Cachexia Clinical Trial
Official title:
Mitochondrial Activity and Myosteatosis in the Cachexia of Cancers of the Upper Aerodigestive Tract
Loss of muscle mass (scientific term: cachexia) affects about 80% of patients with advanced
cancer and impacts their prognosis by decreasing tolerance and response to treatment,
decreasing quality of life and survival. The prognosis in these patients depends directly on
the importance of the loss of muscle mass. Preserving it is therefore an essential
therapeutic objective. It is therefore important to understand perfectly the mechanism of
this muscular loss. The accumulation of fat in the muscle (scientific term: myosteatosis)
could be a mechanism responsible for this loss of muscle mass. It is indeed a hypothesis
proved on animal models. Moreover, it has recently been shown that more the cancer patient
loses weight, more his muscle contains fat. This lets think that this deposit of fat in the
muscle would be directly related to the loss of muscle mass. All of these observations could
not be clearly established in humans and investigators are seeking by this study to
illuminate these mechanisms at the human level. A better understanding of these mechanisms
would allow investigator to set up targeted treatments against the accumulation of fat in
the muscle, which would significantly improve the quality of life of patients with cancer of
the aerodigestive pathways and their chances of recovery.
The MYOMEC study includes the inclusion of healthy patients (to form a control group) but
also patients with cancer of the upper aero-digestive tract. The study will be divided into
two parts: clinical examination and nutritional evaluation the day before surgery at the
time of the participants' admission to hospital and then the biological samples during
surgery. The nutritional examination consists in collecting the morphological data of the
patient, namely:
Its weight, size, calculation of the body mass index Tests of muscular strength (wearing
weight of 1, 2 and 3 kilos) Measurement of the percentage of fat mass and lean mass
(Impedancemetry)
In this study, participants benefit from the following investigations:
- Clinical examination complete with elaboration of the clinical nutritional status,
realized the day before the surgical intervention in hospitalization.
- Elaboration of the radiological nutritional status by a complementary analysis of the
scanner envisaged in the balance of extension of the disease
- Performing surgical site sampling during surgery without additional invasive procedure
and under general anesthesia. It will be realized:
A muscle biopsy of the sterno-cleido-mastoid muscle (neck muscle) (maximum volume 5 mm3), A
tumor biopsy (maximum volume 5mm3). A blood sample (maximum volume 5ml)
No invasive procedure, supplemental examination or additional consultation is required for
the whole off-set study for the extensive muscular percutaneous biopsy regarding which
additional patient agreement will be required. No additional follow-up is required when
participating in this study. Participation in this study does not entail any particular
constraint or additional treatment. The duration of the patient's participation is defined
as follows: from the date of the preoperative consultation or from the consultation of
announcement until his / her discharge from hospital. The exclusion period defined in this
study extends from the date of inclusion of the patient to the date of the surgical
procedure, during which time the patient can not participate in another clinical research
protocol.
Malnutrition is characterized by a negative energy balance due to a deep skeletal muscular
loss, which is itself secondary to the reduction of intake and metabolic abnormalities
aggravating the loss of weight. Sarcopenia is defined as the loss of muscle mass, the
consequences of which are a decrease in muscle strength and physical performance .Cachexia,
identified in many chronic diseases (renal insufficiency, heart failure, diabetes, COPD), is
the result of an imbalance between proteolysis and proteogenesis and can be defined as a
multifactorial syndrome characterized by a weight loss resulting mainly from a loss of lean
mass, in particular muscle mass, which is not reversible by an adequate nutritional
contribution and which leads to functional abnormalities.
Cancers of the ENT sphere represent about 15% of all cancers in men and 2% in women. They
mainly concern subjects between 45 and 70 years of age with a predominant role of
ethylo-tobacco poisoning. Patients with upper aero-digestive tract cancers are particularly
prone to malnutrition on the part of the tumor itself but also on the context
(ethylo-tobacco intoxication, sedentary behavior, poor general condition), tumor
localization involving reduction of intake (Mechanical obstruction, anorexia, pain), but
also after treatment (chemotherapy, radiotherapy, surgery).
