Keywords
cytokines - specific nucleic acids - low dose medicine - signaling molecules
Introduction
Signaling molecules such as cytokines and interleukins are key mediators for the immune
response in responding to internal or external stimuli. In biology, information in
molecular structures—the chemical properties of molecules that enable them to recognize
and bind to one another—is central to the function of all processes. Signaling molecules
are essential for the cross-talk between the psychological, neurological, endocrinological
and immunological systems that form the psycho-neuro-endocrino-immunological network.
This network is responsible for maintaining homeostasis, and correspondingly, a loss
in the homeostatic equilibrium of signaling molecules can lead to the onset of various
pathologies, including inflammatory, allergic and autoimmune diseases. This fits well
into an emerging systemic view of life, which considers the presence of several interconnected
features such as response to stress via hormetic regulation, maintenance of homeostasis
and spatial compartmentalization to be the key hallmarks of human health.[1]
A core principle of homeopathy is the stimulation of self-regulation in diseased individuals
via the administration of homeopathically prepared medicinal products based on the
Principle of Similars. Consistent with the latter principle, the same substance can
have inverse effects depending on the dose. Historically, this effect is referred
to as the Arndt-Schultz principle;[2] in modern times this phenomenon, also referred to as hormesis, was extensively investigated
by Prof. Edward Calabrese, who acknowledged that there is a relation between hormesis
and homeopathy.[3] This type of adaptive response is often characterized by an inverse J-shaped dose–response curve (a low dose stimulates; a higher dose inhibits). Application
of homeopathically prepared substances with the aim to stimulate an adaptive response
(recovery) after an organism has lost its homeostatic equilibrium is also referred
to as “postconditioning hormesis”.[4] This biphasic dose–response is also observed in the functioning of many signaling
molecules and can, for instance, explain the mixed agonist/antagonist action of various
cytokines.[5]
[6]
All homeopathic medicinal products have undergone a process known as potentization,
which involves stepwise serial dilution alternating with kinetic agitation (e.g.,
vigorous shaking with impact, also referred to as succussion, serial kinetic activation,
etc.). Potentization of substances (involving kinetic agitation during each dilution
step) is one of the core characteristics of homeopathically prepared medicinal products.
Potentized signaling molecules have been in use for some time now and are available
on the market as medicinal products in several countries. Whilst homeopathically prepared,
no classical proving data are available. The latter situation is also applicable to
many isopathic substances, but this is not a major problem because the conceptual
relation between, e.g., the use of homeopathically prepared pollen and the indication
hay fever is clear. Various trials on isopathic approaches have further publicized
such approaches,[7] and subsequently these trials have been included in systematic reviews of homeopathy.
This is currently less clear for the use of homeopathically prepared signaling molecules.
On one hand, such products are defined by the WHO as homeopathic medicinal products
if prepared in accordance with one of the recognized homeopathic pharmacopoeias.[8] On the other hand, there is a need to further clarify and communicate the relationship
between the use of these products and homeopathy as a therapeutic system. The latter
will also contribute toward further clarity on the regulatory status of such novel
products in several countries, and thereby ensure or enhance market access.
There is currently a lack of awareness and understanding in the homeopathy community
about the use and therapeutic position of potentized signaling molecules. To date,
both clinical and pre-clinical studies on such products have been excluded from reviews,
and therefore relatively little is known about the nature and extent of the available
data.
Hahnemann developed homeopathy principally as a phenomenological medicinal system.
This took place against the background of his justified criticism against mainstream
medicine at the time, which was primarily based on the flawed theory of humoral pathology.
Hahnemann was, however, firmly dedicated to aligning homeopathy with the natural sciences,
but this connection has been weakened during the accelerating pace of scientific discoveries
in the 20th and 21st century. In our opinion, it is important for both the recognition
and further development of homeopathy that these connections are strengthened.
