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A clinical approach to the thyrotropic axis
Chapter 10
A clinical approach to the thyrotropic axis Introduction The thyrotropic axis is the second of the two catabolic axes. Recall that its purpose is to manage adaptation and growth. Because of the diversity of these demands and the evolutionary history that resulted in this axis (The Theory of Endobiogeny, Volume 1, Chapter 8), the function of each hormone and emunctory within the axis goes far beyond vertical hypothalamic-pituitary-thyroid regulation. Understanding the similarity and divergence of the arrangement and function of the two catabolic axes helps the clinician identity areas of oversolicitation, imbalance, and regulation (Table 10.1). For example, if the corticotropic axis one notes a low adrenocorticotropin hormone (ACTH) index and elevated cortisol, and, in the thyrotropic axis elevated thyroid relaunching and thyroid index, the origin of both will be related to alpha-sympathetic activity. Using a sympatholytic such as Lavandula angustafolia (lavender) essential oil or Passiflora incarnata (passionflower) may be sufficient to regulate both axes. However,
if the thyrotropic axis has multiple indexes elevated and the corticotropic axis is not deranged to a similar degree, treatment should focus primarily and alpha-sympatholytic and thyrotropic plants that inhibit central activity. For example, in addition to lavender and passionflower, one would be wise to use Lycopus europaeus (gypsywort) and Fabiana imbricata (pichi) to inhibit thyrotropin-releasing hormone (TRH) and thyroid-stimulating hormone (TSH) and peripheral thyroid activity.1, 2 The chief metabolite of the thyrotropic axis is lipids, its chief mineral calcium. When evaluating indexes of this axis, also evaluate the lipid panel and indexes related to passive cellular permeability within the somatotropic axis. With respect to calcium, evaluate the serum calcium level, the adaptogen index, parathyroid hormone index, etc. Unlike the corticotropic axis, the thyrotropic contains within itself the means to utilize or facilitate that which it has mobilized. Table 10.2 summarizes metabolites and the thyrotropic hormones implicated.
TABLE 10.1 A comparison of the two catabolic axes in first and second loops First loop
Corticotropic
Thyrotropic
Hypothalamic
CRH
TRH
Anterior pituitary
ACTH
TSH
End-organ hormone
Cortisol
Annexal organ(s)
Liver
Thymus Parathyroid: PTH
Second loop
Corticotropic
Thyrotropic
Hypothalamic
CRH
TRH
Anterior pituitary
ACTH
TSH
End-organ hormone
Aldosterone
T3
Annexal organs
Liver, lung, kidney: Angiotensin II, renin
Skin, liver, kidney: Vitamin D
Emunctories and implicated organs
Skin, kidney, liver, gallbladder digestive tract
Liver, gallbladder, digestive tract, exocrine pancreas, endocrine pancreas, lungs
DHEA
The Theory of Endobiogeny. https://doi.org/10.1016/B978-0-12-816908-7.00010-4 © 2019 Elsevier Inc. All rights reserved.
T4
Calcitonin
145
146 The Theory of Endobiogeny
TABLE 10.2 Mobilization and utilization of metabolites by the thyrotropic hormones Mobilization Metabolite
TRH
Glucose
•
Amino acids
•
T4
Utilization PTH/D3
•
Lipids
•
Calcium
•
TSH
T3
•
•
•
•
D3
Calcitonin
•
•
• •
•
D3, vitamin D3; PTH, parathyroid hormone.
Anatomy, pathophysiology The thyrotropic axis has a notable impact on the development of ectodermal tissues, especially the nervous system, the adrenal medulla (βΣ), and immunity. The pituitary gland is an ectodermal tissue and hence this axis regulates the very foundation of endocrine management of the periphery. The thyrotropic axis is permanently linked to structural formation, structural maintenance, and functional competency of adaptation. The thyrotropic axis gives birth to βΣ, and βΣ entrains and enlivens the thyrotropic axis in turn by sensibilizing tissues to T4 activity. Adaptation syndromes, spasmophilia, neurologic disorders, and disorders of hyper- and autoimmunity are all disorders that lay within the thyrotropic axis. With respect to diseases of adaptation and adaptability, both catabolic axes are directly relaunched by αΣ. Thus, both axes are directly linked to conscious, subconscious, and physiologic perceptions of and response to aggression (The Theory of Endobiogeny, Volume 1, Chapter 12). From the evolutionary perspective, the thyrotropic axis is also closely linked to the sympathetic branch of the autonomic nervous system (ANS) because dopamine, noradrenalin, adrenaline, T4, and T3 are all derived from the amino acid tyrosine. The role of TRH in all these activities cannot be underestimated. It directly or indirectly affects all four axes. In the corticotropic axis, it fixates cortisol to its receptors. In the gonadotropic axis, it stimulates follicle-stimulating hormone (FSH) and directly affects estrogen activity. Its thyrotropic function is the classic vertical activity and stimulation of conversion of T4 to T3. TRH has a privileged thyro-somatotropic relationship as the hypothalamic stimulator of prolactin (which also alters the impact of estrogens). In the somatotropic axis, it stimulates the release of glucagon from the endocrine pancreas with a reflexive
response by insulin. Recall its central actions as a neurohormone is related to circadian and seasonal adaptation, thought, and emotions. TRH is also a general neuromodulator. Ultimately, TRH assists in the integration of the interior and external worlds.