Cancer cachexia affects approximately 80% of patients with advanced cancer and impacts their
prognosis by increasing morbidity and mortality, decreased tolerance and response to
treatment , decreased quality of life and decreased survival. Its prognosis depends on the
extent of the loss of muscle mass. It is generally reported for a patient with a weight loss
superior than 5% of its initial weight over the last 6 months, with 3 stages described:
Pre-cachexia stage, clean cachexia stage, refractory cachexia stage. It is characterized,
among other things, by the development of systemic inflammation and tumor cell lines and
tumor cells from cancer patients have been shown to produce pro-inflammatory cytokines (
IL-6, IL-8).
The loss of skeletal muscle mass, up to 75% in severe malnutrition is related to an
acceleration of muscle catabolism and an alteration of muscle protein anabolism, mediated by
large tumor signals and leads to a decrease in performans status, decrease in overall
survival, increase in susceptibility to toxicity of chemotherapy, and increase in exposure
to long-term hospital stays.
This muscular loss is the result of an increase in proteolysis phenomen but also of a
decrease in protein synthesis. The main proteolytic pathways are the
calpain-calcium-dependent pathway, the lysosomal pathway and the ubiquitin-proteasome-ATP
pathway. Several studies have shown the activation of these proteolytic pathways in cancer
cachexia . Among these proteolytic pathways, the ubiquitin-proteasome-ATP-dependent pathway
appears to be the most involved in cancer cachexia .This proteolytic pathway is mediated by
2 ubiquitin ligases specific for skeletal muscle, MAF-Box and MURF1, which are largely
overexpressed in many models of muscular atrophy and cancer cachexia . On the other hand,
the growth factor IGF1 is a known anabolic factor which activates the proteosynthesis via
the signaling pathway PI3K / Akt / mTOR . The decrease in IGF1 expression in skeletal muscle
is observed in experimental models of cancer cachexia . Studies have shown that certain
factors of tumor origin may contribute to cancer cachexia in some animal models.
2 factors have particularly attracted the attention of scientists in recent years, the ZAG
factor (Zinc alpha 2 glycoprotein), a veritable lipid mobilization factor in humans ,
overexpressed in the liver and adipose tissue and PIF (proteoglycan identified in mouse
murine adenocarcinoma tumor cells which would be responsible for muscle wasting induced by
the activation of the ubiquitin-proteasome-ATP-dependent proteolytic pathway . More recent
work suggests that Myostatin and Activin A, two members of the TGFβ superfamily, may
contribute to cachexia, particularly muscular atrophy, induced by certain cancers.
Adipose loss is an early syndrome in the development of cancer cachexia and is negatively
correlated with patient life expectancy . Early studies on this adipose melt revealed a lack
of storage of triglycerides in adipose tissue . The storage of triglycerides is achieved by
the action of lipoprotein lipase. It predominantly exists in adipose tissue and hydrolyzes
lipoproteins circulating in the blood, thus allowing the capture of fatty acids by
adipocytes and storage of adipose reserves . The development of the tumor would induce a
decrease in the gene expression and activity of lipoprotein lipase via the action of
inflammatory cytokines . However, current research seems to demonstrate that the adipose
melt observed in cancer cachexia is mostly explained by an increase in lipolysis (shown
indirectly by an increase in plasma fatty acid concentration in cachectic patients with
gastrointestinal cancer). .
Lipolysis, via hormone-sensitive lipase (LHS) and monoglyceride lipase (MGL), allows the
hydrolysis of triglycerides into diglycerides and diglycerides into monoglycerides
themselves degraded into free fatty acids and glycerol. Adipose tissue-specific triglyceride
lipase (TGLA) has recently been discovered and has a role that is redundant to that of LHS.