Signaling molecules are interesting substances because of their pivotal role in the
biology of both health and disease. Moreover, these types of substances have been
used therapeutically in homeopathy for approximately 50 years. There is a need to
further map the available scientific data on these products, with a view to informing
more formalized subsequent reviews. There is also a need to further clarify and discuss
the homeopathic character and status of such products in the homeopathy community.
This will also contribute to addressing the current regulatory policy gap with regard
to such products. The aim of this scoping review is to map the available pre-clinical
and clinical data on homeopathically prepared signaling molecules and to address the
question of their position within the epistemological framework of homeopathy.
Methods
We conducted a scoping review of clinical and pre-clinical studies of homeopathically
prepared signaling molecules that are used therapeutically. “Homeopathically prepared”
was defined as being manufactured in accordance with one of the officially recognized
homeopathic pharmacopoeias. Signaling molecules were defined as any molecule involved
in endocrine, paracrine, autocrine, intracrine, and/or direct signaling. Antibodies
were included within this broad definition, because of their involvement in the activation
of the complement system via binding sites on the tail of their Y-shaped form. Nucleic acids such as DNA and RNA were included as well, because in
addition to their main functions of creating, encoding and storing biological information
in cells, they also serve to transmit and express that information inside and outside
the nucleus.
Articles in peer-reviewed journals, reporting original clinical or pre-clinical research
of therapeutically used homeopathically prepared signaling molecules, such as interleukins,
cytokines, antibodies, growth factors, histamine, neuropeptides and hormones, were
eligible. Experimental as well as observational designs, including clinical case reports,
were permitted. Since this was a first exploration of the available literature, we
decided on a post hoc basis to accept studies on combination products containing signaling molecules plus
other homeopathic medicines, and also veterinary studies. English language papers
were eligible, as well as non-English language papers of which we were able to obtain
an English translation. No restrictions on the year of publication were applied.
The following types of papers were excluded: review articles or opinion pieces not
reporting original research; second, similar, publications on the same original study;
papers reporting on homeopathically prepared plant hormones in plant-based experimental
studies.
Potentially relevant publications were identified by approaching the known manufacturers
of homeopathically prepared signaling molecules, and by studying the reference lists
of the provided publications. The Scopus abstract and citation database of peer-reviewed
literature was used for electronically searching the published literature. While hormesis
may help to explain some of the effects observed in association with the low doses
used in homeopathy, hormesis does not entail potentization as a specific process for
homeopathic medicinal products. So, while “low dose” related terms were used as part
of the search strategy to identify potentially eligible papers, only papers involving
homeopathically prepared substances were included in this review.
The following search terms were used: low dose, low-dose medicine, low-dose cytokine,
low-dose multi-component medication, sequential kinetic activation, SKA, ultra-low
dose, ultralow dose, adrenaline/Adrenalinum, Citomix, GUNA-Interleukin, GUNA-FGF, GUNA-Anti-IL, histamine/Histaminum, micro-immunotherapy, 2LARTH, 2LHERP, 2LPARK, 2LPAPI, 2LALERG, and antibody containing
preparations. The end date of the literature search was July 31st, 2020.
The following variables were collected for each of the identified studies: first author,
publication year, journal, study objective(s), type(s) of signaling molecules concerned,
research design, clinical domain/application, results, and main conclusions as reported
by the authors.
The categories of study designs were pre-defined as follows: randomized clinical trials
(double blind, parallel groups, placebo controlled; double blind, placebo controlled;
comparative clinical; double blind, placebo-controlled two-period crossover; double
blind, comparative; double blind, active-controlled; active-controlled); observational
studies (prospective case series; case series; prospective non-comparative cohort;
prospective comparative cohort; retrospective comparative cohort; retrospective non-comparative
cohort; matched pairs); and pre-clinical studies (in vitro, ex vivo; in vitro; in vivo).