Clinical significance of the thyrotropic axis When evaluating the level of function of the thyrotropic axis, it is capital to understand two concepts from an endobiogenic perspective. First, a number of the symptoms attributed to hypo- and hyperfunctioning of thyroid hormones are due to central thyroid hormones (TRH, TSH), or the sensibilization of other neuroendocrine factors and not the peripheral hormones ipso facto. Second, most signs, symptoms, and disorders related to the thyrotropic axis are relative and qualitative in nature, not absolute or quantitative. Table 10.3 demonstrates the role of various aspects of the thyrotropic axis in hyperthyroidism. Table 10.4 demonstrates the various aspects of the aspect with respect to hypothyroidism.
Symptoms related to the thyrotropic axis Various symptoms can be related to the thyrotropic axis (Table 10.5).
Signs related to the thyrotropic axis There are a number of signs related to the thyrotropic axis. They can be divided into the following areas: temperament an internal mental life (Table 10.6), neurologic (Table 10.7), head, ears, eye, nose and throat (Table 10.8), thyroid and chest (Table 10.9), and miscellaneous areas (Table 10.10).
A clinical approach to the thyrotropic axis Chapter | 10 147
TABLE 10.3 Role of various aspects of the thyrotropic axis in hyperthyroidism Thyrotropic factor Factor
↑ TRH
↑ TSH, serum
Endocrine Symptom
Tremors Muscle wasting Insomnia
Exam
↑ Deep tendon reflex Eyelid flutter Clonus
Inflammation Hair loss Brain fog
↑ T4
↑ T3
Overproduced from overstimulation
Overproduction, overconversion
Heat intolerance (if insufficient conversion to T3)
Cold sensitivity
Skin temperature elevated ↑ Osteoclasty
Structural Types of hyperthyroidism Reactive
Hypercatabolic, reactive thyroid state: Asthma, spring arthritis
Fundamental
Low TSH relaunching; peripheral hyperthyroidism: hyperestrogenic (thus hyper T4), hyper beta, risk of breast cancer; psoriasis Treatment: Lycopus europaeus, Borago officinalis; if DHEA, ACTH implicated in the estrogenism: Fragaria vesca
TABLE 10.4 Role of various aspects of the thyrotropic axis in hypothyroidism Thyrotropic factor Factor
TRH insufficient
↑ TSH, serum
↑ T4
↑ T3
Endocrine
Insufficient conversion of T4 to T3
Insufficient production of T4
Anabolic predominance
Mitochondrial strain
Symptom
Repetitive dreams
Weight gain
Hair loss Thinning eyebrows Alteration in timbre of voice: low, weak, and/ or hoarse
Fatigability
Exam
Hyperestrogenism
Types of hypothyroidism Latent
Lymphocytosis; cardiac vegetations; tonsil hypertrophy; appendix hypertrophy
Entrained
Elevated TRH or PL or DA; If there is elevated GH → appeal to glucose with diminished effect of GH (from strong insulin response)
Reactive TSH compensation
Fat pad above ankles (like Kurdish pants); Cobble stoning of posterior pharynx Treatment: Avena sativa, Verbascum thapsus
TABLE 10.5 Symptoms related to the thyrotropic axis3 Category
Finding
Level
State
Brain
General mental fatigue
Thyroid
Insufficient or excessive
Dermatologic
Pruritis
Thyroid
Elevated
Psoriasis
T4
Elevated
General physical fatigue
Thyroid
Insufficient
Energy, lack of
Thyroid
Insufficient
Ear, nose, throat
Enlarged tonsils
Thyroid/TSH, serum
Insufficient/elevated
Genito-urinary
Reduction in the duration on menstruation
Thyroid
Excessive
Reduction in the volume of menstrual flow
Thyroid
Insufficient
PMS with great irritability
Thyroid
Increased
Menstrual flow heavy
Thyroid
Insufficient
Heat intolerance
T4
Hyperfunctioning
Cold sensitivity
T3
Hyperfunctioning
Constantly cold
Thyroid
Deficient in response
Weight loss despite a good appetite
Thyroid
Excessive
Weight gain
Thyroid
Insufficient, especially with elevated TSH serum and relative to global adrenal cortex activity
Insomnia with great agitation
TRH
Hyperfunctioning
Dreams animated, vivid
TRH
Hyperfunctioning
Dreams in black and white
TRH
Insufficient
Repetitive dreams
TRH
Augmented
Energy
Metabolic
Sleep
TABLE 10.6 Temperament and internal mental life3 Finding
Level
Activity
Comment
Great vivacity
Thyroid
Dynamically efficient
Goal oriented
TRH
Predominant
Relative to TSH. It indicates being flexible in conceiving various orders and methods of executing plans. It does not imply that the person has the capacity to execute, only that they can conceive of multiple ways of performing
Process-oriented
TSH
Predominant
Relative to TRH. It is a tendency to be less willing, or, less able to conceive of alternate ways of executing a series of actions that were planned in advance in a particular order
Soft, easily gives in
Thyroid
Insufficient, especially during adaptation
Evaluate for strong para, weak beta, weak TRH
Fearfulness
Thyroid
Insufficient
Correlate with hyper-TRH that attempts to relaunch peripheral thyroid activity
Anxiety and nervousness
TRH
Hyperfunctioning
Tendency; correlate with elevated central and peripheral alpha and elevated dopamine
Expansive creativity
TRH
Predominant
Relative to TSH, with complementary levels of central histamine serotonin and dopamine. This type of creativity arises seeing novel relationships through tangential association
Juxtapositional creativity
TSH
Predominant
Relative to TRH. This type of creativity arises from analytical thinking with juxtaposition of basic elements into novel relationships
Depressive tendency
Thyrotropic
Dysfunctional
Correlate with hyper-TRH if comorbidity of anxiety, with insufficient peripheral thyroid activity if flat affect or psychomotor retardation. TSH has variable effects
A clinical approach to the thyrotropic axis Chapter | 10 149
TABLE 10.7 Neurologic signs3 Part
Quality
Finding
