Using Biofield to Study Health Deviation

The #selfpowered continuous wireless health monitoring using body #energyharvesting can be beneficial in #elderlycare: it can track their mobility, heart health, and sleep patterns, enabling caregivers to optimize their care plans and in #medicalmonitoring of patients with #chronicdiseasemanagement or those in #postoperative care. #Healthalarm uses #personalizedmedicine haptic feedback to track health anywhere, sometimes by touching HmH #medicaldevices

Imagine a #healthalarm that can monitor your vital signs, alert you to potential #healthdeviation risks, and even provide you with real time feedback to improve your well-being. This is possible with the #Humanbiofield, the energy field that surrounds and permeates the human body.

The total energy output of the human body at rest is about 100W, which can be harvested for various purposes, such as powering #mhealth devices, #implanteddevices, or #wearabledevices. The #Humanbiofield is composed of the energy produced by the electromagnetic fields generated resting power by the heart 4.3W, brain 20W, and other organs. The potential energy in the human body as the sum of the energy of #mitochondria in each cell of the body is approximately 1.1?μW. That is the future for #implanteddevices.

The #Humanbiofield can also be measured by various devices, such as #ECGs, #EEGs, #MCGs, #MEGs, and #SQUIDs, as well as by more subtle methods, such as #GDV, #BEG, #BEP, #EPI, and Kirlian photography. These devices can capture the changes in the energy patterns of the human body under different conditions, such as stress, disease, or treatment.

The study of the #Humanbiofield can provide valuable information about the health and well-being of the individual, as well as the interactions between the individual and the environment.

What are some implications of these validation studies for health and medicine?

● The validation studies can help to improve the accuracy and reliability of measuring potential energy in the human body, which is important for assessing health status, estimating energy requirements, planning diets, and designing exercise programs.

● The validation studies can also help to detect subtle changes in the energy fields of the body under different conditions, such as stress, disease, or treatment. This can help to diagnose, prevent, or treat various health problems.

● The validation studies can also help to analyze the human body as a complex system of energetic and field phenomena. This can help to understand the effects of various factors, such as diet, exercise, environment, emotions, thoughts, beliefs, or interventions on the body’s energy potential and well-being.

The study of the #Humanbiofield is a promising field that can offer new possibilities for health and energy. By harnessing the human biofield, we can improve our quality of life and achieve our full potential.

To apply these validation methods in practice, we suggest the following steps:

- Estimate the potential energy of the human body as accurately and objectively as possible, using a combination of human biofield (energetic instruments) and calorimetry or respirometry. The former can assess the subtle energy fields of the body, while the latter can calculate the potential energy based on the heat input and output of the body (determination of initial and boundary conditions in homeostasis equations).

- Design and conduct a validation study with appropriate sample size, population, and protocol. Depending on the chosen validation method, one may need to recruit a sufficient number of participants that represent the target population and have similar characteristics, such as age, gender, body composition, and physical activity level. One also needs to measure the participants’ energy fields in a natural environment, such as their home or workplace, where they are comfortable and relaxed.

Compare and analyze the results of the validation study with appropriate statistical methods. Depending on the chosen validation method and the research question, one may use point-of-contact measurement approaches as reference methods.

This approach may be limited by the sensitivity and accuracy of the instruments that measure the biofield, as well as by the lack of a clear theoretical framework(homeostasis equations) and consensus on what constitutes the biofield and how it relates to health and disease.