An appraisal of all eligible studies took place by rating the direction of the findings
as reported in one of the following categories: clearly positive; tentatively positive;
unclear; tentatively negative; clearly negative. The quality of the papers was not
systematically assessed. The assessment of the direction of the evidence was based
on: (1) the conclusions as reported by the authors; (2) the consistency of the results;
and (3) the identification of methodological flaws. For instance, a lack of consistency
in the results (some test results are significant, while others are non-significant)
would lead to a downgrading of one category in the assessment of the direction of
the evidence. Also, the identification of significant or obvious methodological weaknesses
in the paper would lead to an assessment of “unclear”, even if the results were reported
as positive by the authors.
The papers were independently assessed by all four authors. Consensus on the assessment
of the direction of the evidence was reached on the basis of discussion if/as appropriate.
We did not deem it necessary to comprehensively chart the data. Nonetheless, to help
with visualizing the direction of outcomes, arrows of three different colors were
used. Upward facing vertical green arrows for clearly positive outcomes, upward angled
(45 degrees) yellow arrows for a tentatively positive direction of the results, a
horizontal orange arrow for an unclear direction of the outcomes, and a downward facing
red arrow for a tentatively or clearly negative direction of the outcomes. Reporting
of this paper follows the PRISMA extension guidelines for scoping reviews.[9]
Results
The screening process is summarized in [Fig. 1].
Fig. 1 Flow diagram. Selection process for eligible papers.
During pre-screening, 169 papers related to the Russian company Materia Medica Holding
were excluded on the grounds that these products were not manufactured in accordance
with one of the recognized pharmacopoeias. Nonetheless, their product range contains
serially diluted and kinetically agitated purified antibodies against a variety of
molecules such as IFN-γ, TNF-ɑ, prostate-specific antigen, endothelial NO synthase,
erythropoietin, S-100 protein, β-Unit insulin receptor, bradykinin, histamine, morphine,
and CD-4 co-receptor.
Eight of the remaining 36 studies were excluded,[10]
[11]
[12]
[13]
[14]
[15]
[16]
[17] leaving 17 publications related to GUNA products,[18]
[19]
[20]
[21]
[22]
[23]
[24]
[25]
[26]
[27]
[28]
[29]
[30]
[31]
[32]
[33]
[34] eight to LABO'LIFE products,[35]
[36]
[37]
[38]
[39]
[40]
[41]
[42] two to Boiron products[43]
[44] and one to a product manufactured by Laboratorios Medicor[45] as the principal basis for this scoping review.
Relevant data from the papers were extracted into two tables: one with the data on
the included studies ([Supplementary Table 1], available online only), and a second one with the excluded studies ([Supplementary Table 2], available online only).
The main data on the 28 included papers are summarized in [Table 1].
Table 1
Summary of main findings
|
1st Author, year
|
Journal
|
Type of signaling molecule(s)
|
Research design
|
Clinical domain/indication
|
Direction of outcome[a]
|
Comment
|
|
Barygina et al 2015[18]
|
Journal of Dermatological Science
|
IL-10, IL-4, bFGF and β-endorphin
|
Pre-clinical
|
Dermatology: vitiligo
|
|
Preliminary findings suggesting that the four investigated signaling molecules may
be useful in the treatment of vitiligo.
|
|
Barygina et al 2016[19]
|
Journal of Dermatological Science
|
IL-10, IL-4, bFGF and β-endorphin
|
Pre-clinical
|
Dermatology: psoriasis
|
|
Letter to the editor, reporting that some of the signaling molecules reduced oxidative
stress in lesional fibroblasts.
|
|
Cardani et al 2013[20]
|
Gastroenterology Research
|
IL-10 and anti-IL-1 antibody
|
Pre-clinical
|
Gastroenterology: colitis
|
|
An inflammation modulating effect was observed via a variety of measurements. Consistency
between the different outcome measures adds some confidence to the finding that these
molecules may be useful in the treatment of inflammatory bowel disease.
|
|
Carello et al 2017[21]
|
Italian Journal of Pediatrics
|
IL-12
Interferon-γ and
Galium Heel
|
Clinical, experimental
|
Dermatology: eczema
|
|
Whilst some preliminary positive results are reported, the signaling molecules were
used in conjunction with another product, preventing the (exclusive) attribution of
effects to the signaling molecules.
