Ionic footbaths are often used in holistic health centres and spas to aid in detoxification; however, claims that these machines eliminate toxins from the body have not been rigorously evaluated. In this proof-of-principle study, we sought to measure the release of potentially toxic elements from ionic footbaths into distilled and tap water with and without feet. Water samples were collected and analyzed following 30-minute ionic footbath sessions without feet using both distilled (
With the advent of the industrial revolution, the levels of toxicants in our water, air, and soil have risen dramatically such that even newborn infants are born with toxic elements and chemical pollutants in their bodies [
Currently, many methods of detoxification are available, such as dimercaptosuccinic acid (DMSA), which is known to bind to heavy metals and aid in their elimination from the body [
Consumer use of ionic footbaths appears to come predominantly from holistic health centres, hair salons, and health food stores which often promote ionic footbaths as a means to rid the body of toxins such as heavy metals and often charge upwards of $75 per session [
Following an empty search of Medline, EMBASE, AMED, Alt Health Watch, and CINAHL using the search terms “ionic,” “footbath,” and “detoxification,” a search on Google found one study conducted by the Centre for Research Strategies [
In this proof-of-principle study, we evaluated the IonCleanse Solo footbath. This product has been available in the market since 2002 [
This was a two-phase project. The objective of Phase I was to establish a baseline for the contribution of the ionic footbath machine to release potentially toxic elements (PTEs) when either distilled or tap water was used without feet present. Phase II had several objectives including whether the ionic footbath could (1) effectively remove PTEs through the feet of participants; (2) increase PTE release through the urine; (3) increase PTE release as measured through hair mineral analysis (HMA).
This was a proof-of-principle, nonrandomized, nonblinded comparative, no feet versus feet, trial conducted from the week of May 17, 2010 (Week 0) through to August 9, 2010 (Week 12). Ethics approval was given by Research Ethics Board of the Canadian College of Naturopathic Medicine (CCNM) according to the ethical standards set forth in the 1975 Helsinki Declaration. All participants enrolled gave written informed consent to participate in the study. This study was funded through a grant from the Holistic Health Research Foundation. The trial registry number is NCT01125592.
Between April and May 2010, healthy participants were recruited through e-mail to CCNM staff and students, website-based advertisements, and posters. The e-mail summarized the requirements for the study and asked interested individuals to respond to the study coordinator. The study was also open to the general public.
Inclusion criteria required participants over 18 years of age, in good health, and with a stable medication/supplementation regimen for at least six weeks prior to and during participation in the study. Individuals were excluded if they were not legally competent; were pregnant or nursing mothers; had a pacemaker; were organ transplant or metal joint implant recipients; took antiarrhythmic, anticoagulant or chelating medication; or took any medication whose absence could mentally or physically incapacitate them (antipsychotics, antiepileptics, etc.). Participants were excluded if they had used a sauna within two weeks prior to beginning the study. Participants were also instructed to avoid sauna use during the study.
IonCleanse SOLO (A Major Difference Inc., Aurora, Colo) ionic footbath was used for all sessions in the study. With knowledge of the trial to be conducted, A Major Difference Inc. donated an IonCleanse SOLO machine for the duration of this study. The components of the ionic footbath include the SOLO device, an array, a power cord, plastic foot tub liners, and a plastic foot tub container (Figure
Initial setup of IonCleanse SOLO footbath.
The array is composed of an acrylic housing, a copper rod held in place with a bolt and fly nut, and a metal plate folded on itself several times (Figure
Close up of a new IonCleanse SOLO footbath array.
The IonCleanse SOLO footbath was set up according to manufacturer’s instructions as follows. A new plastic liner lined the foot tub and the “source” water was used to fill the foot tub (approximately 3.75 litres of water per session). The array was plugged into the SOLO device and placed in the foot tub, ensuring that there was sufficient water to cover the copper bar of the array. The device was turned on, and both voltage and amperage, displayed on the front of the machine, were monitored to ensure they stayed within optimal operating range, 13–20 volts and 1.8–2.2 amperes, respectively. This range was maintained for all footbath sessions, and no changes were made to the preset program on the SOLO device. Each session ran for 30 minutes, indicated by a buzzer at the end of the session.
All footbath sessions were conducted at the Robert Schad Naturopathic Clinic (RSNC) located within CCNM.