Studies of Cao et al. showed that the activation of LHS by catecholamines could constitute a
mechanism of regulation of lipolysis during cancer cachexia. . An alteration of TGLA and LHS
would also be responsible for an accumulation of DAG and TAG in the muscle of cancerous mice
. A recent study showed that the invalidation of TGLA and LHS in 2 models of cachexia
induced by injection of Lewis pulmonary carcinoma cells or B16 melanoma cells induced
resistance to the development of cachexia by limiting adipose and muscular loss . Systemic
inflammation developed during cancerous cachexia could also induce an increase in insulin
resistance via TNFalpha . TNFalpha could inhibit the expression of perilipin A, a protein
expressed on the surface of adipocyte lipid droplets , which plays a major role in the
integrity of adipose tissue since it limits the access of enzymes involved in lipolysis to
the lipid droplet . A decrease in the expression of perilipin A would induce an increase in
lipolysis. In addition, a study by Stephens et al. in 2011 concluded that the number and
size of intramuscular lipid droplets are increased in the presence of cancer and also
increase with weight loss / adipose fat loss in other body compartments .
Myosteatosis, a pathological fatty deposit in skeletal muscle, is another characteristic of
body composition, in addition to low muscle mass, which is associated with the poor
prognosis of the cancer disease, in particular a decrease in overall survival and it has
recently been shown that the muscle of cancer patients contains all the more adipose tissue
that severe weight loss . Several studies have shown that myosteatosis is associated with an
increase in insulin resistance and therefore a decrease in proteolysis via the inhibition of
insulin transport of amino acids. The fat content of the muscle may be indirectly and
non-invasively studied on the basis that the adipose tissue typically attenuates the
radiation applied thereto. . The value of the attenuation measurements are determined by the
rate at which the radiation passes through the tissue and is expressed in Hounsfield units
(HU). Muscle and adipose tissue attenuation values were defined between -190 and -30 HU .
The weakening of the radiation in the muscle was correlated well with the fat content of the
muscles. . Thus, the HU values defined by the CT scan may reflect the degree of
intramuscular adipose tissue and are used to categorize the muscle of normal or exposed to
myosteatosis . Low muscle mass and weakening of the radiation in muslce testify of high
degree of myostaatosis and were identified as an independent prognostic factor for overall
survival and mortality in cancer patients, respectively. . The comparison of muscle
metabolism in obese and normoponded subjects showed an abolition of protein synthesis in
response to insulin especially in muscle mitochondria in overweight subjects. Interestingly,
muscle protein renewal was inversely correlated with fat mass. Such an observation raises
the question of the possibility of a deleterious effect of fat mass on protein synthesis.
The hypothesis of this lipotoxicity was confirmed by a work carried out in the rat which
showed that the synthesis of the muscle proteins is slowed down when there is infiltration
of fat into the muscle
At the cellular level, metabolism is governed by the mitochondria which provides 90% of our
energy in the form of ATP. This energy is synthesized within oxidative phosphorylation,
which consists of 2 entities (the respiratory chain and ATP synthase) and which allows the
conversion, in water and ATP, of the reduced equivalents resulting from dehydrogenation
reactions (and Decarboxylation) of energetic nutrients, in the presence of dioxygen (O2) and
ADP, according to chemosmotic coupling theory . The decoupling of oxidative phosphorylation
may be involved in involuntary weight loss. The work of Romestaing et al. Showed that weight
loss following the development of a steatosis was associated with a decrease in the ATP / O2
ratio . Mitochondrial dysfunctions could therefore have a direct effect on the protein
degradation observed during cancer cachexia. In addition, systemic inflammation caused by
the development of the tumor can also affect mitochondrial bioenergetics.
The works of Hochwald et al. were among the first to suggest an alteration of muscle
mitochondrial metabolism by demonstrating a decrease in ATP concentration in the
gastrocnemius of rats with MCA sarcoma . The recent works of Constantinou and col. confirmed
this hypothesis by demonstrating in vivo by 31P nuclear magnetic resonance (NMR) a reduction
in the rate of synthesis of ATP on the lower limb of mice with Lewis pulmonary carcinoma
compared to its healthy mice . This work suggested a decrease in the ability to synthesize
ATP during cancerous cachexia through decoupling proteins such as UCP3 . This decrease in
ATP synthesis could also be explained by alterations in the functioning of the mitochondrial
respiratory chain .