|
|
D'Amico et al 2012[22]
|
Journal of Cancer Therapy
|
IL-12
|
Pre-clinical
|
Oncology: non-small cell lung CA
|
|
Low dose IL-12 modulated some of the T-cell populations in a positive direction, but
not all of the changes were superior to the control group.
|
|
Fiorito et al 2016[23]
|
Comparative Immunology, Microbiology and Infectious Diseases
|
IL-12, IFN-γ
|
Clinical, experimental
|
Veterinary medicine; (feline) herpes virus infections
|
|
Randomized, blinded placebo-controlled pilot trial. After 1 year of treatment, the
PCR viral assay became negative in 80% of cats on active treatment compared with none
of the cats on placebo. Clinical signs also improved more in the active group as compared
with placebo.
|
|
Floris et al 2018[35]
|
Journal of Inflammation Research
|
IL-1β, IL-2, TNF-α, SNA
|
Pre-clinical
|
Rheumatology; reducing chronic inflammation
|
|
The preparation reduced the expression of some pro-inflammatory mediators extracted
from monocytes of healthy volunteers. The contribution of the SNAs is not clearly
discussed/explained.
|
|
Floris et al 2020[36]
|
Dose–Response
|
IL-1, IL-4, IL-5, IL-6, IL-10, IL-12, IL-13, TNF- α, TGF-β, Histaminum, SNA-HLA-2
|
Pre-clinical
|
Respiratory medicine; allergies
|
|
Some evidence suggesting effects on IgE-mediated inflammation; not all doses and effects
were statistically significant.
|
|
Floris et al 2020[37]
|
International Journal of Rheumatology
|
IL-1β, TNF-α, IL-2, SNAs targeting HLA class I, class II, and Human IL-2
|
Pre-clinical
|
Rheumatology; rheumatoid arthritis
|
|
The preparation reduced the clinical, serological, and histological markers of inflammation
in mice. Highly diluted IL-2 as well as SNAs targeting IL-2 appears to successfully
downregulate IL-2.
|
|
Floris et al 2018[38]
|
Journal of Biological Regulators and Homeostatic Agents
|
RANTES chemotactic cytokine
|
Clinical, observational
|
Dentistry; maxillary surgery
|
|
Comparative observational study, suggesting that RANTES C27 can downregulate RANTES
levels in immuno-compromised patients undergoing maxillary surgery, with sufficiently
high levels of RANTES at baseline. The small, heterogeneous group of patients included
in this observational study make these findings very preliminary.
|
|
Gariboldi et al 2009[24]
|
Pulmonary Pharmacology and Therapeutics
|
IL-12, IFN-γ
|
Pre-clinical
|
Respiratory medicine; allergies
|
|
Low dose IL-12 and IFN–γ reduced bronchial hyper-responsiveness in mice, as further
confirmed by histological and IgE analyses. Succussion increased the activity of the
preparation, providing support for the importance of the potentization process.
|
|
Jenaer et al 2000[39]
|
British Homeopathic Journal
|
DNA, RNA, two types of SNAs
|
Clinical, observational
|
Gynecology; genital herpes
|
|
Observational study in patients, suggesting that the homeopathic product prevented
or reduced attacks in patients with chronic recurring genital herpes. The nature of
the SNAs used is not described. Further RCTs are necessary.
|
|
Lilli et al 2019[40]
|
Degenerative Neurological and Neuromuscular Disease
|
SNA-s and non-defined immune mediators
|
Pre-clinical
|
Neurology; Parkinson's disease
|
|
Findings suggesting that the product can reduce oxidative stress in an in vitro model.
Ingredients of the product are not described, making it impossible to further assess
the potential mechanism of action.
|
|
Lotti et al 2015[25]
|
Journal of Biological Regulators and Homeostatic Agents
|
FGF, IL-4, IL-10, anti-IL-1
|
Clinical, observational
|
Dermatology; vitiligo
|
|
Results suggesting that the product can augment the effects of phototherapy in patients
with vitiligo.