Three independent footbath sessions using two brands of distilled water (Life Brand and Longo’s, 4-litre plastic container, steam-distilled water) were run. A sample of the distilled water was placed in the 100 mL sample bottle and labelled. The footbath was prepared as described above using distilled water. The machine was turned on, and 1/8 tsp of salt (Baleine Sea Salt, 30220 Aigues-Mortes, France), according to the manufacturer’s instructions, was placed in the footbath water. At the end of the session, the water was stirred and a sample taken. This procedure was used for the first two footbath sessions with distilled water. In the last session, the sample was obtained after the salt had been added to the foot tub. The footbath session continued as described above.
The following procedure was used for all tap water footbath sessions. At the outset, it was determined that 50 L of water would be required to conduct the six footbath sessions. A 105 L plastic container (Storage Solutions, Gracious Living, Woodbridge, ON) was used for all tap water tests. The level of 50 L was predetermined and marked on two of the outside walls of the 105 L plastic container. The hot and cold tap water was run for 30 seconds to ensure that no stagnant water remained in the pipes. The 105 L container was filled to the predetermined level with a mixture of hot and cold water, and, according to the manufacturer’s instructions, 6 × 1/8 tsp of sea salt (Baleine Sea Salt, 30220 Aigues-Mortes, France) were added and stirred 20 times. A water temperature of approximately 39-40°C was used. A 100 mL sample of the tap water was obtained and labelled with the identifier “CCNM” and a sequential number. The samples were numbered in the sequence in which they were obtained to blind the laboratory to the source of the water sample. Samples were placed in the refrigerator overnight and couriered to the laboratory the following day.
On Week 0, the baseline parameters of the footbath device were established as follows: daily, for three consecutive days, the SOLO device was set up as before and run for 30 minutes with no feet in the footbath water. Samples were taken. On Week 5, after all participant footbath sessions had been completed, three additional postsession “no feet” sessions were conducted on the same day and samples obtained.
An overview of the study schedule is provided in Figure
Study schedule.
At baseline and Week 12, participants were requested to provide a hair and 24-hour urine sample for analysis following instructions provided by the laboratory for obtaining these samples. Hair is a very stable medium [
Twenty-four-hour urine collections were also collected during the 24 hours following the second and fourth footbath sessions. Collection began the day of the footbath session and continued until the first morning void the day after.
Footbath sessions were scheduled weekly on the same weekday and time. To decrease any residual particulate matter or mineral-containing excretions participant’s feet were rinsed under running water prior to placing their feet in the foot tub. The tap water and footbath device were set up as previously described for the initial footbath session. For all footbaths conducted within the day, the 105 L container was used as a consistent water source. Participants placed their washed feet into the prefilled foot tub and the SOLO device turned on. At the end of 30 minutes, participants removed their feet from the footbath, the footbath water was stirred and a sample taken and labelled. At the end of the day, all samples were collected and couriered to the laboratory. The array was removed from the footbath and rinsed with clean water. Once the visible residue was removed, a disinfectant (Ultra-Safe Plus commercial cleaner, Safer Soaps, Traveler’s Rest, SC) was sprayed on the array as per the manufacturer’s recommendations. Several minutes later, the array was rinsed and dried with a clean towel.
Each week, the array was soaked in a dilute solution of ascorbic acid (A Major Difference Inc., Aurora, Colo) and water according to manufacturer’s instructions.
Water, hair, and urine analyses were performed using Inductively Coupled Plasma Source Mass Spectroscopy (ICP-MS) by CanAlt Health Laboratory Inc., Concord ON, Canada. Calibration of the method has been carried out using at least two internationally recognized National Institute of Standards and Technology (NIST) standards for each element and is validated by analysis of Certified Reference Material (CRM). CanAlt Health Laboratory follows and documents Good Laboratory Practice Standards for handling of materials, quality control, and standardization of instruments to control for determinate error and to provide quality assurance.
