Week 1 MC Questions PDF

Summary

This document provides an overview of non-alcoholic fatty liver disease (NAFLD) and metabolic dysfunction-associated fatty liver disease (MAFLD). It discusses the pathophysiology, clinical features, and diagnostic criteria of these conditions and compares the differences between diagnostic approaches. The document also includes information regarding counteracting the pathophysiology of MAFLD and an approach to hepatic investigations.

Full Transcript

Liver Pathology Part III

MAFLD – e-learning P1 BMS 200
Week 1
Non-Alcoholic Fatty Liver Disease (NAFLD) – Recall from BMS 150

Steatosis in the absence of significant alcohol consumption
○ Most common cause of liver disease in US
○ Estimated prevalence of up to 40% of the population
Forms include:
○ Simple hepatic steatosis and steatosis complicated by inflammation
These show fewer long-term complications unless they progress to
NASH
Progression to NASH is uncommon, and it is unclear why some
progress
○ Non-alcoholic steatohepatitis (NASH)
Progresses to cirrhosis in 10 – 20% of cases
In those that progress to cirrhosis, the incidence of liver cancer can
be as high as 1-2% per year
Non-Alcoholic Fatty Liver Disease (NAFLD) –
Recall from BMS 150
Pathologic findings:
○ Initially hepatocyte ballooning, lobular inflammation, and steatosis (fat
accumulation in hepatocytes)
○ With progressive disease there is steadily more fibrosis, eventually
leading to cirrhosis
○ Strongly associated with obesity and the metabolic syndrome
Pathophysiology:
○ “two-hit” model, involving 1) hepatic fat accumulation and 2) increased
oxidative stress
Free radicals cause lipid peroxidation of the accumulated
intracellular fat
○ Obesity seems to be associated with reduced intestinal barrier function
🡪 increased inflammation in the liver
Movement of microbes from the gut into the portal circulation
 General cirrhosis pathogenesis – Recall from
BMS 150
Cirrhosis definition:
Diffuse remodeling of the liver into
parenchymal nodules surrounded by
fibrous bands and variable degree of
vascular shunting
Pathogenesis (most likely theory):
Stellate cells become activated & differentiate into highly fibrogenic
myofibroblasts
▪ Activated by inflammatory cytokines (eg. TNF-alpha), toxins,
reactive oxygen species
▪ Signals implicated include PDGF, TGF-beta, IL-17
▪ Deposit ECM into the space of Disse 🡪 fibrous septae formation
in regions of hepatocyte loss
Kumar et. al., Robbins and Cotran Pathologic Basis of Disease 9th ed.
 Non-Alcoholic Fatty Liver Disease (NAFLD) – Recall from BMS
150
> 80% < 20%
~ 11% of NASH (2%?)

NAFLD – a dynamic spectrum of liver pathology:
A. Healthy liver.
B. Simple steatosis (arrow shows fatty hepatocyte)
C. Nonalcoholic steatohepatitis (NASH); ballooned hepatocyte (arrow) near central vein
with adjacent blue-stained pericellular fibrosis (arrowheads).

Non-Alcoholic Fatty Liver Disease (NAFLD) –
Recall from BMS 150
Clinical features:
○ Usually asymptomatic until hepatic failure (due to
cirrhosis)
clinical findings usually due to accompanying
atherosclerotic disease/diabetes
Cardiovascular disease a frequent cause of
death
○ Fatigue and right-sided abdominal pain can occur
in some
○ Increased risk of hepatocellular carcinoma
Diagnosis:
○ Liver enzymes alone are poorly reliable
○ Scores calculated from age, BMI, fasting glucose,
AST, ALT are helpful for gauging degree of
inflammation and fibrosis
○ Detection of fibrosis via imaging or biopsy for
definitive diagnosis
Kumar et. al., Robbins and Cotran Pathologic Basis of Disease 9th ed.
MAFLD vs NAFLD
MAFLD = “metabolic dysfunction associated fatty liver disease”
How does MAFLD differ from NAFLD in terms of diagnostic criteria?
Both require a 5% “level” of hepatic steatosis
○How is this diagnosed? For discussion later
NAFLD diagnosis requires exclusion of other causes of liver
disease (i.e. significant alcohol use, hemochromatosis, etc.)
○negative criterion
MAFLD diagnosis requires the presence of metabolic drivers of
hepatic steatosis and inflammation, which can be any one of the
following positive criteria:
○T2DM
○Obesity (this can be a tricky thing to define)
○A “metabolic dysfunction” composite score (see next slide)

Gofton et. Al., “MAFLD: How is it different from NAFLD?”, Clin Mol Hepatol, 2023; 29 (Supp)
MAFLD and NAFLD Diagnostic Criteria
* Metabolic risk abnormalities for MAFLD – 2
out of 7 (these are FYI)
Elevated waist circumference
Blood pressure > 130/85 (or BP meds)
Elevated plasma triglycerides (> 1.7 mmol/L)
MAFL Decreased HDL cholesterol
Prediabetes (to cover in future diabetes lecture)
D Elevated HOMA insulin resistance score (to
cover in future diabetes lecture)
Elevation in CRP

Looks a lot
like the
metabolic
syndrome
NAFL criteria
D

Adapted from Gofton et. Al., “MAFLD: How is it different from NAFLD?”, Clin Mol Hepatol, 2023;
Why do the diagnostic differences between NAFLD and MAFLD matter?
Clearer diagnoses:
Patients could have non-alcoholic steatohepatitis AND have a chronic viral hepatitis…
with the viral hepatitis complicating NASH
○ What do you call that?
Someone with MAFLD who also has hep B or hep C just has MAFLD complicated
with a viral hepatitis
○ No negative criteria 🡪 diagnostic clarity
Better identification of patients who need more aggressive/targeted management
Studies seem to indicate that a MAFLD diagnosis is more closely linked to the
development of worsened liver fibrosis

Gofton et. Al., “MAFLD: How is it different from NAFLD?”, Clin Mol Hepatol, 2023; 29 (Supp)
Why do the diagnostic differences between NAFLD and MAFLD matter?
Identification of those with higher “wear and tear” due to “metabolic dysregulation”
A MAFLD diagnosis increases the risk of the following conditions over a NAFLD
diagnosis (although sometimes only slightly)
○Subsequent development of diabetes (in those who are not
already diabetics)
○Chronic kidney disease
○Worsened lung function (and worsened complications after
COVID infection)

Gofton et. Al., “MAFLD: How is it different from NAFLD?”, Clin Mol Hepatol, 2023; 29 (Supp)
Why do the diagnostic differences between NAFLD and MAFLD matter?

Under-reporting of alcohol ingestion
It is estimated in some cohorts that up to 30% of those diagnosed with
NAFLD actually do consume alcohol regularly and in clinically significant
quantities (as assessed with fancy biochemistry tests)
○ There can be serious stigma in some cultures about frequent alcohol
consumption (and a regular stigma in most cultures)
○ This leads to patient under-reporting
Not an issue with MAFLD diagnostic criteria
A small caveat:
A small proportion of those with a fatty liver do not fulfill ANY of the
other criteria for MAFLD… and therefore would have NAFLD, but not
MAFLD
○ Approximately 5% of those with fatty livers
Gofton et. Al., “MAFLD: How is it different from NAFLD?”, Clin Mol Hepatol, 2023; 29 (Supp)
Is a MAFLD diagnosis “redundant”?