Julienne and col. in 2012 studied the mitochondrial activity of skeletal muscles in murine
models of cancer cachexia based on the ATP / Oxygen ratio and concluded that muscular
mitochondrial oxidative capacities were reduced by decreasing the activity of complex IV,
responsible for muscle loss and accumulation of free fatty acids in muscle (myosteatosis)
since less oxidized by mitochondria. They also observed that the expression of MURF1 and
MAF-Box (proteolytically active ligases) was increased in the muscle of rats with cancers .
Cancerous cachexia affects about 80% of patients with advanced cancer and increases their
prognosis by increasing their morbidity and mortality. It is defined as a loss of lean mass
especially muscular resulting from an imbalance between proteolysis and proteogenesis. It
has been shown that the presence of cancer in the murine model favors the development of
myosteatosis, which is linked, among other things, to alteration of muscle lipases and a
decrease in mitochondrial activity, the consequence of which is a decrease Of the oxidation
by the latter of free fatty acids which would consequently accumulate in the muscle of mice
suffering from cancer. It is known that this myosteatosis then induced is responsible for an
insulin resistance participating in a decrease in proteogenesis and therefore in weight
loss.
The main objective here is to confirm this same hypothesis in humans by studying the
influence of cachexia on muscle mitochondrial activity as a marker of myosteatosis in
patients with cancer of the upper air-digestive tract, cachectic or not, and non-cachectic
controls.
Patients will be recruited from ENT and Cervico-facial Surgery at CHU Gabriel Montpied in
Clermont-Ferrand.
Inclusion of patients in 2 groups:
- Group K +: cancer of the upper aerodigestive tract with or without cachexia
- Group K-: absence of cancer and absence of cachexia The recruitment arrangements for
the K + group will be made through a Multidisciplinary Consultation Meeting (RCP), the
decision of which is an exclusive or non-exclusive surgery. Before the protocol is
realized, during the preoperative consultation, an information sheet is given to the
patient and an informed consent in 2 copies is signed after a period of reflection of
the patient of 7 days.
At inclusion, the day before the surgery, patients benefit from a dual general and
nutritional evaluation:
- Collection of epidemiological data: age, medical and surgical history (cardiac
insufficiency, renal insufficiency, respiratory insufficiency, COPD, coronary artery
disease), ethyl intoxication (gram / day), tobacco poisoning (package / year), usual
treatment, tumor characteristics for group K+ (histological type, location, tumor
stage, nature of treatment), indication and nature of surgery for group K-,
pre-operative renutrition program for K + group (food supplements, enteral or
parenteral feeding )
- Clinical nutritional evaluation: bodyweight (kg), weight loss in the last 6 months
(kg), height (m), body mass index (BMI in kg / m²) (NPH), Short Physical Performance
Battery (SPPB), muscle strength measurement by dynamometry (Newton), Impedancemetry
(Kyle index, Janssen index)
- Myostéatosic and nutritional morphological evaluation by, respectively, Hounsfield Unit
and Muscular Mass Index at L3 level (cm² / m²) by abdominal tomodensitometry for the K
+ group (carried out in the cancer extension imaging balance)
Patients will benefit from 4 organic samples during the planned surgery (carcinological
surgery for Group K +, cervical surgery for Group K-):
- Carrying out a muscle biopsy of the SCOM muscle with a total volume of about 300 mg,
without resorting to an additional invasive act. This sampling is immediately divided
into 6 samples and placed in a liquid nitrogen tank for transport to the place of
storage. It will then be frozen at -80 ° C.
