically respond to physiological cues.
The use of Shewanella species as the electroactive agent within the hydrogel is particularly strategic. Known for their electrochemical robustness and environmental resilience, these bacteria efficiently shuttle electrons to external acceptors without requiring electrodes with complex surface modifications. Their encapsulation within a biocompatible alginate network ensures containment and viability while allowing nutrient and ion exchange necessary for sustained metabolic function.
Moreover, the ion-exchange Nafion membrane, a polymer widely used in fuel cells and battery separators, optimizes ion transport between anode and cathode compartments. This design aspect enhances the bio-battery’s electrochemical performance and stability, borrowing mature material science principles to augment living system functionality.
As neuromodulation and biosensing technologies gain momentum within personalized medicine, the integration of such bio-batteries as self-sufficient power modules can address key challenges related to device miniaturization, longevity, and biocompatibility. Unlike traditional batteries prone to leakage, bulk, and toxic breakdown products, bio-batteries based on living hydrogels offer a paradigm shift towards safer, adaptive, and sustainable bioelectronics.
This pioneering work also expands the scientific frontier of engineered living materials, blending synthetic biology, electrochemistry, and advanced manufacturing. By marrying microbial metabolism with precise 3-D fabrication techniques, the research embodies a new class of biohybrid systems capable of energy generation, sensing, and actuation in physiological environments.
In conclusion, the emergence of 3-D printable living hydrogel bio-batteries signifies a milestone in sustainable biomedical engineering. The demonstrated miniaturization, high viability of electroactive microbes, efficient electrochemical cycling, and practical nerve stimulation applications collectively suggest broad potential for future development. Beyond medical devices, these living bio-energy systems could inspire environmentally responsible power solutions for diverse portable electronics and biosensors. Continued exploration and optimization could lead to commercially viable bio-batteries that harmonize energy technology with living systems and ecological imperatives.
Subject of Research: Not applicable
Article Title: 3-D Printable Living Hydrogels as Portable Bio-energy Devices
News Publication Date: 5-Mar-2025
Web References:
10.1002/adma.202419249
Image Credits: SIAT
Keywords: bio-battery, living hydrogels, 3-D bioprinting, electroactive bacteria, Shewanella oneidensis MR-1, portable energy devices, nerve stimulation, bioelectrical stimulation, sustainable energy, implantable devices, biohybrid systems, metabolic energy generation
Tags: 3D printing in biotechnologybiocompatible energy sourceschallenges in bio-battery miniaturizationelectroactive bacteria in bioengineeringimplantable medical device innovationsliving hydrogel applicationsmetabolic processes in living systemsminiaturized bio-battery technologyphysiological monitoring advancementsportable bioelectrical stimulation devicesShewanella oneidensis MR-1 researchsustainable energy solutions in healthcare