Level
Activity
Comment
General
Startle response
Startles easily to the lightest touch or sound
TRH
Reactive
Correlate with strong beta expression
Eyelids
Flutter
Spontaneous at rest
TRH
Hyperfunctioning
Base line thought
Eyelids
Flutter
Spontaneous interacting
TRH
Hyperfunctioning
In adaptation
Glabellar tap
Postglabella tap movement
Eyelid rapid flutter
TRH
Reactive
Eye
Pupillary light reflex
Exaggerated constriction to light
TRH
Reactive
Clonus
Foot
Brisk, diffuse
TRH
Elevated
Via spinal column
Deep tendon reflex (DTR)
Tendons
Brisk, diffuse
TRH
Elevated
Via spinal column
Extremities
Arms, hands, legs
Tremors
TRH
Excessive
And dysregulated; correlate with dopamine and alpha
TABLE 10.8 Signs related to head, ears, eye, nose, and throat3 Part
Quality
Finding
Level
Activity
Comment
Body
Build
Sharp features
TSH
Predominant
Example: Sharp nose, high cheek bones, pointed chin, oval face, thin build
Voice
Quality
Weak and hoarse
Thyroid
Insufficient
T3 is generally more implicated than T4
Skin
Temperature and moisture
Cold and dry
Thyroid
Insufficient
Generalized to entire body
Nail
Thickness
Fine and breakable
Thyroid
Insufficient
Hair
Quality
Thick
Thyroid
Favorably adapted
Curly hair
TRH
Predominant
Fragile
Thyroid
Insufficient
Thin
Thyroid
Not predominant
Falls out easily
Thyroid
Insufficient
Alopecia
Thyroid
Insufficient
Or in autoimmune terrain
Arch
Convex
TRH
Predominant
Occurs when there is a strong GH and ACTH response
Pilosity
Fine
Thyroid
Strong
Thinning from hair loss at the ends
Thyroid
Diminished
Relative to historically adapted levels
Length
Long
Thyroid
Well functioning
Initiated by FSH
Curvature
Curled at ends
Thyroid
Insufficient to demand
Gonadotropic appeal to re-equilibrate thyroid to gonadotropic function
Eyebrow
Eyelashes
Structural role of TRH along with appeal to thyroid and GH; all three conditions must be present
In structural nourishment of hair
TABLE 10.8 Signs related to head, ears, eye, nose, and throat—cont’d Part
Quality
Finding
Level
Activity
Comment
Eye
Size
Large
TRH, alpha, central
Strong
More predominant in children and women with anxiety tendency
Small
Thyroid
Insufficient
Inability to readjust peripheral thyroid activity during fetal development
Tonsils
Size
Hypertrophy
Thyroid
Insufficient responsiveness to TSH
Reflects a latent thyroid insufficiency
Pharynx
Deformity
Cobble stoning
Thyroid
Insufficient responsiveness to TSH
Elevated TSH to compensate for latent thyroid insufficiency
TABLE 10.9 Signs related to the thyroid gland and chest3 Part
Quality
Finding
Level
Activity
Comment
Thyroid
Volume
Increased
Thyroid
Augmented
Consistency
Nodules
Thyroid
Oversolicited
Consistency
Goiter
Thyroid
Insufficient
Clavicle, bilateral
Proximal
Pain on palpation
Sternum
Orientation
Convex sternum
PTH
Elevated
Correlate with GH
Breasts
Asymmetry
Left > right
TSH
Predominant
Instructure, in response to the basic influence of LH on laterality
Heart
Rate
Heart rate rapid
Thyroid
Augmented
May be absolutely elevated or augmented by TRH and/or cortisol
Finding
Level
Activity
TSH demand greater than T4 response
Thyroid gland congestion from oversolicited
TABLE 10.10 Others signs by region3 Part
Quality
Comment
Anterior projection of organs represents the current anatomical congestion and/or state of dysfunction Colon
Transverse, distal, left
Pain on palpation
TSH
Strong
Oversolicitation of thyroid and splenic flexure for nutrient reuptake
Colon
Transverse, distal, right
Pain on palpation
TRH
Predominance
Relative to TSH
Posterior projection of organs represents chronic congestion and/or state of dysfunction T4, left
Para spinal, 2.5 cm lateral
Pain on palpation
TRH
Scapula, right
Inferior-medial, T7-T8
Pain on palpation
FSH, TRH
Congestion, colon
Scapula, left
Inferior-medial, T7-T8
Pain on palpation
TSH, PL
Congestion, colon
General
Extremities
Lymphatic congestion
Thyroid
Latent hypothyroidism
Palm
Central
Erythematous
Thyroid
Strong
Oversolicitation of exocrine pancreas
TRH role implicated; direct interpretation: Congestion, lung, bronchial involvement
A clinical approach to the thyrotropic axis Chapter | 10 151
TABLE 10.10 Others signs by region—cont’d Part
Quality
Finding
Level
Activity
Comment
Leg
Medial to ankle, bilateral
Adiposity
TSH
Elevated
Compensated hypothyroidism
Leg
Proximal tibia, most medial aspect
Pain on palpation
T4
Diminished efficiency
LH implicated in strong TSH, pain L > R on exam
Leg
Proximal tibia, most medial aspect
Pain on palpation
TSH
Strong
LH more easily disturbed than FSH by strong TSH, pain L > R on exam
Ankle
Superior to ankle
Fat pad
TSH
Reactive
Compensation attempt for weak T4
A discussion of key thyrotropic indexes of the biology of functions When approaching an evaluation of the thyrotropic indexes, first review quantitative biomarker measurements: serum TSH, free T4, free T3, thyroid antibodies, etc. This information will contextualize the interpretation of indexes, especially since serum TSH is used to calculate a number of indexes. What is presented here is not comprehensive. It is a discussion of key indexes for students working with the elementary
concepts of endobiogeny. The indexes are d ivided into groups based on the area of origin and area of action that the indexes represent. It is arbitrary and there are some overlaps that are not presented to avoid redundancy. Conceptually, we have grouped the indexes as follows: central indexes with peripheral impact (Table 10.11; Fig. 10.1), radial gonado- thyrotropic (Table 10.12), those evaluating the thyroid gland and its threshold of response (Table 10.13), and, parathyroid and bone indexes (Table 10.14).