Retrospective observational design and low patient numbers make these data preliminary.
|
|
Mancini et al 2018[26]
|
International Immunopharmacology
|
Progesterone, IL-10
|
Pre-clinical
|
Gynecology; endometriosis
|
|
Promising effects of low dose progesterone and IL-10 alone and in combination on multiple
endometrial cell-lines, suggesting added value of the combination.
|
|
Martin-Martin et al 2017[27]
|
Drug Design, Development and Therapy
|
IL-4, IL-10, anti-IL-1 antibodies
|
Clinical, experimental
|
Rheumatology; rheumatoid arthritis
|
|
Randomized, open-label trial in rheumatoid arthritis patients suggesting that the
homeopathic products can help maintain low levels of disease activity. Further trials
with larger numbers of patients and longer follow-up are warranted.
|
|
Naidoo and Pellow 2013[43]
|
Homeopathy
|
Histaminum and
cat saliva
|
Clinical, experimental
|
Dermatology; allergy
|
|
Randomized placebo-controlled trial in subjects with cat allergy, with positive results.
Histaminum was used in conjunction with another product, preventing the (exclusive)
attribution of effects to histaminum.
|
|
Poitevin et al 1988[44]
|
British Journal of Clinical Pharmacology
|
Lung histamine and Apis mellifica
|
Pre-clinical
|
Respiratory medicine/dermatology; allergy
|
|
In vitro study, demonstrating inhibition of anti-igE-induced degranulation of basophils. These
effects were only observed at particular potency levels.
|
|
Radice et al 2015[28]
|
Translational Oncology
|
IL-4, IL-12
|
Pre-clinical
|
Oncology; colon carcinoma
|
|
In this in vitro, ex vivo study, enhanced production of IL-12 and Th1 polarization was seen in cells from normal
donors and early carcinoma rather than from advanced stages.
Low numbers of donors make these results preliminary.
|
|
Radice et al 2014[29]
|
International Immunopharmacology
|
IFN-γ
|
Pre-clinical
|
Oncology; colorectal cancer
|
|
SKA IFN-γ treatment was found effective but less compared with r-IFN- γ in increasing
NK cell activity, and only in cells from non-metastatic cases.
|
|
Roberti et al 2014[30]
|
Journal of Biological Regulators and Homeostatic Agents
|
IL-4, IL-10, IL-11
|
Clinical, experimental
|
Dermatology; psoriasis
|
|
This crossover trial reports “within-group” analyses only, and there is no indication
in the data that the effect was superior to placebo.
Apart from methodological concerns, the low number of recruited patients does not
permit reliable conclusions with regard to the safety of the product.
|
|
Ruiz-Vega et al 2005[45]
|
Homeopathy
|
Histamine
|
Pre-clinical
|
Neurology; sleep
|
|
This in vivo study reports significant effects of histamine 30C compared with control on sleep
patterns as measured via EEG. Whilst demonstrating biological effects, the clinical
relevance of these findings is not entirely clear.
|
|
Tagliacarne et al 2018[31]
|
Immunology Letters
|
G-CSF, IFN-γ, IL-1β, IL-2, IL-4, IL-6 plus 6 other homeopathic ingredients
|
Pre-clinical
|
ENT medicine; cells recovered from adenoidectomies or adeno-tonsillectomies
|
|
The product modulated a broad range of immune cells involved in the early immune response
against respiratory infections.