The water reports provided by CanAlt Health Laboratory Inc. list the concentrations of 28 individual elements. Descriptive statistics (total, mean, standard deviation) were calculated for each element. In addition, to facilitate reporting, elements tested were categorized into three groups and subtotals determined for “array components,” “essential elements,” and “PTEs” (Table
The change in each element’s concentration was calculated by subtracting the concentration in the postfootbath session (Post-FBS) from the concentration in the source sample (Pre-FBS) to derive the difference (Diff-FBS). There were 3 distinct groups of water samples: (1) distilled water with no feet, (2) tap water with no feet, and (3) tap water with feet. Mann-Whitney tests compared the Post-FBS to the Pre-FBS element concentration to determine whether the Diff-FBS element concentration was statistically significant. This analysis was done for both the tap water with no feet and the tap water with feet groups. One valid observation was sufficient for the highly controlled distilled water source to act as a comparison group, and this precluded use of the Mann-Whitney test. Also, Mann-Whitney test compared the Diff-FBS (no feet/feet) to determine whether the presence of participants’ feet affected results. A Kruskal-Wallis test comparing the total concentrations of the Pre-FBS and Post-FBS tap water with no feet and Post-FBS tap water with feet was used to determine whether a significant difference existed between the groups.
Categorization of reported elements by group.
Array components | Essential elements | Potentially toxic elements |
---|---|---|
(i) Chromium (Cr) | (i) Boron (Bo) | (i) aluminum (Al) [ |
(ii) Cobalt (Co) | (ii) Calcium (Ca) | (ii) Antimony (Sb) [ |
(iii) Copper (Cu) | (iii) Lithium (Li) | (iii) Arsenic (As) [ |
(iv) Iron (Fe) | (iv) Magnesium (Mg) | (iv) Barium (Ba) [ |
(v) Manganese (Mn) | (v) Phosphorus (P) | (v) Cadmium (Cd) [ |
(vi) Molybdenum (Mo) | (vi) Potassium (K) | (vi) Lead (Pb) [ |
(vii) Nickel (Ni) | (vii) Selenium (Se) | (vii) Silver (Ag) [ |
(viii) Silicon (Si) | (viii) Sodium (Na) | (viii) Uranium (U) [ |
(ix) Strontium (Sr) | ||
(x) Sulphur (S) | ||
(xi) Vanadium (Vn) | ||
(xii) Zinc (Zn) |
HMA reports list the concentration of 40 individual elements. Total PTEs, defined as Al, Sb, As, Ba, Beryllium (Be) [
The UA reports list the concentrations of 40 individual elements. Total PTEs, defined as Al, Sb, As, Ba, Be, Cd, Hg, Pb, and U, were summed for UA results. Microsoft Office Excel-2007 was used for all data manipulations and descriptive statistics. StatsDirect version 2.7.7 was used for the nonparametric statistics.
An e-mail request was sent out to all the staff (
While participants’ schedules necessitated some minor adjustments of appointment times, all but one of the footbath sessions occurred on the same weekday between 10 AM and 4 PM. One participant’s second footbath was performed two days after the usually scheduled session due to an illness unrelated to the study. Participants were requested to maintain a stable lifestyle and medication/supplementation regime throughout; however one participant, during Week 3, needed to take antibiotics for 11 days for an illness unrelated to the study.
The footbath sessions were well tolerated by all of the participants. There were no adverse events reported during the course of the study.
Characteristics of the participants.
Number | Mean age (years) | Age range | Medication use ( | Supplement use ( | |
---|---|---|---|---|---|
Gender | |||||
Male | 3 | 56.3 | 54–59 | 0 | 2 |
Female | 3 | 36.6 | 30–45 | 3 | 0 |
Total | 6 | 46.5 | 30–59 | 3 | 2 |
Changes in element concentrations in distilled water after running the machine without feet.