There is little argument that MAFLD results in worsened
mortality compared to NAFLD… but is that just because those
with MAFLD also have metabolic syndrome, obesity, or
diabetes on top of steatosis?
○Why not just say someone has NAFLD as well as metabolic
syndrome or obesity or diabetes?
This is a good question, but perhaps not a very clinically-
relevant one
○Simply put, MAFLD is a more straightforward diagnosis that helps
guide the clinician to more comprehensive treatment sooner
○Studies will likely address this question in the future

Gofton et. Al., “MAFLD: How is it different from NAFLD?”, Clin Mol Hepatol, 2023;
MAFLD – some extra pathophysiology
Why do obesity, insulin
resistance, and fatty liver tend
to cluster together?
Insulin resistance 🡪 increased
FFA liberation from
adipocytes 🡪 conversion into
triglycerides and storage in
hepatocytes
Elevated glucose and insulin
levels 🡪 hepatic triglyceride
synthesis

Greenberger’s Current Diagnosis & Treatment in Gastroenterology, Hepatology, &
 MAFLD – some extra pathophysiology
Why do obesity, insulin
resistance, and fatty liver tend to
cluster together?
As intra-abdominal fat increases,
adiponectin levels tend to
decrease
○Adiponectin is an adipokine
released by visceral fat
○It increases glucose
utilization and fatty acid
oxidation
○Studies show adiponectin
levels tend to be lower in
patients with fatty liver and
steatohepatitis
Greenberger’s Current Diagnosis & Treatment in Gastroenterology, Hepatology, &
 MAFLD – counteracting pathophysiology
What works in MAFLD?
○ Weight loss through lifestyle modification – the best
therapeutic option so far!
Those that are obese or have type II diabetes can
reduce steatosis with weight reduction
Exercise and weight loss can improve fibrosis and
steatosis
○ No approved meds yet, though some do improve
inflammation and steatosis in patients
Thiazolidenedione medications (i.e. pioglitazone)
improve insulin sensitivity and seem to increase
adiponectin secretion
Incretin agonists improve insulin secretion and help
with weight loss in diabetes
○ Vitamin E seems to reduce oxidative stress in hepatocytes,
and is linked to reduced steatosis and inflammation in
patients with steatohepatitis

Greenberger’s Current Diagnosis & Treatment in Gastroenterology, Hepatology, &
An Approach to Hepatic
Investigations
Blood Labs: Liver Enzymes, Liver Function Tests, and
others

Application of Selected Tests to Liver Pathology

E-learning P2 BMS 200
Laboratory Analysis of the Liver

Learning outcome:
Compare and contrast how the different transaminases (ALT, AST), ALP,
bilirubin, albumin, and PT/iNR can be used to assess etiology and extent of liver
damage
Liver enzyme tests:
○ ALT & AST
○ GGT, ALP, & 5’ nucleotidase
Liver function tests:
○ Albumin & PT/iNR
○ Bilirubin
Direct (conjugated) and indirect (unconjugated)
Selected disease-specific tests
General Patterns and Concepts

Damage to hepatocytes or to the biliary tree causes enzymes that
are normally found within the cell or attached to cell membranes to
“leak” into the bloodstream
○ When serum levels of these enzymes increase (liver enzyme tests), it indicates
damage, but says nothing about liver function
The function of the liver can be crudely evaluated by considering
three major parameters in the blood:
○ Serum albumin (maintains oncotic pressure, helps transport hydrophobic substances) –
decreases as hepatic function is impaired
○ Bilirubin (breakdown product of heme, excreted into the biliary tree) – increases as hepatocytes are
damaged or sometimes when hepatic function is impaired
○ “Time to clot”, known as the PT/INR (the liver produces coagulation proteins)
– increases as hepatic function is impaired
Elevated PT/INR = longer time to form a clot = less coagulation
proteins
General Patterns and Concepts
In situations where hepatocytes suffer damage but the biliary tree does not experience obstruction or
damage:
○ ↑↑ AST and ALT
○ normal or mildly elevated ALP or GGT
○ Known as a hepatocellular pattern
In situations where the primary problem is obstruction/inflammation of the biliary tree
(intrahepatic or extrahepatic bile ducts or the wall of the gallbladder):
○ ↑↑ ALP and GGT
○ Normal or ↑ AST and ALT
○ Known as a cholestatic pattern
Liver Enzyme tests - ALT

ALT = alanine aminotransferase
Found mostly in the cytosol of hepatocytes
○ few other cells express significant amounts, main other source is
the kidney (but far more in hepatocytes)
○ Therefore elevations in ALT are relatively specific for hepatocyte damage
Small amounts of ALT are released into the bloodstream in
healthy individuals, but significant elevations usually indicate
hepatocyte damage
○ FYI – normal level varies from lab to lab, but usually ranges from
10 to no more than 40 IU (a little higher for men)
○ Half life of a few days
Liver Enzyme tests - AST

AST = aspartate aminotransferase
Found in the cytosol and mitochondria of hepatocytes
○ Many other cells containg AST – elevations in the serum could
be due to hepatic, skeletal myocyte, cardiomyocyte, renal, or
pancreatic injury
○Therefore elevations in AST are less specific for hepatocyte damage
As with ALT, low levels of AST are present in the blood of
healthy individuals, but significant elevations usually indicate
hepatocyte damage
FYI factoids:
○ Normal level similar to ALT, 10 to no more than 40 IU, half life is
a few days
○Less AST than ALT in the cytosol 🡪 if hepatocyte membrane is
disrupted, usually more ALT is released than AST
Liver Enzyme tests - ALP

ALP = alkaline phosphatase
Found at/around the canalicular membrane of hepatocytes
○ ALP is also expressed by bone (during growth or fracture or other
changes to bone) and by the placenta
Therefore, levels are increased during pregnancy or
childhood/adolescence
○ During damage to the biliary apparatus ALP is released to the
bloodstream
Includes cholestasis in the intra- and extrahepatic biliary tree, and
sometimes during cholecystitis (25%)
Assorted ALP FYI info
○ Normal level ranges between 35 – 100 IU (varies widely in normal
population)
Liver Enzyme tests – GGT & 5’ nucleotidase

GGT = gamma-glutamyl transpeptidase
GGT is found in the cell membranes of a wide variety of cells (hepatocytes
& cholangiocytes, kidney, pancreas, spleen, heart… many)
○ Although sensitive, it is not specific – many people have an isolated elevated
GGT and no significant pathology
○ Alcohol-use disorder can result in disproportionate increases in GGT vs ALP…
one has to be aware of the non-specific nature of GGT, though, before
stigmatizing the patient
5-NT is also found in a wide variety of cells, but increases usually mean
hepatobiliary disease (more specific than GGT)
Both of these labs are meant to “double-check” whether an elevation of
ALP means hepatobiliary disease
○ GGT normal levels: 9 – 85 U/L 🡪 this is the preferred “double check” test for ALP
elevations
○ 5’ NT normal levels: 0 – 18 U/L (varies with age)
Liver Function tests - bilirubin
Where does bilirubin come from?
(preview for hematology) :
Hemoglobin is degraded to the
“heme” portion and the “globin”
portion
○ “globin” portion is just a protein – it
gets metabolized by macrophages
○ “heme” portion is a porphyrin ring
structure… tougher to break down
Macrophage degrades heme to
biliverdin 🡪 unconjugated bilirubin
(hydrophobic)
○ Unconjugated bilirubin is carried
(via albumin) to the hepatocyte…
The hepatocyte conjugates bilirubin
to a soluble form (bilirubin
glucuronide)
Rubin’s Pathology: Mechanisms of
th
Liver Function tests - bilirubin