TABLE 10.11 Central thyrotropic indexes with peripheral impact Relationship Index
Definition
Import
Direct
Thyroid relaunching
It measures the level of reactivation of the thyrotropic axis by the locus ceruleus (Fig. 10.1)
It witnesses the degree of disadaptation of the organism, implicating the solicitation of TRH for central and/or peripheral activity and all that that implies
Thyroid relaunching corrected
It measures the endogenous part of solicitation of the thyrotropic axis by the locus ceruleus. By extension, it indicates the level of endogenous disadaptation of the organism (Fig. 10.1)
It witnesses the degree of disadaptation arising specifically from endogenous causes of disadaptation
Thyroid relaunching
TRH/TSH
It measures the relative level of tissular activity of TRH in relation to that of TSH
Indirectly it evaluates the relative part of congestion vs hyperplasia in anabolic adaptation, the relative part of nutrition vs metabolic production, the relative part of neuroendocrine vs organo-metabolic adaptation, and the relative part of the elaboration of potential vs structural realization, and thus of the imaginary relative to the material realization
Amylosis index, demyelination index
Inverse
Correlations Adaptation index, genito-thyroid, beta-MSH/alphaMSH Adaptation index, genito-thyroid, beta-MSH/alphaMSH
Adenosis index, serum TSH
Estrogen index, organotissular estrogen yield index, prolactin index
152 The Theory of Endobiogeny
FIG. 10.1 Thyroid relaunching and thyroid relaunching corrected indexes. Center: the locus ceruleus, in the brain stem, is the origin of noradrenalin (NA), the neurotransmitter of alpha-sympathetic. The thyroid relaunching index evaluates the degree to which alpha stimulates TRH in the parvoventricular nucleus of the hypothalamus. TRH relaunches thyroid activity (left). The thyroid relaunching index corrected corrects the basic evaluation for the degree that this occurs due to endogenous threats, be they real or perceived, mental or emotional aggressions. In this example, the limbic area (right), stimulates alpha in the locus ceruleus, which then stimulates TRH and relaunches the thyroid. (© 2015 Systems Biology Research Group.)
TABLE 10.12 Radial gonado-thyrotropic index Relationship Index
Definition
Import
Direct
Genito-thyroid
It measures the part played by the gonads in the appeal to and response by both metabolic and endocrine thyroid activity in the functional adaptation of structure
High: Thyroid activity is efficient relative to the estrogen demand. Favors inflammation and autoimmunity Low: TSH is not able to adapt the thyroid relative to the degree of estrogen demand. Favors hyperimmunity
Cortisol
Inverse
Correlations Adaptation index, cortisol index, corrected estrogen index IL-1, thyroid index, thyroid yield
TABLE 10.13 Indexes evaluating the thyroid gland and its activity Relationship Index
Definition
Import
Direct
Inverse
Correlations
Thyroid index
It measures the effective metabolic activity of peripheral thyroid hormones
High: Thyroid metabolic activity is elevated without conclusion regarding the degree of solicitation, rate of response or requirements of the organism Low: Thyroid metabolic activity is diminished without conclusion to the degree of solicitation, rate of response or requirements of the organism
LDH
CK
Genito-thyroid, thyroid yield, metabolic yield
Thyroid yield
It measures the relative part of the thyroid’s metabolic contribution in comparison with the level pituitary stimulation
High: The thyroid is easily relaunched when its metabolic effects decline Low: There is a delay in the readaptation of thyroid metabolic activity by the pituitary
Thyroid index
Serum TSH
Genito-thyroid, thyroid yield, metabolic yield
A clinical approach to the thyrotropic axis Chapter | 10 153
TABLE 10.14 Parathyroid and bone indexes Relationship Index
Definition
Import
Direct
Inverse
Correlations
Para-thyroid hormone index (PTH)
It measures the endocrinometabolic activity of PTH
High: There is a prolonged appeal to PTH to solicit bone for adaptation due to the inefficiency of thyroid activity in regulating cellular respiration and/ or the efficiency of thyroid response to stimulation Low: The inverse holds true
Serum calcium
Thyroid metabolic index
Bone remodeling
Bone remodeling
It measures bone remodeling activity and the extent of bone impairment. It also bears witness to the general level of metabolism, and specifically to its adaptation activity
High: The bone is being solicited in its turnover activity to participate in adaptation as a source of calcium for adaptation and osteocalcin for metabolism Low: Favors a more efficient peripheral metabolic activity that does not require a strong appeal to bone
Serum TSH
Estrogen activity
PTH, adrenal cortex, estrogen index, corrected estrogen index
References 1. Duraffourd C, Lapraz JC. Traité de Phytothérapie Clinique: Médecine et Endobiogénie. Paris: Masson; 2002. 2. Lapraz JC, Carillon A, Charrié J-C, et al. Plantes Médicinales: Phytothérapie Clinique Intégrative Et Médecine Endobiogénique. Paris: Lavoisier; 2017.
3. Lapraz J-C, Clairemont de Tonnerre M-L. La Médecine Personnalisée: Retrouver Et Garder La Santé. Paris: Odile Jacob; 2012.