Elements (ug/L) | Distilled water + salt (pre-FBS) | Distilled water + salt (post-FBS) | Mean difference | %change |
---|---|---|---|---|
Aluminum | 25.0 | 26.0 | 1.0 | 4.0 |
Antimony | 0.0 | 2.0 | 2.0 | 200.0 |
Arsenic | 0.0 | 6.0 | 6.0 | 600.0 |
Barium | 0.0 | 0.0 | 0.0 | 0.0 |
Boron | 0.0 | 1.0 | 1.0 | 100.0 |
Cadmium | 0.0 | 9.0 | 9.0 | 900.0 |
Calcium | 30.0 | 150.0 | 120.0 | 400.0 |
Chromium | 4.0 | 23,634.0 | 23,630.0 | 590,750.0 |
Cobalt | 0.0 | 320.0 | 320.0 | 320.0 |
Copper | 40.0 | 280.0 | 240.0 | 600.0 |
Iron | 31.0 | 116,421.0 | 116,390.0 | 375,451.6 |
Lead | 1.0 | 0.0 | −1.0 | −100.0 |
Lithium | 0.0 | 0.0 | 0.0 | 0.0 |
Magnesium | 570.0 | 570.0 | 0.0 | 0.0 |
Manganese | 0.0 | 1,566.0 | 1,566.0 | 1566.0 |
Molybdenum | 50.0 | 3,155.0 | 3,105.0 | 6,210.0 |
Nickel | 2.0 | 15,179.0 | 15,177.0 | 758,850.0 |
Phosphorus | 21.0 | 59.0 | 38.0 | 180.9 |
Potassium | 60.0 | 50.0 | −10.0 | −16.7 |
Selenium | 0.0 | 1.0 | 1.0 | 100.0 |
Silicon | 20.0 | 1,170.0 | 1,150.0 | 5,750.0 |
Silver | 0.0 | 0.0 | 0.0 | 0.0 |
Sodium | 136,740.0 | 141,860.0 | 5,120.0 | 3.7 |
Strontium | 5.0 | 6.0 | 1.0 | 20.0 |
Sulfur | 0.0 | 0.0 | 0.0 | 0.0 |
Uranium | 0.0 | 0.0 | 0.0 | 0.0 |
Vanadium † | 1.0 | 59.0 | 58.0 | 5,800.0 |
Zinc | 10.0 | 30.0 | 20.0 | 200.0 |
Total | ||||
Array component‡ | ||||
Essential elements† | ||||
PTEs§ |
Though two different sources were used, it is evident from these results that Al, Cu, Fe, and Na were present in the distilled water in small amounts at the outset. In the Post-FBS, the largest changes in element concentrations were for Cr, Co, Cu, Fe, Mn, Mo, Ni, and Si. Total PTEs increased 17
Changes in element concentrations in tap water after running the machine without feet.
Elements ( | Pre-FBS ( | Post-FBS ( | Post-FBS–Pre-FBS | ||
Mean ± Std dev | Mean ± Std dev | Difference ± Std dev | %change | ||
Aluminum§ | 93.75 ± 11.35 | 105.00 ± 18.95 | 14.17 ± 12.22 | 15.1 | 0.257 |
Antimony§ | |||||
Arsenic§ | |||||
Barium§ | 20.00 ± 0.00 | 25.00 ± 5.48 | 5.00 ± 5.48 | 25.0 | 0.333 |
Boron† | 35.00 ± 5.77 | 36.67 ± 5.16 | 3.33 ± 5.16 | 9.5 | 0.905 |
Cadmium§ | |||||
Calcium† | 39,255.00 ± 1,354.51 | 39,843.33 ± 906.15 | 1,206.67 ± 893.37 | 3.1 | 0.609 |
Chromium‡ | |||||
Cobalt‡ | |||||
Copper‡ | |||||
Iron‡ | |||||
Lead§ | 2.75 ± 1.71 | 3.17 ± 1.17 | 0.33 ± 1.37 | 12.1 | 0.676 |
Lithium† | 0.00 ± 0.00 | 1.17 ± 2.86 | 1.17 ± 2.86 | 0.0 | 0.800 |
Magnesium† | 10,720.00 ± 437.34 | 11,025.00 ± 561.31 | 405.00 ± 427.73 | 3.7 | 0.476 |
Manganese‡ | |||||
Molybdenum‡ | |||||
Nickel‡ | |||||
Phosphorus† | 16.75 ± 15.73 | 48.50 ± 28.03 | 37.33 ± 21.73 | 222.9 | 0.114 |
Potassium† | 2,052.50 ± 235.28 | 2,146.67 ± 190.23 | −11.67 ± 163.64 | −0.6 | 0.610 |
Selenium† | 0.75 ± 0.50 | 0.50 ± 0.55 | 0.00 ± 0.00 | 0.0 | 0.905 |
Silicon‡ | |||||
Silver§ | 0.00 ± 0.00 | 0.00 ± 0.00 | 0.00 ± 0.00 | 0.0 | 0.000 |
Sodium† | 77,622.50 ± 41,701.87 | 101,911.67 ± 9,916.69 | 19,190.00 ± 38,454.88 | 24.7 | 0.114 |
Strontium† | 200.50 ± 4.80 | 202.83 ± 7.88 | 3.17 ± 10.94 | 1.6 | 0.114 |
Sulfur† | 6,245.00 ± 1,537.15 | 6,178.33 ± 1,234.35 | −628.33 ± 1,253.99 | −10.1 | 0.914 |
Uranium§ | 0.00 ± 0.00 | 0.00 ± 0.00 | 0.00 ± 0.00 | 0.0 | 0.000 |
Vanadium† | |||||
Zinc† | 22.50 ± 9.57 | 35.00 ± 17.61 | 16.67 ± 10.33 | 74.1 | 0.543 |
Total | |||||
Array components‡ | |||||
Essential elements† | 136,171.50 ± 43,506.28 | 161,473.17 ± 10,605.21 | 20,265.83 ± 39,878.15 | 14.9 | 0.171 |
PTEs§ | 118.75 ± 11.53 | 147.00 ± 25.42 | 30.50 ± 19.85 | 25.7 | 0.133 |
§PTEs: potentially toxic elements were defined to be aluminium, antimony, arsenic, barium, cadmium, lead, silver, and uranium.