Two forms of bilirubin measured:
○ Unconjugated bilirubin (indirect) – bilirubin in the serum that has
not yet been complexed to glucuronide
Due to large hematomas, disorders where large numbers of RBCs
are damaged
Due to disorders that affect bilirubin conjugation
Some increase can be seen with hepatocyte damage
○ Conjugated bilirubin (direct) – the hepatocyte has conjugated
bilirubin, but it has “leaked back” into the bloodstream because of:
Blockage within the biliary system
Inability to transport conjugated bilirubin into canaliculi (rare)
Damage to hepatocytes
Liver Function tests - bilirubin

Assorted bilirubin facts:
Texts/papers differ on whether this is a “function” test or an “enzyme” test
○ Most of the time, an elevation in serum bilirubin is due to hepatocyte damage or impaired
bile flow… so it’s similar to AST/ALT/GGT/ALP in that way
○ However, sometimes elevated serum bilirubin is a deficit in liver function (i.e. Gilbert’s
syndrome)
○ Most texts group bilirubin with the “function” tests or group it independently from “function”
or “enzyme” tests
Hepatocytes are able to rapidly conjugate bilirubin – the rate-limiting step is
transport of bilirubin into the canaliculi
○ This means when a hepatocyte is damaged, conjugated bilirubin increases in the serum more than
unconjugated bilirubin
○ Elevations in only unconjugated bilirubin is almost always an RBC problem or an enzyme
deficit in conjugation
Liver Function tests - albumin

Albumin is a protein synthesized by the liver – major functions
include:
○ Carrier for hydrophobic molecules (like bilirubin)
○ Establishes oncotic pressure in the capillary
Decreases in serum albumin are usually caused by:
○Long-term deficiency in production – chronic liver diseases or serious
protein malnutrition (can’t build protein if you don’t eat it)
○ Loss of albumin from a variety of organs (usually the kidney,
but there are others)
○ Accumulation of more extracellular fluid than usual – “dilutes”
albumin in the blood
Albumin has a pretty long half life (almost 3 weeks), so liver
dysfunction has to be present for a while before it drops
Liver function tests – PT/INR

Why such a weird name?
○ PT refers to the prothrombin time – the time it takes to clot using a specific
“branch” of the coagulation cascade (you’ll learn about this in hematology)
○ INR = international normalized ratio… it’s a mathematical correction that
standardizes the result between labs (often this test is just known as the
INR)
Increased PT/INR means that it takes longer to form a clot due to a
deficiency of coagulation factors in the blood
○ Ratio value – the normal PT/INR is 1
○ 1.5 roughly means it takes 50% longer for blood to clot than the lab’s
reference “normal”
The liver is the source of almost all serum coagulation factors, and
many depend on the presence of vitamin K
○ Therefore liver dysfunction or vitamin K deficiency can increase clotting
times
Liver function tests – PT/INR

PT/INR FYI factoids
INR increases fairly quickly after the liver’s synthetic capabilities
are compromised
○Half life of most coagulation factors range from
hours to a few days
○Therefore a better way to assess liver function
acutely than albumin
Bringing it all together – liver labs

*Most types of acute hepatocellular injury:
○ Both ALT and AST are very elevated, but ALT more than AST
○ ALP and GGT may be normal, but often modestly increased (elevated
less than 3X normal)
○ Not enough time for albumin to change, but both direct and indirect
bilirubin are often increased
If PT/INR increased, indicates severe damage
*Most types of chronic hepatocellular injury:
○ ALT and AST modestly increased, usually ALT > AST
○ ALP and GGT normal or modestly increased
○ Albumin often decreased, PT/INR and both
unconjugated/conjugated bilirubin increased
Decreased liver function is often a result of late-stage disease – early
disease often exhibits normal bilirubin, PT/INR, and albumin
Bringing it all together – liver labs

*Cholestasis:
○ AST and ALT are normal to moderately elevated
○ ALP and GGT are very elevated
○ Usually large increase in serum bilirubin, especially conjugated , but PT/INR and
albumin are normal
Other liver test patterns (FYI):
○ Cirrhosis – looks like chronic hepatocellular injury, except the AST:ALT ratio is often
2 or greater
○ Alcoholic liver disease – can resemble acute or chronic hepatocellular injury
(depending on stage and situation, except AST:ALT ratio is often 2 or greater and
often GGT is very elevated
○ Hepatocellular carcinoma, liver metastases – most tests are normal, but ALP is very
elevated
○ Gilbert’s syndrome – all liver tests are normal except for an elevated unconjugated
bilirubin (conjugated normal)
Bringing it all together – liver labs
Assorted tests beyond general liver labs that are useful in diagnosing
hepatobiliary disease covered in BMS thus far
Disorder Liver Lab Pattern *Other labs

Hepatitis A Acute hepatocellular Anti-HepA IgM

Hepatitis B Acute or chronic hepatocellular 🡪 HBeAg, HBV DNA, HBsAg
cirrhosis Anti-HBe, anti-HBs, anti-HBc

Hepatitis C Chronic hepatocellular 🡪 cirrhosis HCV RNA

Autoimmune hepatitis Usually chronic hepatocellular, Anti-smooth muscle antibodies, ANA
sometimes flares with acute Rarely anti-cytochrome antibodies
hepatocellular, LFTs often N

Primary biliary ALP, GGT most elevated 🡪 cirrhosis Anti-mitochondrial antibodies
cirrhosis/cholangitis pattern
Primary sclerosing ALP, GGT and AST most elevated early p-ANCA (associated with ulcerative colitis)
cholagnitis (looks like cirrhosis due to cholestasis)

Other labs FYI
Liver imaging – FYI review

Simple ultrasound is the best way to examine the larger biliary
ducts, gallbladder initially
MRI/CT can assess masses and MRI can give some information
about fibrosis
○MRI can also provide more detailed views of the
biliary system (known as MRCP)
Liver biopsy is necessary to evaluate and stage fibrosis or
cirrhosis, and is the definitive test for liver disease that is difficult
to diagnose non-invasively
Liver investigations in MAFLD - FYI
Most common liver disease – but expensive to diagnose
definitively
How is steatosis > 5% diagnosed? Tough question
○ Elastography assesses fibrosis well, but can have false positives
can be done via ultrasound (cheaper, accurate) and MRI (not as much
data, emerging)
○ MRI is best at diagnosing steatosis precisely
○ Rarely biopsy – biopsy definitively diagnosis steatosis and fibrosis
Since we can’t screen everyone using ultrasound
elastography (Fibroscan) or MRI, patients are referred for
imaging when:
○ Fulfill the metabolic criteria of MAFLD
○ Elevation in liver enzymes – elevations in ALT most common, early
chronic hepatocellular pattern
○ They are scored using (usually simple) blood tests and other
clinical data – the scoring systems are used to predict presence of
fibrosis
MAFLD screening tests (FYI)