A clinical approach to the thyrotropic axis Introduction The thyrotropic axis is the second of the two catabolic axes. Recall that its purpose is to manage adaptation and growth. Because of the diversity of these demands and the evolutionary history that resulted in this axis (The Theory of Endobiogeny, Volume 1, Chapter 8), the function of each hormone and emunctory within the axis goes far beyond vertical hypothalamic-pituitary-thyroid regulation. Understanding the similarity and divergence of the arrangement and function of the two catabolic axes helps the clinician identity areas of oversolicitation, imbalance, and regulation (Table 10.1). For example, if the corticotropic axis one notes a low adrenocorticotropin hormone (ACTH) index and elevated cortisol, and, in the thyrotropic axis elevated thyroid relaunching and thyroid index, the origin of both will be related to alpha-sympathetic activity. Using a sympatholytic such as Lavandula angustafolia (lavender) essential oil or Passiflora incarnata (passionflower) may be sufficient to regulate both axes. However,
if the thyrotropic axis has multiple indexes elevated and the corticotropic axis is not deranged to a similar degree, treatment should focus primarily and alpha-sympatholytic and thyrotropic plants that inhibit central activity. For example, in addition to lavender and passionflower, one would be wise to use Lycopus europaeus (gypsywort) and Fabiana imbricata (pichi) to inhibit thyrotropin-releasing hormone (TRH) and thyroid-stimulating hormone (TSH) and peripheral thyroid activity.1, 2 The chief metabolite of the thyrotropic axis is lipids, its chief mineral calcium. When evaluating indexes of this axis, also evaluate the lipid panel and indexes related to passive cellular permeability within the somatotropic axis. With respect to calcium, evaluate the serum calcium level, the adaptogen index, parathyroid hormone index, etc. Unlike the corticotropic axis, the thyrotropic contains within itself the means to utilize or facilitate that which it has mobilized. Table 10.2 summarizes metabolites and the thyrotropic hormones implicated.
TABLE 10.1 A comparison of the two catabolic axes in first and second loops First loop
Corticotropic
Thyrotropic
Hypothalamic
CRH
TRH
Anterior pituitary
ACTH
TSH
End-organ hormone
Cortisol
Annexal organ(s)
Liver
Thymus Parathyroid: PTH
Second loop
Corticotropic
Thyrotropic
Hypothalamic
CRH
TRH
Anterior pituitary
ACTH
TSH
End-organ hormone
Aldosterone
T3
Annexal organs
Liver, lung, kidney: Angiotensin II, renin
Skin, liver, kidney: Vitamin D
Emunctories and implicated organs
Skin, kidney, liver, gallbladder digestive tract
Liver, gallbladder, digestive tract, exocrine pancreas, endocrine pancreas, lungs
DHEA
The Theory of Endobiogeny. https://doi.org/10.1016/B978-0-12-816908-7.00010-4 © 2019 Elsevier Inc. All rights reserved.
T4
Calcitonin
145
146 The Theory of Endobiogeny
TABLE 10.2 Mobilization and utilization of metabolites by the thyrotropic hormones Mobilization Metabolite
TRH
Glucose
•
Amino acids
•
T4
Utilization PTH/D3
•
Lipids
•
Calcium
•
TSH
T3
•
•
•
•
D3
Calcitonin
•
•
• •
•
D3, vitamin D3; PTH, parathyroid hormone.
Anatomy, pathophysiology The thyrotropic axis has a notable impact on the development of ectodermal tissues, especially the nervous system, the adrenal medulla (βΣ), and immunity. The pituitary gland is an ectodermal tissue and hence this axis regulates the very foundation of endocrine management of the periphery. The thyrotropic axis is permanently linked to structural formation, structural maintenance, and functional competency of adaptation. The thyrotropic axis gives birth to βΣ, and βΣ entrains and enlivens the thyrotropic axis in turn by sensibilizing tissues to T4 activity. Adaptation syndromes, spasmophilia, neurologic disorders, and disorders of hyper- and autoimmunity are all disorders that lay within the thyrotropic axis. With respect to diseases of adaptation and adaptability, both catabolic axes are directly relaunched by αΣ. Thus, both axes are directly linked to conscious, subconscious, and physiologic perceptions of and response to aggression (The Theory of Endobiogeny, Volume 1, Chapter 12). From the evolutionary perspective, the thyrotropic axis is also closely linked to the sympathetic branch of the autonomic nervous system (ANS) because dopamine, noradrenalin, adrenaline, T4, and T3 are all derived from the amino acid tyrosine. The role of TRH in all these activities cannot be underestimated. It directly or indirectly affects all four axes. In the corticotropic axis, it fixates cortisol to its receptors. In the gonadotropic axis, it stimulates follicle-stimulating hormone (FSH) and directly affects estrogen activity. Its thyrotropic function is the classic vertical activity and stimulation of conversion of T4 to T3. TRH has a privileged thyro-somatotropic relationship as the hypothalamic stimulator of prolactin (which also alters the impact of estrogens). In the somatotropic axis, it stimulates the release of glucagon from the endocrine pancreas with a reflexive
response by insulin. Recall its central actions as a neurohormone is related to circadian and seasonal adaptation, thought, and emotions. TRH is also a general neuromodulator. Ultimately, TRH assists in the integration of the interior and external worlds.
Clinical significance of the thyrotropic axis When evaluating the level of function of the thyrotropic axis, it is capital to understand two concepts from an endobiogenic perspective. First, a number of the symptoms attributed to hypo- and hyperfunctioning of thyroid hormones are due to central thyroid hormones (TRH, TSH), or the sensibilization of other neuroendocrine factors and not the peripheral hormones ipso facto. Second, most signs, symptoms, and disorders related to the thyrotropic axis are relative and qualitative in nature, not absolute or quantitative. Table 10.3 demonstrates the role of various aspects of the thyrotropic axis in hyperthyroidism. Table 10.4 demonstrates the various aspects of the aspect with respect to hypothyroidism.