†Essential elements were defined to be boron, calcium, lithium, magnesium, phosphorus, potassium, selenium, sodium, strontium, sulphur, vanadium, and zinc.
‡Array components were defined to be chromium, cobalt, copper, iron, manganese, molybdenum, nickel, and silicon.
Bold indicates a statistically significant difference,
The concentration of essential elements predominates in the tap water prior to the footbath. There are also PTEs in the tap water, with Al representing the largest concentration. In the Post-FBS, as with the distilled water results, the largest changes in element concentrations occur within the array elements (
Changes in element concentrations in tap water after running the machine with participants feet.
Elements ( | Pre-FBS ( | Post-FBS ( | Post-FBS FF–Pre-FBS | ||
Mean ± Std dev | Mean ± Std dev | Difference ± Std dev | %change | ||
Aluminum§ | 110.80 | 126.75 | 5.00 | 4.5 | 0.239 |
Antimony§ | 1.00 | 1.71 | 1.21 | 120.8 | 0.056 |
Arsenic§ | |||||
Barium§ | |||||
Boron† | 40.00 | 41.13 | 4.04 | 10.1 | 0.118 |
Cadmium§ | |||||
Calcium† | 39,316.00 | 39,091.46 | −231.04 | −0.6 | 0.250 |
Chromium‡ | |||||
Cobalt‡ | |||||
Copper‡ | |||||
Iron‡ | |||||
Lead§ | 2.40 | 2.50 | 0.00 | 0.0 | 0.607 |
Lithium† | 1.40 | 2.00 | 0.25 | 17.9 | 0.985 |
Magnesium† | 10,647.60 | 10,600.83 | −128.67 | −1.2 | 0.218 |
Manganese‡ | |||||
Molybdenum‡ | |||||
Nickel‡ | |||||
Phosphorus† | |||||
Potassium† | |||||
Selenium† | |||||
Silicon‡ | |||||
Silver§ | 0.00 | 0.00 | 0.00 | 0.0 | 0.000 |
Sodium† | |||||
Strontium† | 204.80 | 190.83 | −11.67 | −5.7 | 0.070 |
Sulfur† | 9,858.00 | 8,685.71 | −496.79 | −5.0 | 0.512 |
Uranium§ | 0.20 | 0.29 | 0.04 | 20.8 | 0.851 |
Vanadium† | |||||
Zinc† | |||||
Total | |||||
Array components‡ | |||||
Essential elements† | 158,689.22 | 159,238.88 | −2,212.53 | −1.4 | 0.8013 |
PTEs§ |
§PTEs: potentially toxic elements were defined to be aluminium, antimony, arsenic, barium, cadmium, lead, silver, and uranium.
†Essential elements were defined to be boron, calcium, lithium, magnesium, phosphorus, potassium, selenium, sodium, strontium, sulphur, vanadium, and zinc.
‡Array components were defined to be chromium, cobalt, copper, iron, manganese, molybdenum, nickel, and silicon.