Inclusion of six other homeopathic ingredients prevents the attribution of the treatment
effects to the signaling molecules.
|
|
Tessaro et al 2017[32]
|
Journal of Reproductive Infertility
|
Progesterone, IL-10
|
Pre-clinical
|
Gynecology; polycystic ovary syndrome
|
|
Consistent positive effects on multiple outcome parameters, i.e. hormonal analyses,
morphological evaluation of ovaries and immunohistochemistry, suggest a possible role
in the treatment of PCOS.
|
|
Tessaro et al 2015[33]
|
Journal of Ovarian Research
|
Recombinant human FSH (rh-FSH)
|
Pre-clinical
|
Gynecology; polycystic ovary syndrome
|
|
The findings suggest that SKA FSH could attenuate some of the characteristic of PCOS
in the mouse model. However, the effects did not mimic the effects of rhFSH, i.e.,
the oocyte maturation rate.
|
|
Thomas et al 2016[41]
|
Advances in Infectious Diseases
|
IL-1, IL-2, IFN-α, RNA, and two types of SNAs
|
Clinical, observational
|
Oncology; cervical cancer
|
|
The overall results show a clear reduction of HR-HPV infection in the treated patients,
without reaching statistical significance.
Comparative observational study with low patient numbers warranting the conduct of
confirmatory RCT.
|
|
Uberti et al 2017[34]
|
Cells, Tissues, Organs
|
Acetylcholine
|
Pre-clinical
|
Dermatology; burn injuries, chronic ulcers, etc.
|
|
SKA ACh positively influenced keratinocyte functions such as cell viability, proliferation
and migration, for better wound healing. Non-kinetically activated low dose ACh did
not have the same effects.
|
|
Van der Brempt et al 2011[42]
|
Revue Française D'Allergogie
|
IL-1, IL-4, IL-5, IL-6, IL-10, IL-12, IL-13, TNF- α, TGF-β, Histaminum, SNA-HLA-2
|
Clinical, experimental
|
ENT medicine; allergic rhinitis
|
|
In this placebo-controlled pilot trial, the primary outcome measure (rhinitis symptom
score) did not reach statistical significance compared with placebo. Rescue medication
use, as well as a combined score, was statistically significantly less in the active
group compared with placebo.
|
Abbreviations: ACh, acetylcholine; b-FGF, basic fibroblasts growth factor; g-CCF,
granulocyte-colony stimulating factor; IL, interleukin; IFN-γ, interferon gamma; NK-cells,
natural killer cells; RANTES, Regulated on-Activation, Normal T-cell Expressed and
Secreted; rIFN-γ, recombinant interferon-gamma; SNA, specific nucleic acids (very
short single strands of DNA molecules); SKA, serial kinetic activation; SNA-HLA-2,
SNAs targeting human leucocyte antigen type II; TGF-β, tumor growth factor β; TNF-α,
tumor necrosis factor α; PCOS, polycystic ovary syndrome; ENT, ear, nose & throat.
a Key to the directions of outcome: 
= clearly positive; 
= tentatively positive; 
= uncertain; 
= tentatively negative; 
= clearly negative.
A wide range of signaling molecules are utilized in the products, as well as normal
T-cell expressed specific nucleic acids consisting of very short single strands of
DNA molecules. A clear majority of products (21 of 28) are derived from a combination
of two or more signaling molecules.
Seventeen papers reported pre-clinical studies, and 11 reported clinical studies (six
experimental, five observational). The direction of outcome is positive in the great
majority of the papers, and the results are unclear in only two of the papers. Sixteen
of the studies report a tentatively positive outcome, which was most commonly due
to the inclusion of relatively few subjects in the clinical studies, positive but
equivocal findings, non-significance of some of the outcome assessments, etc.
The clinical indications studied are given in [Table 2], showing that the most commonly studied have been psoriasis, vitiligo, rheumatoid
arthritis, respiratory allergies, polycystic ovary syndrome, and herpes.