Symptoms related to the thyrotropic axis Various symptoms can be related to the thyrotropic axis (Table 10.5).
Signs related to the thyrotropic axis There are a number of signs related to the thyrotropic axis. They can be divided into the following areas: temperament an internal mental life (Table 10.6), neurologic (Table 10.7), head, ears, eye, nose and throat (Table 10.8), thyroid and chest (Table 10.9), and miscellaneous areas (Table 10.10).
A clinical approach to the thyrotropic axis Chapter | 10 147
TABLE 10.3 Role of various aspects of the thyrotropic axis in hyperthyroidism Thyrotropic factor Factor
↑ TRH
↑ TSH, serum
Endocrine Symptom
Tremors Muscle wasting Insomnia
Exam
↑ Deep tendon reflex Eyelid flutter Clonus
Inflammation Hair loss Brain fog
↑ T4
↑ T3
Overproduced from overstimulation
Overproduction, overconversion
Heat intolerance (if insufficient conversion to T3)
Cold sensitivity
Skin temperature elevated ↑ Osteoclasty
Structural Types of hyperthyroidism Reactive
Hypercatabolic, reactive thyroid state: Asthma, spring arthritis
Fundamental
Low TSH relaunching; peripheral hyperthyroidism: hyperestrogenic (thus hyper T4), hyper beta, risk of breast cancer; psoriasis Treatment: Lycopus europaeus, Borago officinalis; if DHEA, ACTH implicated in the estrogenism: Fragaria vesca
TABLE 10.4 Role of various aspects of the thyrotropic axis in hypothyroidism Thyrotropic factor Factor
TRH insufficient
↑ TSH, serum
↑ T4
↑ T3
Endocrine
Insufficient conversion of T4 to T3
Insufficient production of T4
Anabolic predominance
Mitochondrial strain
Symptom
Repetitive dreams
Weight gain
Hair loss Thinning eyebrows Alteration in timbre of voice: low, weak, and/ or hoarse
Fatigability
Exam
Hyperestrogenism
Types of hypothyroidism Latent
Lymphocytosis; cardiac vegetations; tonsil hypertrophy; appendix hypertrophy
Entrained
Elevated TRH or PL or DA; If there is elevated GH → appeal to glucose with diminished effect of GH (from strong insulin response)
Reactive TSH compensation
Fat pad above ankles (like Kurdish pants); Cobble stoning of posterior pharynx Treatment: Avena sativa, Verbascum thapsus
TABLE 10.5 Symptoms related to the thyrotropic axis3 Category
Finding
Level
State
Brain
General mental fatigue
Thyroid
Insufficient or excessive
Dermatologic
Pruritis
Thyroid
Elevated
Psoriasis
T4
Elevated
General physical fatigue
Thyroid
Insufficient
Energy, lack of
Thyroid
Insufficient
Ear, nose, throat
Enlarged tonsils
Thyroid/TSH, serum
Insufficient/elevated
Genito-urinary
Reduction in the duration on menstruation
Thyroid
Excessive
Reduction in the volume of menstrual flow
Thyroid
Insufficient
PMS with great irritability
Thyroid
Increased
Menstrual flow heavy
Thyroid
Insufficient
Heat intolerance
T4
Hyperfunctioning
Cold sensitivity
T3
Hyperfunctioning
Constantly cold
Thyroid
Deficient in response
Weight loss despite a good appetite
Thyroid
Excessive
Weight gain
Thyroid
Insufficient, especially with elevated TSH serum and relative to global adrenal cortex activity
Insomnia with great agitation
TRH
Hyperfunctioning
Dreams animated, vivid
TRH
Hyperfunctioning
Dreams in black and white
TRH
Insufficient
Repetitive dreams
TRH
Augmented
Energy
Metabolic
Sleep
TABLE 10.6 Temperament and internal mental life3 Finding
Level
Activity
Comment
Great vivacity
Thyroid
Dynamically efficient
Goal oriented
TRH
Predominant
Relative to TSH. It indicates being flexible in conceiving various orders and methods of executing plans. It does not imply that the person has the capacity to execute, only that they can conceive of multiple ways of performing
Process-oriented
TSH
Predominant
Relative to TRH. It is a tendency to be less willing, or, less able to conceive of alternate ways of executing a series of actions that were planned in advance in a particular order
Soft, easily gives in
Thyroid
Insufficient, especially during adaptation
Evaluate for strong para, weak beta, weak TRH
Fearfulness
Thyroid
Insufficient
Correlate with hyper-TRH that attempts to relaunch peripheral thyroid activity
Anxiety and nervousness
TRH
Hyperfunctioning
Tendency; correlate with elevated central and peripheral alpha and elevated dopamine
Expansive creativity
TRH
Predominant
Relative to TSH, with complementary levels of central histamine serotonin and dopamine. This type of creativity arises seeing novel relationships through tangential association
Juxtapositional creativity
TSH
Predominant
Relative to TRH. This type of creativity arises from analytical thinking with juxtaposition of basic elements into novel relationships
Depressive tendency
Thyrotropic
Dysfunctional
Correlate with hyper-TRH if comorbidity of anxiety, with insufficient peripheral thyroid activity if flat affect or psychomotor retardation. TSH has variable effects
A clinical approach to the thyrotropic axis Chapter | 10 149
TABLE 10.7 Neurologic signs3 Part
Quality
Finding
Level
Activity
Comment
General
Startle response
Startles easily to the lightest touch or sound
TRH
Reactive
Correlate with strong beta expression
Eyelids
Flutter
Spontaneous at rest
TRH
Hyperfunctioning
Base line thought
Eyelids
Flutter
Spontaneous interacting
TRH
Hyperfunctioning
In adaptation
Glabellar tap
Postglabella tap movement
Eyelid rapid flutter
TRH
Reactive
Eye