Bold indicates a statistically significant difference,
The concentration of essential elements (98.9%) vastly outweighs that of PTEs (<1%) in the tap water prior to the footbath. Although present in very low quantities, Al had the highest concentration of all of the PTEs present in baseline tap water. Statistically significant differences were found in Diff-FBS for both array components (
We also compared the change in element concentrations (Diff-FBS in tap water with feet versus Diff-FBS in tap water without feet, Table
To assess leeching as a factor in the change of concentration of elements, we plotted the total element concentration in
Post-footbath session: total concentration of all elements in order of session occurrence.
Comparison of mean total PTEs§ (
Four samples were obtained from the participants: at baseline (Week 0), during the second (Week 2) and fourth (Week 4) footbath sessions, and Week 12 (Figure
Total PTEs§ excreted in urine for each participant. §Total potentially toxic elements (PTEs) were defined to include aluminium, antimony, arsenic, barium, beryllium, cadmium, mercury, lead, and uranium.
Hair samples were taken at baseline and at Week 12 of the study. PTEs analyzed included Hg, Pb, Al, Cd, Sb, As, Ba, Be, and U. The difference (
Change in total PTE§ (
We found that the IonCleanse SOLO device did not induce the elimination of PTEs through the feet of study participants. There is no evidence that the device stimulates pathways of PTE elimination through either the kidneys, via urine, or through the hair after receiving four 30-minute footbath sessions given weekly.
The manufacturers of the IonCleanse device claim that their product’s effectiveness lies in its ability to generate positively and negatively charged ions (H+, OH−) via electrolysis in water. Purportedly, these ions cause the neutralization and subsequent removal of charged particles from the body via osmosis and diffusion through the skin that is in contact with the ion gradient created in the water. While much attention in the claim is given to the impact this gradient may have on a person whose feet are immersed in this water, little is given towards the impact this gradient may have on the array itself.
Stainless steel is a composite of different elements with Fe as the basic element. The composition of the steel varies, with 316 grade having a higher amount of chromium in order to provide increased resistance to corrosion [
Corrosion can be defined as “deterioration of a material due to interaction with its environment. It is the process in which metallic atoms leave the metal or form compounds in the presence of water and gases” [
Summary of differences between element concentrations after footbath runs with feet and without feet.
Elements ( | Post-FBS–Pre-FBS no feet | Post-FBS–Pre-FBS with feet | |
Mean ± Std dev | Mean ± Std dev | ||
Aluminum§ | 14.17 | 5.00 | 0.487 |
Antimony§ | 1.00 | 1.21 | 0.8859 |
Arsenic§ | |||
Barium§ | 5.00 | 6.04 | 0.911 |
Boron† | 3.33 | 4.04 | 0.814 |
Cadmium§ | 5.50 | 8.04 | 0.064 |
Calcium† | |||
Chromium‡ | |||
Cobalt‡ | |||
Copper‡ | 253.33 | 456.71 | 0.162 |
Iron‡ | |||
Lead§ | 0.33 | 0.00 | 0.909 |
Lithium† | 1.17 | 0.25 | 0.994 |
Magnesium† | |||
Manganese‡ | |||
Molybdenum‡ | |||
Nickel‡ | |||
Phosphorus† | 37.33 | 44.29 | 0.502 |
Potassium† | |||
Selenium† | |||
Silicon‡ | |||
Silver§ | 0.00 | 0.00 | |
Sodium† | |||
Strontium† | |||
Sulfur† | −628.33 ± 1,253.99 | −496.79 ± 2,448.86 | 0.490 |
Uranium§ | 0.00 | 0.04 | 0.731 |
Vanadium† | |||
Zinc† | 16.67 | 16.63 | 0.956 |
Total | 142,837.17 | 158,783.82 | 0.2962 |
Array components‡ | |||
Essential elements† | 20,265.83 | −2,212.53 | 0.1011 |
PTEs§ | 30.50 | 25.92 | 0.8697 |
§PTEs: potentially toxic elements were defined to be aluminium, antimony, arsenic, barium, cadmium, lead, silver, and uranium.
†Essential elements were defined to be boron, calcium, lithium, magnesium, phosphorus, potassium, selenium, sodium, strontium, sulphur, vanadium, and zinc.
‡Array components were defined to be chromium, cobalt, copper, iron, manganese, molybdenum, nickel, and silicon.
Bold indicates a statistically significant difference,
Composition of grade 316 stainless steel.