FIB-4 score – use the following to calculate:
○Patient age, AST, ALT, platelet count
NAFLD fibrosis score
○Patient age, BMI, presence of insulin
resistance/diabetes
○AST, ALT, platelet count
There are others
○Some, such as the ELF, assess molecular markers
that are not part of the “typical” blood tests that most
labs run frequently (but Lifelabs carries it)
Etiology of Eating Disorders
Anorexia nervosa and bulimia are
complex eating disorders with multiple
factors contributing to their etiology
Psychological factors: OCD traits, cognitive rigidity, emotion sensitivity
and impulsivity as well as history of developmental stressors/ trauma and
challenging interpersonal relationships
Body dissatisfaction is important as well as some
behavioural factors like engaging in diets, and
particular athletics
Accurso 2019
Etiology of Eating Disorders
Anorexia nervosa and bulimia are complex eating disorders
with multiple factors contributing to their etiology
Biological factors:
50% due to multiple genetic effects
Dysfunction in serotonin, dopamine, norepinephrine, opioid and
cholecystokinin systems
Hypothalamic regulation (amenorrhea can precede weight
loss!)
Some research suggests changes within peripheral satiety
network
Vicious cycle as malnourishment can exacerbate the comorbid
psychiatric conditions and further the behaviours

Accurso 2019
Etiology of Eating Disorders
Anorexia nervosa and bulimia are
complex eating disorders with multiple
factors contributing to their etiology
Sociocultural factors:
Idealization of thinness
Triggers:
Dieting is often a precipitating factor for triggering
ED
Illness leading to weight loss – especially true for AN
Accurso 2019
Complications of Eating Disorders
All-cause mortality 2-10x higher then general population
Independent of weight:
Vitamin and mineral deficiencies
Stunted growth (if across lifespan)
Reduced gastric motility (more discomfort and more food avoidance)
Consequences of malnutrition:
Bradycardia, hypotension, orthostasis, hypothermia,
Metabolic alkalosis, hypochloremia, increased bicarbonate
Osteopenia
Myopathies
Consequences of purging:
Esophageal tears, intractable vomiting, hematemesis
Metabolic acidosis (abuse of laxatives), hypokalemia
cardiomyopathies (d/t specific vomit inducers)

Accurso 2019
Pathogenesis of Obesity,
Part 1

In-person Class 1 BMS 200
Week 1
References:
REFERENCE:

Oussaada SM, van Galen KA, Cooiman, MI, Kleinendorst L, Hazebroek EJ, van Haelst MM, Ter Horst
KW, Serlie MJ. The pathogenesis of obesity. 2019;92:26-27.
https://doi-org.ccnm.idm.oclc.org/10.1016/j.metabol.2018.12.012
von Loeffelholz C, Birkenfeld AL. Non-Exercise Activity Thermogenesis in Human Energy Homeostasis.
Endotext [Internet]. MA. 2022 https://www.ncbi.nlm.nih.gov/books/NBK279077/
O’Rahilly S, Farooqi I. Pathobiology of Obesity. In: Loscalzo J, Fauci A, Kasper D, Hauser S, Longo D,
Jameson J. eds. Harrison's Principles of Internal Medicine, 21e. McGraw Hill; 2022. Accessed July 13,
2023.
https://accessmedicine-mhmedical-com.ccnm.idm.oclc.org/content.aspx?bookid=3095&sectionid=2654
45670
Review from 150: Insulin Resistance & Obesity
Most important environmental risk factor for insulin resistance is
obesity
○ Central obesity seems to be more crucial
○ A separate risk factor from obesity is lack of exercise
Most cases of insulin resistance are caused by a combination of
genetic and environmental risk factors…
○ … but don’t forget that T2DM is highly heritable
○ Thought that about 5% of population-wide variance in body weight is due to
genetic causes, but environment-gene interactions make this very difficult to
study
Review from 150: Obesity FAQs
Do obese people eat more?
○ Often, but not always
In studies that do not record exact caloric intake, often there is a poor
association between body weight and questionnaire-reported caloric
intake
In studies that record caloric intake more closely, the association is
better
Obese people and those with glucose intolerance often have
impaired satiety mechanisms – i.e. poorly-characterized leptin
resistance
Do obese people “burn less energy”?
○ This is a complicated question:
In states where weight loss is not occurring, the obese person seems to
use more calories than someone who is lean but may use less calories than
someone who is lean during weight loss states
Many obese people do have reduced BMR, though most don’t
Literature still developing around this area
Review from 150: Regulation of body weight and appetite

Satiety signals:
Leptin, GLP1, CCK,
PYY, vagal
afferents

“Hunger”
signals:
Ghrelin (released
by the stomach
during fasting)

All of these act on
different nuclei in
the hypothalamus
Review from
150: Controllers
of appetite
Review from 150: Insulin Resistance and visceral
fat
Non-esterified fatty acids (NEFA) increase insulin resistance
○ More released from central fat than peripheral fat
○ Increased intracellular concentrations of NEFA cause serine phosphorylation of
insulin receptor – which inactivates it (tyrosine phosphorylation activates it)
Adipokines modify sensitivity of insulin receptor
○ Adipose tissue is endocrine tissue – protein hormones from fat cells (adipokines)
increase sensitivity of insulin receptor and increase activity of enzymes that oxidize
NEFA
Increased NEFA oxidation mediated by AMP-K, a protein kinase activated by
metformin
Anti-hyperglycemic adipokines: leptin, adiponectin (drops in T2DM)
Hyperglycemic adipokines: resistin, retinol-binding-protein 4
Pro-inflammatory cytokines also secreted by fat cells, and decrease
insulin receptor sensitivity
Visceral obesity, insulin resistance, and inflammation

This was briefly discussed in BMS 150 (next slide)
Visceral adipocytes:
○ Recruit macrophages and activate them 🡪 production of pro-
inflammatory cytokines (TNF-alpha, IL-6)
Expression of MCP-1 (a chemokine) brings monocytes into visceral
fat as well as production of pro-inflammatory cytokines by the
adipocyte
Elevated systemic levels of IL-6 🡪 increased production of CRP by the
liver
○ Insulin resistance in visceral adipocytes 🡪 increased concentrations
of free fatty acids 🡪 activation of DAMPs in many cells
increased production of pro-inflammatory cytokines
○ Pro-inflammatory cytokines cross-talk with intracellular signaling
cascades that lead to insulin resistance (serine phosphorylation of
the insulin receptor)

Kahn et. Al., J Clin Invest. 2019 Oct 1; 129(10): 3990–4000; doi:
Review from 150: Chronic Inflammation and obesity

Systemic inflammatory
effects of obesity
○ excessive lipid build-up can
stress the adipocyte (ROS)
○ free fatty acids in high
concentrations may bind to
PAMP-R within the adipocyte
both of the above can lead to As shown above, pro-
the production of IL-6 and inflammatory
TNF-alpha by the adipocyte cytokines lead to
insulin resistance, and
Review from
150: Insulin
Resistance and
visceral fat

