Exoskeleton and Faraday Cage: The Feasibility of Using Titanium Implants

Titanium is a material that is widely recognized for its exceptional properties, such as high strength-to-weight ratio and resistance to corrosion. However, when it comes to making titanium implants safe for subdermal insertion, the challenges and risks involved make it a highly specialized and risky endeavor. This article explores the feasibility of using titanium implants for creating an exoskeleton or a Faraday cage, while also discussing the practical and ethical considerations involved.

Medical Considerations and Ethical Concerns

Titanium has a well-established record in the medical field for its use in implants and orthopedic devices. However, the process of subdermal insertion is not a standard medical practice and comes with several risks and ethical considerations. According to Marshall Woolner, surgical titanium is readily available; however, finding a willing surgeon to perform such an invasive procedure is extremely unlikely. Furthermore, a court may find it hard to believe that spending a significant sum, such as half a million dollars, to place subdermal titanium throughout the body is in the patient's best interest. Such a procedure could result in the loss of medical registration and other legal complications.

Practical Limitations of Titanium Implants

While titanium is medically inert and requires minimal preparation for implantation (sterilization being the primary requirement), there are practical limitations to using it for an exoskeleton or a Faraday cage. The weight of titanium, even when used in the form of wire mesh, would make it difficult to tolerate, especially over an extended period. Additionally, the intricate process of inserting titanium at critical points such as the eyes, nose, mouth, and joints would be impractical and may result in movement difficulties and pain for the patient.

Alternative Solutions: Metal Mesh Body Suit

Given the practical and ethical limitations of using titanium implants for creating an exoskeleton or a Faraday cage, a more feasible approach might be to wear a metal mesh body suit. This alternative solution would provide the necessary protection against electromagnetic spectrum energy without the need for invasive surgeries.

Conclusion

The use of titanium implants for creating an exoskeleton or a Faraday cage through subdermal insertion is fraught with practical and ethical challenges. The high cost, risk of complications, and impracticality of the procedure make it a challenging undertaking. As an alternative, a metal mesh body suit may be a more viable option for those seeking protection from electromagnetic energy.

Key Takeaways

Titanium has excellent medical properties, but subdermal insertion comes with significant risks. Ethical considerations and legal scrutiny may hinder the feasibility of such a procedure. The weight and practical placement of titanium would make it difficult to use for a full body exoskeleton or Faraday cage. A metal mesh body suit offers a more practical solution for protection against electromagnetic spectrum energy.

Keywords

titanium implants, exoskeleton, faraday cage, subdermal insertion, medical safety