- Carrying out a blood sample according to the following conditions: 1 dry tube, 1 EDTA
tube and 2 dry tubes for biochemistry The dry tube and the EDTA tube will be
immediately put in ice for transport to the storage site. It will then be immediately
centrifuged and then frozen at -80 ° C. The two dry tubes for biochemistry will be
transmitted to the laboratory of biochemistry of the CHU Gabriel-Montpied.
- Carrying out a tumor biopsy with a total volume of approximately 200 mg without
resorting to an additional invasive procedure. This sampling is immediately divided
into 4 samples and placed in a liquid nitrogen tank for transport to the place of
storage. It is then frozen at -80 ° C (only for K + Group).
;
Status | Clinical Trial | Phase | |
---|---|---|---|
Recruiting |
NCT05603585 -
Optimal Protein Supplementation and Early Exercise In Mechanically Ventilated Patients
|
N/A | |
Recruiting |
NCT06206785 -
Resting Energy Expenditure in Palliative Cancer Patients
|
||
Enrolling by invitation |
NCT05028192 -
Mitochondria Preservation by Exercise Training: a Targeted Therapy for Cancer and Chemotherapy-induced Cachexia
|
||
Completed |
NCT01696604 -
A Study to Evaluate the Safety, Tolerability, Pharmacokinetics, and Pharmacodynamics of GSK2849466 in Healthy Male Subjects
|
Phase 1 | |
Recruiting |
NCT04627376 -
Multimodal Program for Cancer Related Cachexia Prevention
|
N/A | |
Completed |
NCT02567773 -
Safety, Tolerability, Pharmacokinetic (PK), and Pharmacodynamic Study of GSK2881078 and Study to Evaluate the Effect of CYP3A4 Inhibition on PK of GSK2881078
|
Phase 1 | |
Completed |
NCT00866970 -
Safety, Efficacy and Pharmacokinetics of ALD518 in Patients With Non-Small Cell Lung Cancer-related Fatigue and Cachexia
|
Phase 2 | |
Active, not recruiting |
NCT00710632 -
Screening to Predict Weight Loss in Patients With Cancer
|
N/A | |
Completed |
NCT00031785 -
Megestrol in Treating Patients Who Are Undergoing Radiation Therapy for Lung Cancer
|
Phase 3 | |
Withdrawn |
NCT02017925 -
Pulmonary Rehabilitation in Improving Lung Function in Patients With Locally Advanced Non-Small Cell Lung Cancer Undergoing Chemoradiation
|
N/A | |
Recruiting |
NCT01829880 -
Impact of Body Composition on Bisoprolol and Ramipril Pharmacokinetics in Patients With Chronic Heart Failure
|
N/A | |
Completed |
NCT01419145 -
A Feasibility Study of Multimodal Exercise/Nutrition/Anti-inflammatory Treatment for Cachexia - the Pre-MENAC Study
|
N/A | |
Completed |
NCT01692990 -
Study on the Effect of Fish Oil and Appetite
|
Phase 0 | |
Terminated |
NCT00962234 -
Metabolism of Lipids in Advanced Cancer
|
N/A | |
Completed |
NCT00994669 -
Development of a Non-invasive Assessment of Skeletal Muscle Loss in Cancer Patients
|
N/A | |
Terminated |
NCT00851448 -
Safety, Tolerance and Efficacy of an Oral Nutritional Supplement in Lung Cancer Patients
|
N/A | |
Completed |
NCT01015274 -
Non-invasive Assessment of Skeletal Muscle Loss in Cancer Patients
|
||
Completed |
NCT00972634 -
Computerized Questionnaires in Assessing Symptoms, Pain, Depression, and Physical Function in Patients With Metastatic and/or Advanced Locoregional Cancer
|
N/A | |
Terminated |
NCT00535015 -
Safety and Efficacy Study of Betamarc to Treat Loss of Weight and Appetite in Non-Small Cell Lung Cancer
|
Phase 2 | |
Terminated |
NCT00558558 -
Haelan and Nutrition in Cancer Patients
|
Phase 2 |