4
9
Obesity - Definitions
What is overweight? What is
obesity?
○ BMI definition (most used):
Overweight 🡪 BMI ≥ 25 kg/m 2

Obesity 🡪 BMI ≥ 30 kg/m2

○ Waist:hip ratio for obesity
(sometimes used):
Men 🡪 ratio > 0.90
Women 🡪 ratio > 0.85

Advantages to
using each
definition?
Obesity - Definitions
EE = Energy expenditure
The total amount of energy we expend, measured in kcal/day
Consists of:
○ Resting metabolic rate (RMR) – metabolism of an individual at rest
Energy requirements of respiration, circulation, etc.
○Activity-related energy expenditure (AEE) – exactly what it sounds like
Exercise activity thermogenesis (EAT) – energy used during “dedicated
exercise”
Non-exercise activity thermogenesis (NEAT) – energy used when an
individual is moving, but “not exercising” 🡪 much larger component of
AEE
○Diet-induced thermogenesis (DIT) – increase in metabolic rate
associated with ingestion of food and post-absorptive heat production

Ousaada et. al., Metab Clin Exp. 92: 26
Energy expenditure breakdown

Model of human energy expenditure
components
○ Exercise-related physical activity is comparable to
exercise-related activity thermogenesis (EAT), while
spontaneous physical activity is comparable to non-
exercise activity thermogenesis (NEAT)
○ In most people, EAT is much, much less than
NEAT
In those who train regularly, it can be 15 – 30% of EE
(very regular, dedicated exercise)
2 hours of training/week – 1-2 % of inter-individual
variance
○ Note that parts of spontaneous physical activity are
beyond voluntary control, also called “fidgeting.”
fidgeting can consume between 100 – 800 kcal/day

Ousaada et. al., Metab Clin Exp. 92: 26 https://www.ncbi.nlm.nih.gov/books/
RMR

RMR = energy expenditure in an individual that is at rest and has not
recently eaten
Proportion of EE due to RMR varies between individuals
○ If sedentary, 60 – 75% of total daily EE
Main determinant of RMR is fat-free mass (FFM)
○ Main component of FFM is weight of skeletal muscle
○ also includes bone, visceral organs, extra-cellular fluid
RMR varies from 2 – 10% in the same individual
○ time of day, temperature season, etc. as well as errors in measurement
RMR varies much more between individuals, between 7.5 and 18%
○ Amount of FFM is the main determinant of inter-individual variability – about 62%
○ Over 25% of inter-individual variation in RMR is not well understood – assumed to
be genetic/molecular differences

Ousaada et. al., Metab Clin Exp. 92: 26
Components of daily EE

a) total EE expenditure b) EE per kg of FFM

Ousaada et. al., Metab Clin Exp. 92: 26
RMR vs. BMR
RMR has less stringent requirements than BMR
Basal metabolic rate (BMR):
○ Completely rested subjects in the morning, after 8 hours of sleep, fasting
for 12 hours, and at a room temperature of between 22 – 26 Celsius
○ 80% of variations in BMR are due to FFM variations (same as RMR)
RMR:
○ post-absorptive (i.e. not right after a meal) state at any time of day, at
rest
○ can vary from BMR by 10%

https://www.ncbi.nlm.nih.gov/books/
NEAT - generalities

NEAT = “portion of daily energy expenditure resulting
from spontaneous physical activity that is not
specifically the result of voluntary exercise”
○ variation can be up to 2000 kcal/day in two similar-sized
individuals
○ differences in occupations, leisure activities, molecular/genetic
factors, seasonal effects
○ The most variable aspect of energy expenditure on a
population basis
6-10% of EE in individuals with a sedentary lifestyle
up to 50% in highly active individuals (often those that are
standing or constantly moving around in their occupation)

https://www.ncbi.nlm.nih.gov/books/
NEAT – impact of diet and exercise
Measurement of NEAT is extremely complex, and studies vary
in terms of the impact of dietary changes
With overfeeding:
○ a significant minority of people will increase NEAT, to the point
where increased activity compensates for increased calories
consumed
○ the majority do not increase NEAT to compensate for over-feeding,
but total EE does still increase somewhat
With underfeeding:
○ RMR and NEAT both decrease in those that are inactive
20% weight loss 🡪 320 – 500 kcal/day reduction in EE
Due mostly to losses in FFM
○ Studies suggest that those that undergo exercise regimens with
underfeeding will not suffer as large a decrease in NEAT
https://www.ncbi.nlm.nih.gov/books/
Models of energy expenditure
Independent model of energy expenditure:
○ changes in EE are independent of the energy you “budget” for a behaviour
(NEAT, EAT)
○ Therefore, if you increase your NEAT & EAT, your total EE goes up… and it’s
“easier” to lose weight
Compensation/allocation model of energy expenditure
○ if you increase the energy expenditure in one area (EAT for example), you
decrease the expenditure in another (RMR or NEAT)
There is evidence for both models
Literature on weight loss also identifies two types of populations:
○ Compensator – if a compensator is overfed, then spontaneous physical activity
(NEAT) increases
○ Non-compensator – with overfeeding, less increase in EE, mostly due to less of
an increase in NEAT
57% of variability of spontaneous physical activity is believed to be a result of
inheritance/ genetics

https://www.ncbi.nlm.nih.gov/books/
 Exercise, diet, and insulin resistance
With weight loss due to caloric restriction, skeletal muscles seem to
become more efficient
○ not sure why – in rats, the following was found:
decreases SNS activity 🡪 decreased cardiovascular energy
expenditure and skeletal muscle energy expenditure
a molecular “switch” to isoforms of the myosin heavy chain that
expend less ATP
Reductions in the activity of the SNS as well as reductions in the
release of thyroid hormone with underfeeding also contribute to
decreases in EE (RMR)
Exercise causes translocation of GLUT-4 transporters to the
sarcolemma 🡪 improved glucose transport from blood to “busy”
muscle… impact on insulin resistance?
https://
www.ncbi.nlm.nih.g
ov/books/
Small Group Activity
Dive into the following paper:
○ https://www-sciencedirect-com.ccnm.idm.oclc.org/science/article/pii/S0026049519300071?via%3Dihub
○ It’s in your folder for today
Each group look specifically for the following information:
Group 1 – definition of diet-induced thermogenesis
Group 2 – do some macronutrients have different degrees of diet-
induced thermogenesis? Which ones have the highest?
Group 3 – does the temperature of food impact diet-induced
thermogenesis?
How do we regulate energy intake?