Pupillary light reflex
Exaggerated constriction to light
TRH
Reactive
Clonus
Foot
Brisk, diffuse
TRH
Elevated
Via spinal column
Deep tendon reflex (DTR)
Tendons
Brisk, diffuse
TRH
Elevated
Via spinal column
Extremities
Arms, hands, legs
Tremors
TRH
Excessive
And dysregulated; correlate with dopamine and alpha
TABLE 10.8 Signs related to head, ears, eye, nose, and throat3 Part
Quality
Finding
Level
Activity
Comment
Body
Build
Sharp features
TSH
Predominant
Example: Sharp nose, high cheek bones, pointed chin, oval face, thin build
Voice
Quality
Weak and hoarse
Thyroid
Insufficient
T3 is generally more implicated than T4
Skin
Temperature and moisture
Cold and dry
Thyroid
Insufficient
Generalized to entire body
Nail
Thickness
Fine and breakable
Thyroid
Insufficient
Hair
Quality
Thick
Thyroid
Favorably adapted
Curly hair
TRH
Predominant
Fragile
Thyroid
Insufficient
Thin
Thyroid
Not predominant
Falls out easily
Thyroid
Insufficient
Alopecia
Thyroid
Insufficient
Or in autoimmune terrain
Arch
Convex
TRH
Predominant
Occurs when there is a strong GH and ACTH response
Pilosity
Fine
Thyroid
Strong
Thinning from hair loss at the ends
Thyroid
Diminished
Relative to historically adapted levels
Length
Long
Thyroid
Well functioning
Initiated by FSH
Curvature
Curled at ends
Thyroid
Insufficient to demand
Gonadotropic appeal to re-equilibrate thyroid to gonadotropic function
Eyebrow
Eyelashes
Structural role of TRH along with appeal to thyroid and GH; all three conditions must be present
In structural nourishment of hair
TABLE 10.8 Signs related to head, ears, eye, nose, and throat—cont’d Part
Quality
Finding
Level
Activity
Comment
Eye
Size
Large
TRH, alpha, central
Strong
More predominant in children and women with anxiety tendency
Small
Thyroid
Insufficient
Inability to readjust peripheral thyroid activity during fetal development
Tonsils
Size
Hypertrophy
Thyroid
Insufficient responsiveness to TSH
Reflects a latent thyroid insufficiency
Pharynx
Deformity
Cobble stoning
Thyroid
Insufficient responsiveness to TSH
Elevated TSH to compensate for latent thyroid insufficiency
TABLE 10.9 Signs related to the thyroid gland and chest3 Part
Quality
Finding
Level
Activity
Comment
Thyroid
Volume
Increased
Thyroid
Augmented
Consistency
Nodules
Thyroid
Oversolicited
Consistency
Goiter
Thyroid
Insufficient
Clavicle, bilateral
Proximal
Pain on palpation
Sternum
Orientation
Convex sternum
PTH
Elevated
Correlate with GH
Breasts
Asymmetry
Left > right
TSH
Predominant
Instructure, in response to the basic influence of LH on laterality
Heart
Rate
Heart rate rapid
Thyroid
Augmented
May be absolutely elevated or augmented by TRH and/or cortisol
Finding
Level
Activity
TSH demand greater than T4 response
Thyroid gland congestion from oversolicited
TABLE 10.10 Others signs by region3 Part
Quality
Comment
Anterior projection of organs represents the current anatomical congestion and/or state of dysfunction Colon
Transverse, distal, left
Pain on palpation
TSH
Strong
Oversolicitation of thyroid and splenic flexure for nutrient reuptake
Colon
Transverse, distal, right
Pain on palpation
TRH
Predominance
Relative to TSH
Posterior projection of organs represents chronic congestion and/or state of dysfunction T4, left
Para spinal, 2.5 cm lateral
Pain on palpation
TRH
Scapula, right
Inferior-medial, T7-T8
Pain on palpation
FSH, TRH
Congestion, colon
Scapula, left
Inferior-medial, T7-T8
Pain on palpation
TSH, PL
Congestion, colon
General
Extremities
Lymphatic congestion
Thyroid
Latent hypothyroidism
Palm
Central
Erythematous
Thyroid
Strong
Oversolicitation of exocrine pancreas
TRH role implicated; direct interpretation: Congestion, lung, bronchial involvement
A clinical approach to the thyrotropic axis Chapter | 10 151
TABLE 10.10 Others signs by region—cont’d Part
Quality
Finding
Level
Activity
Comment
Leg
Medial to ankle, bilateral
Adiposity
TSH
Elevated
Compensated hypothyroidism
Leg
Proximal tibia, most medial aspect
Pain on palpation
T4
Diminished efficiency
LH implicated in strong TSH, pain L > R on exam
Leg
Proximal tibia, most medial aspect
Pain on palpation
TSH
Strong
LH more easily disturbed than FSH by strong TSH, pain L > R on exam
Ankle
Superior to ankle
Fat pad
TSH
Reactive
Compensation attempt for weak T4
A discussion of key thyrotropic indexes of the biology of functions When approaching an evaluation of the thyrotropic indexes, first review quantitative biomarker measurements: serum TSH, free T4, free T3, thyroid antibodies, etc. This information will contextualize the interpretation of indexes, especially since serum TSH is used to calculate a number of indexes. What is presented here is not comprehensive. It is a discussion of key indexes for students working with the elementary
concepts of endobiogeny. The indexes are d ivided into groups based on the area of origin and area of action that the indexes represent. It is arbitrary and there are some overlaps that are not presented to avoid redundancy. Conceptually, we have grouped the indexes as follows: central indexes with peripheral impact (Table 10.11; Fig. 10.1), radial gonado- thyrotropic (Table 10.12), those evaluating the thyroid gland and its threshold of response (Table 10.13), and, parathyroid and bone indexes (Table 10.14).