Element | Percentage composition |
---|---|
Chromium | 16–18% |
Nickel | 10–14% |
Molybdenum | 2-3% |
Manganese | 2% |
Silicon | 1% |
Carbon | 0.08% |
Phosphorus | 0.045% |
Sulfur | 0.03% |
[
One hypothesis whereby PTE elimination could be supported using the ionic footbath device is through stimulation of an alternate detoxification pathway through the kidneys. To test this hypothesis, 24-hour urine collections were obtained concurrent with the second and fourth footbath sessions. If the hypothesis was correct, increased elimination resulting in elevated urinary total PTEs in sessions two and four should have been evident over and above baseline. This was not found to be the case. While some variance between participants is evident, during the 4 weeks where participants were receiving footbaths there were no clinically relevant changes in the elimination of PTEs that cannot be differentiated from normal fluctuations in excretion via urinary pathways. It is unclear why results for Participant-1 appeared as an outlier to the general trend in the other participants. Given these results, exposure to four sessions of ionic footbath did not appear to have any substantive influence over the body’s ability to eliminate PTEs through the urine.
Hair is a stable medium that records which elements are circulating in the blood, and there is evidence that toxic elements in hair are representative of toxic element levels in the internal organs [
In this trial, we tested the application of the IonCleanse SOLO ionic footbath across the lifespan of an array amongst six individuals. Each participant was exposed to four footbath sessions. It is conceivable that a larger number of sessions are required to see an overall detoxification effect in the individual; however, the lack of observable changes in PTEs in the water that might be attributed to a person seems unlikely. If there was any resistance to effect from a single exposure this was accounted for with multiple exposures over the course of one month.
In addition to testing for possible stimulation of physiological detoxification pathways, we also analyzed pre- and postexposure samples for both urine and hair in each participant. By testing and comparing three possible routes of elimination (feet, urine, and hair) we went beyond the implied claims of direct elimination through the feet by exploring other possible routes of elimination. Budgetary constraints precluded us from examining elimination through the colon as stool. It is possible that detoxification through the liver and bile could have been augmented with exposure. However, as both urinary excretion and HMA did not uncover any significant changes in these routes of elimination over the course of treatment and due to a lack of biological rationale it is unlikely that a liver specific elimination would be stimulated either.
The outcome of primary importance in this study, toxic element concentrations, depends on accurate measurements with low intertest variability. A strength of this study was the quality analysis performed by an independent laboratory following good laboratory practices with expertise in water, urine, and hair mineral analysis. The laboratory was blinded to the source of the water being tested and to the protocol from which sequential participant urine and hair samples were taken.
This was a proof-of-principle study with a small sample size. The small sample size would not permit us to identify small shifts in the elimination of PTEs through the utilization of the ionic footbath device. It is possible that a larger study may be able to identify clinical significant differences. Further, we tested healthy participants (self-defined and suffering from no major diseases), and it is conceivable that, in people with high levels of toxicity, application of the ionic footbath could have led to increased elimination either directly or indirectly.
We did not perform materials testing on all of the components of the ionic footbath device. As such, we were not able to confirm other potential sources of PTEs that might be contributing to the changes in toxic elements observed between Pre-FBS and Post-FBS without feet. We hypothesized that the elements found in the residual water could come from the array, salt, plastic storage container, or the plastic liner of the foot tub.
In this proof-of-principle study we found no evidence to suggest that ionic footbaths help promote the elimination of toxic elements from the body through the feet, urine, or hair. While unlikely to cause harm or result in any increased uptake, the use of ionic footbaths may release minute quantities of PTEs into the aqueous environment.
The authors are grateful for the support that they received for this study. This research was supported by a grant from the Canadian CAM Research Fund (CCRF), a partnership of the Holistic Health Research Foundation of Canada and IN-CAM. They thank all of the study participants for their time and dedication to this project. D.A. Kennedy is supported by a career development grant from Sickkids Foundation. A Major Difference Inc. provided the use of an IonCleanse SOLO device and all related supplies for this study. A Major Difference Inc. had no other involvement in the project. CanAlt Health Laboratory Inc. provided the water and urine analysis at a reduced cost, enabling the authors to increase the number of participants in the study. The Robert Schad Naturopathic Clinic of the Canadian College of Naturopathic Medicine provided the facilities free of charge for the study.