Homeostatic pathway – basically, stimulates eating
behaviour when energy stores are low, and suppresses
it in
○ “Major peripheral players” – sense when nutrients are
present or absent:
Adipose tissue, stomach, intestines, special senses, pancreas,
liver
These areas release the many, many endocrine signals that
modulate appetite and energy expenditure
○ “Major central players” – nerves and central nervous system
nuclei/connections that integrate this information and
translate it to a “sense of hunger”
Vagus nerve, brainstem, hypothalamic nuclei, cortex, aspects of the
limbic system
Ousaada et. al., Metab. Clin. Exp. 92, 26-36, 2019;
 Simple “CNS portion” of the homeostatic model
The arcuate nucleus of
the hypothalamus (ACN)
and the paraventricular
nucleus (PVN) seem
important in integrating
signals from the periphery
and the CNS
Note: AGRP
When nutrients are neurons also
secrete NP Y
present, POMC neurons
in the ACN release MSH 🡪 NP Y stimulates
PVN drives behaviour to When nutrients are present, AGRP neurons are inhibited 🡪 less
food intake
reduce eating and AGRP (separate
▪ AGRP blocks the MSH receptors (MC4R) mechanism)
increase energy
expenditure Therefore, satiety is mediated by increased MSH signaling,
either directly (MSH release) or indirectly (inhibition of AGRP
release)
Serotonin signaling and the homeostatic pathway

Serotonergic neurons in the midbrain (the raphe nucleus) project to
the arcuate nucleus as well as nuclei involved in the hedonic
pathway
○Increased serotonin signaling 🡪 activation of MSH neurons,
inhibition of AGRP/NPY neurons…
Impact on satiety?
○ Lorcarserin is a 5-HTc receptor agonist which can induce
weight loss in obese subjects
○ Signaling mechanisms are complicated and can involve
changes in serotonin release, modulation of serotonin
receptors, and upregulation/downregulation of serotonin
transporters
Quite a bit of human data that suggests that it is important
in satiety and weight regulation
Ousaada et. al., Metab. Clin. Exp. 92, 26-36, 2019;
How do we regulate energy intake?

Hedonic model – food intake is driven by reward pathways in the brain,
less by nutrient availability
○ Therefore, “less reliance” on feedback from peripheral sites that are exposed to
nutrients
However, this is likely an oversimplification, as nutrients and hormones
associated with nutrient intake have recently been found to directly influence
these brain areas
○ “Major central players” – many of these brain areas are important areas of the
CNS that mediate reward
Lateral hypothalamus, ventral tegmental area, nucleus accumbens (part of
ventral striatum), limbic system nuclei
Major neurotransmitters implicated are dopamine as well as the endogenous
opioids (enkephalins, endorphins, etc.)
○ Reward = pleasant sensations associated with eating, and that can often drive
eating in the absence of hunger

Ousaada et. al., Metab. Clin. Exp. 92, 26-36, 2019;
 Simple “CNS portion” of the hedonic model
Basic pathway:
The lateral hypothalamus projects
to a midbrain area, the ventral
tegmental area
Dopaminergic neurons in the
ventral tegmental area project
diffusely to the:
○ Nucleus accumbens
○ Amygdala
○ Prefrontal and orbitofrontal cortex
The VTA and NA also “talk back” to
the hypothalamus
Stogios et. Al., Nutrients 2020, 12, 3883;
How do we regulate energy intake?
Are the hedonic and homeostatic pathways separate?
○ Not at all… the hedonic pathway can impact the arcuate
nucleus
○ As well, activity (or lack of it) in the homeostatic pathway will
modulate the reward pathway
○ It seems like there is a disruption in the “balance” between
these two pathways in obese persons
○In the end, it appears that the “master integrator” is the
hypothalamus 🡪 it weighs information from both pathways to drive
eating behaviour

Ousaada et. al., Metab. Clin. Exp. 92, 26-36, 2019;
Energy intake and reward deficiency
Reward deficiency hypothesis
○ In all of us, delicious (often fatty, often sweet) food rewards us… the
reward is that adjective “delicious”, and all the positive feelings that
accompany eating something you like
Viewing it simply 🡪 hedonic pathway activation
○ Human evidence seems to indicate that lean subjects have better
activation of the reward pathway than obese subjects… therefore
it’s possible obese subjects are “reward deprived”…
Striatal dopamine release seems to be impaired in those who are
obese, with decreased D2/D3 receptor activation
○ In addition, those who are obese may anticipate reward more when
expecting a meal
In those who are obese, visual palatable food stimuli elicit greater
activation of the corticolimbic system
Increased reward expectation + decreased reward upon
eating 🡪 increased eating behaviour
Ousaada et. al., Metab. Clin. Exp. 92, 26-36, 2019;
 The “peripheral” homeostatic players

Adipose-derived:
Leptin, adiponectin,
resistin, retinol-binding
protein 4 (RBP-4), FGF-
21
GI-derived:
Stomach – ghrelin
(orexigenic)
Rest of the GI tract: GLP-
1, CCK, peptide YY,
oxyntomodulin
Pancreas:
Insulin
Interaction of
peripheral and central
players in the
homeostatic system
Importance of the hypothalamus
Surrounds the 3rd ventricle and the
CSF has some “crossover” with
molecules from the peripheral
circulation
Parts of the hypothalamus have a
“leakier” BBB
However, many peripheral signals
can impact other brain areas
(transported across BBB, i.e. insulin)
As well, the vagus synapses with the
hypothalamus, and is important in
relaying peripheral messages
 Segue - Types of fat
White fat – predominant form of adipose tissue, serves as a store of
triglycerides, and visceral adipose tissue (within the peritoneum, especially
omental fat) is an important endocrine organ
○ Storage vacuole – specialized phospholipid monolayer with local adaptations to limit
lipid peroxidation in the presence of free radicals
Brown fat – steadily decreases as we age, most found in infants in
particular areas of the body, main role is thermogenesis… and energy
balance?
○ Uncoupling protein in mitochondria “burns fat” (beta oxidation) without generating
ATP
○ Allows leakage of protons across inner mitochondrial membrane 🡪 heat production
○ Regulated by catecholamines (activated by beta-3 receptors)
○ Small fat vacuoles, many more mitochondria
White fat can “brown” with exercise, cold, sympathetic stimulation
○ Known as beige, or brite (brown-like) adipose tissue, looks like brown-fat cells
interspersed with white fat cells

Kahn et. Al., J Clin Invest. 2019 Oct 1; 129(10): 3990–4000; doi:
Location/characteristics of different types of
adipose tissue

Kahn et. Al., J Clin Invest. 2019 Oct 1; 129(10): 3990–4000; doi:
Homeostatic pathway mediators
Leptin:
Secreted by white adipocytes in the presence of insulin,
inhibited by catecholamines (so increased post-prandially)
Anorexigenic – suppresses NPY and AGRP, increases MSH
secretion from the arcuate nucleus of the hypothalamus
○ Those with congenital leptin deficiencies (very rare) become obese
due to hyperphagia
Discovered in 1994 and generated lots of excitement
○ The weight loss pill/molecule/injection!
○ Alas, it was not to be…
Obese subjects tend to have elevated leptin levels and the
hypothalamus is resistant to leptin
○ May be mediated by gliosis/inflammation in the hypothalamus, but yet
to be conclusively proven
Kahn et. Al., J Clin Invest. 2019 Oct 1; 129(10): 3990–4000; doi:
Homeostatic pathway mediators
Insulin:
Secreted by pancreatic beta-cells in response to elevated blood glucose
and some amino acids
Receptors for insulin are present in the ventral striatum, and are linked to
increased dopamine signaling in that area
○ Increased hedonic pathway signaling can amplify
homeostatic satiety signaling in the hypothalamus

Kahn et. Al., J Clin Invest. 2019 Oct 1; 129(10): 3990–4000; doi:
GI hormones and homeostatic appetite signaling