TABLE 10.11 Central thyrotropic indexes with peripheral impact Relationship Index
Definition
Import
Direct
Thyroid relaunching
It measures the level of reactivation of the thyrotropic axis by the locus ceruleus (Fig. 10.1)
It witnesses the degree of disadaptation of the organism, implicating the solicitation of TRH for central and/or peripheral activity and all that that implies
Thyroid relaunching corrected
It measures the endogenous part of solicitation of the thyrotropic axis by the locus ceruleus. By extension, it indicates the level of endogenous disadaptation of the organism (Fig. 10.1)
It witnesses the degree of disadaptation arising specifically from endogenous causes of disadaptation
Thyroid relaunching
TRH/TSH
It measures the relative level of tissular activity of TRH in relation to that of TSH
Indirectly it evaluates the relative part of congestion vs hyperplasia in anabolic adaptation, the relative part of nutrition vs metabolic production, the relative part of neuroendocrine vs organo-metabolic adaptation, and the relative part of the elaboration of potential vs structural realization, and thus of the imaginary relative to the material realization
Amylosis index, demyelination index
Inverse
Correlations Adaptation index, genito-thyroid, beta-MSH/alphaMSH Adaptation index, genito-thyroid, beta-MSH/alphaMSH
Adenosis index, serum TSH
Estrogen index, organotissular estrogen yield index, prolactin index
152 The Theory of Endobiogeny
FIG. 10.1 Thyroid relaunching and thyroid relaunching corrected indexes. Center: the locus ceruleus, in the brain stem, is the origin of noradrenalin (NA), the neurotransmitter of alpha-sympathetic. The thyroid relaunching index evaluates the degree to which alpha stimulates TRH in the parvoventricular nucleus of the hypothalamus. TRH relaunches thyroid activity (left). The thyroid relaunching index corrected corrects the basic evaluation for the degree that this occurs due to endogenous threats, be they real or perceived, mental or emotional aggressions. In this example, the limbic area (right), stimulates alpha in the locus ceruleus, which then stimulates TRH and relaunches the thyroid. (© 2015 Systems Biology Research Group.)
TABLE 10.12 Radial gonado-thyrotropic index Relationship Index
Definition
Import
Direct
Genito-thyroid
It measures the part played by the gonads in the appeal to and response by both metabolic and endocrine thyroid activity in the functional adaptation of structure
High: Thyroid activity is efficient relative to the estrogen demand. Favors inflammation and autoimmunity Low: TSH is not able to adapt the thyroid relative to the degree of estrogen demand. Favors hyperimmunity
Cortisol
Inverse
Correlations Adaptation index, cortisol index, corrected estrogen index IL-1, thyroid index, thyroid yield
TABLE 10.13 Indexes evaluating the thyroid gland and its activity Relationship Index
Definition
Import
Direct
Inverse
Correlations
Thyroid index
It measures the effective metabolic activity of peripheral thyroid hormones
High: Thyroid metabolic activity is elevated without conclusion regarding the degree of solicitation, rate of response or requirements of the organism Low: Thyroid metabolic activity is diminished without conclusion to the degree of solicitation, rate of response or requirements of the organism
LDH
CK
Genito-thyroid, thyroid yield, metabolic yield
Thyroid yield
It measures the relative part of the thyroid’s metabolic contribution in comparison with the level pituitary stimulation
High: The thyroid is easily relaunched when its metabolic effects decline Low: There is a delay in the readaptation of thyroid metabolic activity by the pituitary
Thyroid index
Serum TSH
Genito-thyroid, thyroid yield, metabolic yield
A clinical approach to the thyrotropic axis Chapter | 10 153
TABLE 10.14 Parathyroid and bone indexes Relationship Index
Definition
Import
Direct
Inverse
Correlations
Para-thyroid hormone index (PTH)
It measures the endocrinometabolic activity of PTH
High: There is a prolonged appeal to PTH to solicit bone for adaptation due to the inefficiency of thyroid activity in regulating cellular respiration and/ or the efficiency of thyroid response to stimulation Low: The inverse holds true
Serum calcium
Thyroid metabolic index
Bone remodeling
Bone remodeling
It measures bone remodeling activity and the extent of bone impairment. It also bears witness to the general level of metabolism, and specifically to its adaptation activity
High: The bone is being solicited in its turnover activity to participate in adaptation as a source of calcium for adaptation and osteocalcin for metabolism Low: Favors a more efficient peripheral metabolic activity that does not require a strong appeal to bone
Serum TSH
Estrogen activity
PTH, adrenal cortex, estrogen index, corrected estrogen index
References 1. Duraffourd C, Lapraz JC. Traité de Phytothérapie Clinique: Médecine et Endobiogénie. Paris: Masson; 2002. 2. Lapraz JC, Carillon A, Charrié J-C, et al. Plantes Médicinales: Phytothérapie Clinique Intégrative Et Médecine Endobiogénique. Paris: Lavoisier; 2017.
3. Lapraz J-C, Clairemont de Tonnerre M-L. La Médecine Personnalisée: Retrouver Et Garder La Santé. Paris: Odile Jacob; 2012.