Table 2
Clinical indications of the studies
|
Clinical indication
|
N studies
|
|
Respiratory allergies
|
4
|
|
Rheumatoid arthritis
|
3
|
|
Polycystic ovary syndrome
|
2
|
|
Psoriasis
|
2
|
|
Vitiligo
|
2
|
|
Cat allergy
|
1
|
|
Cervical cancer
|
1
|
|
Colitis
|
1
|
|
Colon carcinoma
|
1
|
|
Colorectal cancer
|
1
|
|
Eczema
|
1
|
|
Endometriosis
|
1
|
|
Feline herpes virus infections
|
1
|
|
Genital herpes
|
1
|
|
Maxillary surgery
|
1
|
|
Non-small cell lung cancer
|
1
|
|
Parkinson's disease
|
1
|
|
Sleep disturbance
|
1
|
|
Tonsillitis/adenoiditis
|
1
|
|
Wounds
|
1
|
Discussion
This scoping review found that there is a significant and growing body of evidence
on the use of homeopathically prepared signaling molecules. The majority of the data
involves pre-clinical research and only a minority involves clinical trials. Overall,
the pre-clinical data are varied, and generally promising. A few of the clearly positive
pre-clinical studies were published in high impact factor journals. Whilst the observational
studies are promising, and the majority of clinical trials have tentatively positive
results, further trials are needed, including high quality confirmatory clinical trials.
Homeopathically prepared signaling molecules are used in a wide variety of clinical
domains, with dermatology being the most advanced in terms of the accumulation of
both pre-clinical and clinical studies.
The main strength of this review is that for the first time the studies on these types
of products are summarized and brought to the attention of the homeopathy community
via publication in a peer-reviewed homeopathy journal.
A limitation inherent to a scoping review is that the quality of the papers is not
systematically assessed. A further limitation is that we may have missed articles
only held in databases other than Scopus, such as for instance the Web of Science.
However, Scopus is considered to be comprehensive in the domain of health-related
topics, so we do not expect that we have missed a significant number of articles.
Another weakness is that grading the direction of the evidence (as reported in [Table 1]), based on independent review by four assessors followed by consensus discussion
if appropriate, is a non-validated method. Despite this, we did feel it provided some
added value to the results and conclusions as reported by the papers' authors ([Supplementary Table 1], available online only), especially because one of the main purposes of a scoping
review is to provide the reader with a first orientation regarding the available data.
The high volume of studies related to Materia Medica Holding products came as a surprise
to us. One of the reasons for this was that these products have not always been positioned
on the market as “homeopathic medicinal products”. From a regulatory point of view,
this is strictly speaking correct, because only products that are manufactured in
accordance with a recognized homeopathic pharmacopoeia are recognized as homeopathic
medicinal products.[46] However, from a practical point of view, these products have undergone a potentization
process involving serial dilution alternating with kinetic agitation (referred to
as release-activation), very similar to preparation in accordance with the German
Homeopathic Pharmacopoeia (personal communication). Despite debate over the homeopathic
nature of these products,[47] most third parties point to a variety of arguments which support the notion that
these products are homeopathic.[48] Some of these publications[49]
[50]
[51] have even been retracted after the editors realized that the products investigated
were homeopathic, in some cases even explicitly stating its homeopathic nature as
the principal reason for the retraction.[52]
[53]
[54] Whilst these papers therefore did not meet the inclusion criteria for this scoping
review, we recognize as limitation that a significant number of relevant papers were
not included. This gap should be addressed in a complementary scoping review.
The majority of the published material reported positive, or tentatively positive,
results and all of the identified research was funded by the manufacturing companies
concerned. Little or no research has been conducted to date by independent research
groups without links to funding by the industries concerned. Publication bias can
therefore not be excluded. We conducted a limited search on clinicaltrials.gov to
see if we could identify any completed clinical trials (using the same search terms
as described in the Methods section) that were not subsequently published. This search
yielded one trial of 2LALERG in seasonal allergic rhinitis that was completed in 2016[55] and that did not demonstrate superiority to placebo. Due to problems with the design
and execution of this trial, its authors decided not to publish it (personal communication).
In all scenarios, further confirmatory studies are needed.