Ghrelin – released by cells in the
gastric fundus in response to
fasting
○ Stimulates hunger pathways (i.e.
amplification of AGRP and NP Y,
inhibition of MSH) likely by
stimulating the vagus nerve
There are receptors in the brain for
ghrelin, though
○ Only orexigenic hormone
○ Obesity:
Fasting levels of ghrelin are
negatively correlated with BMI
Obese patients might not suppress
ghrelin as effectively after a meal
GI hormones and homeostatic appetite signaling
We’ve seen all of these before in BMS 150 – secreted by
enteroendocrine cells in various parts of the GI tract (next slide)
CCK is released proximally in the small intestine (duodenum)
○ Slows gastric emptying, and increases sensations of satiety
GLP-1 and PYY are released more distally in the intestine
○ also slow gastric emptying and increase satiety
The brain expresses receptors for all of these enteroendocrine
hormones
○ However, in those with transection of the vagus, their satiety-
inducing effect is blunted or abrogated
Vagal afferents have receptors for all of these molecules
○Likely that much of the satiety effect is through vagus 🡪 NTS of
the brainstem 🡪 hypothalamus
Longo et. Al., Acta Diabetologica (2023) 60:1007–1017; doi: 10.1007/s00592
BMS 150 review
Cell Location Hormone (Stimulus) Main Hormonal Functions
Stomach, Somatostatin Generally “turns down” the release of hormones
D duodenum, (many different stimuli cause from nearby cells
pancreas release)
ECL – stomach ECL – histamine (stimulated by ECL – stimulates acid production
EC – stomach, vagus) EC – increased motility
EC, ECL small and large EC – serotonin, substance P
intestines (mechanical, neural, endo)
Gastrin (amino acids in the Increases secretion of stomach acid
G Stomach stomach, vagal stimulation,
gastrin-releasing peptide)

Small Intestine CCK (fats and proteins in the Pancreatic enzyme secretion, gallbladder
I* (especially duodenum) contraction, satiety
duodenum) Inhibits gastric acid secretion
Glucagon-like peptide (amino GLP-1 - Insulin secretion, satiety
acids & carbs) Inhibits gastric acid secretion
L* Small intestine
Peptide YY (distal small intestine) Peptide YY – inhibits gastric secretion & motility
– slows gastric emptying
Motilin (fasting) Migrating motor complex
Mo Small intestine

Secretin (acid in small intestine, Bicarbonate and water secretion from pancreas
S Small intestine especially duodenum) Inhibits gastric acid secretion, emptying
Cause and effect in regulation of appetite
Most human data shows association between a component of the homeostatic/hedonic pathway
and obesity
○ correlation does not necessarily imply causation
For example:
○ high-calorie snacking in lean subjects can change serotonin
transporter activity 🡪 impaired serotonin signaling
○ striatal dopamine signaling can be increased after bariatric surgery-
induced weight loss
○In these situations, weight loss or gain 🡪 changes in the pathways

Ousaada et. al., Metab. Clin. Exp. 92, 26-36, 2019;
Adipokines, insulin resistance, and obesity

Is adiponectin part of the homeostatic pathway?
produced mostly by white adipose tissue (particularly subcutaneous white fat),
but other tissues (muscle, bone, liver) can secrete it
As visceral fat and insulin resistance increase, adiponectin tends to decrease
Not enough evidence to say that it stimulates or inhibits appetite in humans
However, adiponectin does:
○ increase insulin sensitivity (our body will need less insulin secreted to act)
○ decrease fat accumulation in the liver and hepatic glucose output
Other adipokines can increase insulin resistance – in particular resistin (perhaps
more important in mice) and retinol-binding protein 4 (RBP-4)

Kahn et. Al., J Clin Invest. 2019 Oct 1; 129(10): 3990–4000; doi:
Summary of Obesity Complications
System Description
Dyslipidemia Increased TG and LDL, systemic inflammation 🡪 atherosclerosis

Fatty Liver Disease Ectopic fat in hepatocytes 🡪 fibrosis 🡪 cirrhosis
Type 2 Diabetes & insulin Visceral fat has a large impact on overall insulin sensitivity
resistance
PCOS/ Hypogonadism reduced testosterone in hypogonadism, likely due to related to insulin
resistance
Hormonal abnormalities in PCOS 🡪 increased androgen production (likely
due to insulin resistance) which is partially converted to estrogens by
visceral fat 🡪 dysregulated cycles

Skin Skin folds 🡪 increased risk of fungal infection
acanthosis nigricans

Cardiovascular Increase atherothrombotic vascular disease independent of diabetes type 2,
but still suspected to be related to insulin resistance

Harrison’s Principles of Internal Medicine 2022
Summary of Obesity Complications
System Description
Respiratory Dyspnea due to increased mass and increased pressure on thoracic
cage, increased adipose tissue around upper airways
GI Increased intraabdominal pressure can result in reflux esophagitis,
also increased risk of gallstones
Rheumatic Increased OA of knees/hips, but NO increase in RA or other
inflammatory joint disease
Cancer As BMI increases by 5 kg/m2 🡪 cancer mortality increases by 10%
Infections Increased susceptibility to bacterial wound infections and SARS-COV2
complications
CNS Increased risk of dementia & stroke (atherosclerosis)
Increased incidence of idiopathic intracranial hypertension

Harrison’s Principles of Internal Medicine 2022
How can the gut microbiota influence our food intake?
Introducing - Microbiota-Gut-Brain Axis (MGBA):
Composed of ANS, ENS, Spinal nerves, HPA axis, Immune system, Enteroendocrine
cells (EEC’s) and Microbiome
CNS receives and directs input via spinal nerves that connect with ENS
ENS receives and directs input via EEC’s which in terms can be modified by and can influence
the composition of the microbiome
HPA: it’s unclear the specific role that it plays but appears to be implicated in MGBA; chronic
elevations of cortisol are correlated with changes in gut microbiota function
Immune system facilitates a symbiotic relationship with commensal gut microbiota
Vagus nerve; directly detects intestinal distention via mechanoreceptors AND vagal
chemoreceptors connect to EEC’s; appear to be activated by changes in microbiota (animal
studies)

Von Son 2021, Longo 2023
How can the gut microbiota influence our food intake?
Possible mechanisms:
Changes in gut microbiota seen in obesity result in increased gut permeability that
allow LPS to enter circulation and trigger proinflammatory state within adipocytes
and systematically, which can then promote insulin insensitivity
Obese humans have increase in plasma LPS post high-fat meal versus lean humans
Enteroendocrine cells modify their secretions (serotonin, ghrelin, CCK, GLP-1, PYY)
in response to microbial metabolites like SCFA’s, these can then influence insulin,
gastric acid and bile acid secretion
Vagus nerve connects gut to nucleus of solitary tract which connects to
hypothalamic arcuate nucleus that is involved in energy balance
Vagotomy has been associated with changes in body weight

Von Son 2021, Longo 2023
How can the gut microbiota influence our food intake?

Possible mechanisms:
Gut microbiome produces SCFA’s,
GABA, dopamine and serotonin
SCFA’s have been implicated in
regulating satiety:
Increase PYY and GLP-1 secretion
Stimulating vagus nerve
Passing through BBB and inducing
anorexigenic signals
Reducing fat accumulation in adipocytes
Inducing thermogenesis and increased energy expenditure
Increase leptin production
HOWEVER, intervention studies failed to show benefit of supplementary
SCFA’s on weight in metabolic syndrome
Von Son 2021, Longo 2023
How can the gut microbiota influence our food intake?