Whilst the identified studies related to the therapeutic effectiveness of histamine
were limited/inconclusive, it is worth mentioning that high dilution research on the
effects of histamine on basophil degranulation is one of the best-established basic
research models, and after more than 20 years of work on these models, the biological
effects of 15–17cH potencies of histamine have been confirmed,[56]
[57] and reproduced in large multi-center studies.[58]
[59]
The volume of the identified studies, and the response to some publications on these
types of products in the scientific literature, clearly confirm the need to address
the position of these products within homeopathy.
There is a need to formally assess the quality of the identified studies, using established
criteria. Some further work may need to be done on the model validity of this category
of papers from a homeopathy perspective.[60] Further discussion would be needed in particular on how to assess the judgmental
domains “Rationale for the choice of the particular homeopathic medicine” and “The
extent to which homeopathic principles are reflected in the intervention”.
We are of the opinion that these types of products potentially serve a bridge function
between homeopathy and the natural sciences. Whilst many questions remain, it is clear
that the homeopathic method of preparation is essential for releasing the “bioregulatory”
action of these products. It is as yet unclear whether this is due to some sort of
primary action of the homeopathically prepared substances and/or whether the homeopathic
medicine acts as a catalyst for various biological processes. We feel that the group
of signaling molecules is of particular interest in this regard because the scientific
understanding of the actions of these molecules is still expanding rapidly, and this
can provide a useful platform for linking homeopathic principles to modern pharmacology
and biology. The ground is potentially fertile for this, because the use of these
signaling molecules in higher doses based on a conventional pharmacological approach
has largely failed, as illustrated for instance by attempts to use IFN-γ.[61]
[62] Further discussion on what makes this new class of products homeopathic is urgently
needed. The mere fact that these products have not undergone a classical Hahnemannian
proving is, in our opinion, insufficient as an argument to dismiss this class of products
as non-homeopathic. Interestingly, it is well documented that cytokines in higher
than physiological concentrations are actually pathogenetic.[63] Physiological as well as pathogenetic effects of these molecules may also provide
some hints regarding their possible homeopathic uses. To our knowledge, the latter
aspect has not been sufficiently explored. We also think that the time is right to
move from a purely phenomenological approach to a more modern one that involves phenomenology
as well as pathophysiological reasoning. Hahnemann himself tried to do something similar
when endeavoring to integrate the dominant (now obsolete) miasma theory into the therapeutic
framework of homeopathy.
It is conceivable that it will be possible to at least partly connect the therapeutic
effects of homeopathically prepared signaling molecules to the emerging field of low-dose
medicine[64] and stimulation of hormetic regulation. On the other hand, experts in the field
have pointed out that the observation of hormetic effects in itself does not constitute
any sort of explanatory theory for the effects of homeopathic medicines.[2]
[3] It is therefore important also to acknowledge the distinctions between homeopathy
and hormesis. A detailed discussion on this topic is outside the scope of this article.
Additionally, modern approaches have been proposed,[65] which link the science of molecular networks with patients' autoregulatory capacity.
Signaling molecules are pivotal elements in these molecular networks. This could therefore
provide a modern framework for the stimulation of self-regulation that is aimed for
in homeopathy. Further interactions with molecular biologists, immunologists and pharmacologists
will be needed to advance this process.
As borne out by 200 years of homeopathy history, biological materials provide a key
source for homeopathic medicinal products. Signaling molecules are amongst the most
information dense molecules from a biological perspective. For instance, it has been
demonstrated that IL-6 signaling requires only a few IL-6 molecules.[64] Therefore, from a homeopathy perspective, it is quite conceivable that these types
of substances have therapeutic potential. Further steps to explore this potential
are warranted.
Highlights
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Signaling molecules are pivotal elements in the body's self-regulating molecular networks.
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Homeopathically prepared signaling molecules have been used therapeutically for approximately
five decades, though this fact is not well known.
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This scoping review systematically identified the available clinical and pre-clinical
data for the first time.
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A surprising volume of promising data was identified.
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Further steps to explore the therapeutic use of homeopathically prepared signaling
molecules are warranted.