Possible mechanisms:
Homeostatic Pathway Observations:
Bifidobacterium and Lactobacillus positively correlate with leptin (promotes satiety)
and negatively with ghrelin (promotes hunger)
Following H. pylori eradication increase in Bacteroidetes/ Firmicutes ratio
correlates with reduced ghrelin concentrations
However, CCK promotes reduced food intake via vagus nerve…
Human studies with CCK agonists fail to produce weight loss
Animal dysbiosis studies demonstrate reduced vagus nerve input to brain resulting
reduced CCK-induced satiety
Hedonistic Pathways Observations:
No direct connection between mesolimbic dopaminergic system (reward
system) and gut microbiota has been established, hypothesize that gut dysbiosis
may influence via causing generalized neuroinflammation

Von Son 2021, Longo 2023
Microbiota-gut-brain axis (MGBA) and GLP-1
Glucagon-like peptide 1 (GLP-1)
Released by intestinal epithelial enteroendocrine cells
Within the small intestine, this release is induced by presence of specific nutrients
Within the large intestine, this release is induced by the microbiota
Functions:
Increase insulin and reduce glucagon
Delay gastric emptying and promote pyloric contractions
Regulate appetite (suspected via vagus nerve)
Giving butyrate (SCFA) via IV 🡪 no influence on appetite (animal study) BUT via diet 🡪
decreases food intake

Longo 2023
Microbiota: Glucose and Insulin Metabolism
Human observations:
Transplant of microbiota from healthy patients into patients with
metabolic syndrome increases insulin sensitivity
Intestinal dysbiosis correlates with low grade inflammation in
obesity and in insulin resistance
Possible mechanism:
Gut microbiota induces increase intestinal permeability resulting in
LPS and fatty acid leakage and activation of TLR4 🡪 systemic
inflammation

Longo 2023
Microbiota: Energy Harvesting
Observations – what do we know so far?
Obese humans seem to have reduced counts of Bacteroidetes compared
to control (though debated in some studies)
Germ-free mice are leaner, but once allowed to be colonized increase
body fat by 50% and reduce insulin sensitivity
Gut microbiome genes present in obese mice and obese humans appear
to be involved in energy harvesting: digesting polysaccharides, transport
and intracellular metabolism
Fecal transplant from obese mice to germ-free mice results in transfer of
obese phenotype

Greiner 2011
Microbiota: Lipogenesis
Additional observations:
Increased energy harvest 🡪 increased fermentation 🡪
increased production of short chain fatty acids
(SCFA’s)
Obese humans have elevated SCFA production
Mice deficient in SCFA receptors are leaner than
controls

Greiner 2011
Pathogenesis of Diabetes,
Part 2

BMS 200
Week 1
The twin cycle hypothesis and
T2DM
What is the general model? What are the two cycles?

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
Background to the twin cycle
hypothesis
T2DM is thought to develop after many years of insulin
resistance
▪ Key aspect of the transition from early insulin resistance to loss of beta cell mass is
dysregulated lipid and glucose metabolism across multiple different organs
Liver, muscle, pancreas, skeletal muscle,
visceral adipose tissue, subcutaneous adipose
tissue
The twin cycle begins with early insulin resistance
▪ Easier to understand in a setting with:
Excess caloric intake (exacerbated by leptin
resistance, biopsychosocial factors… etc.)
Impaired ability to “clear” nutrients by skeletal
The twin cycle hypothesis and
T2DM
Start
here!

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
The “first” cycle – the liver
Studies in humans seem to indicate that diabetic patients have a “tipping
point”, where normal energy storage options are saturated
Where should we store our energy?
▪ Lots in subcutaneous fat
▪ Some in muscle (what is the energy storage form?)
▪ Some in the liver (what is the energy storage form?)
▪ A bit in visceral fat
Sensitive, effective insulin receptors aid “normal” energy storage in these
“healthy” energy depots

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi: 10.1097/XCE.000000
The “first” cycle – the liver
In the setting of positive energy/calorie balance and constant,
“longer-term” insulin secretion, skeletal muscle and
subcutaneous fat begins to experience insulin resistance
▪ This is the beginning of the first cycle
Circulating nutrients – in particular glucose – remain in the
bloodstream longer AND adipose tissue loses some of its
ability to convert these calories into stored triglycerides (due to
insulin resistance)
▪ The result is an increase in circulating free fatty acids (FFA) for long periods of time throughout the day
Elevated FFAs then have to be dealt with by the liver

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi: 10.1097/XCE.000000
 The “first” cycle – the liver
The liver seems to have 3 major
options when it is “drowning” in these
elevated levels of FFAs
▪ Burn the energy – (beta oxidation)
▪ Store the energy – hepatic steatosis (not good)
▪ Export the energy – VLDL production
Recall – what are the
characteristics of VLDL?
What is its goal?
What is its life cycle?
Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
Summary –Endogenous Pathway
Endogenous
HDL
Lipoprotein Liver
synthesis
Apoprote Initial VLDL
ins from lipoprotein (ApoB-100, ApoA-V,
(key apoproteins) ApoC-II)
HDL

LD Intermediate IDL (ApoE, ApoB-100)
VLD IDL lipoproteins ↓
L L (key apoproteins) LDL (ApoB-100)
VLD
L Cleared by Liver
LD (clearance (LDL receptor for B-100,
mechanism) ApoE clearance)
L
IDL
Function Carry liver-synthesized
lipids to other cells
The twin cycle hypothesis and
T2DM
Step 2
Start
here!

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
The “first” cycle – the liver
Insulin resistance isn’t just “shutting insulin off”
▪ It’s an imbalance in the see-saw between glucagon and
insulin signaling – which is especially important when
considering liver physiology
In those with longer-term insulin resistance/T2DM, the liver
accumulates lipid (steatosis) and this may exacerbate insulin
resistance in hepatocytes
▪ Steatosis 🡪 Inappropriate gluconeogenesis 🡪 increased blood
glucose 🡪 increased pancreatic insulin secretion…
▪ You end up with the strange metabolic situation of fat
accumulation in hepatocytes, increased VLDL export (both
“insulin-driven” functions) and decreased ability of the liver to
shut off gluconeogenesis (“glucagon-driven” function)

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
The “first” cycle – the liver
Don’t forget the role of elevated circulating FFAs (from
insulin-resistant adipocytes)
▪ The body has no choice but to deal with these – we don’t have an “energy excretion”
mechanism
▪ The hepatocytes tend to take these FFAs out of circulation and “repackage” them as
triglycerides in VLDL or incorporate them as lipid droplets – this activity is enhanced in
T2DM
▪ Elevation of FFAs (in particular palmitic acid) activates TLRs and seems to exacerbate
insulin resistance and “stress” the cell out

Many of those with the metabolic syndrome/T2DM
have “ectopic” deposition of fat
▪ Within skeletal muscle
▪ Within the pancreas 🡪 next cycle

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
The twin cycle hypothesis and
T2DM
Step 2
Start
here!

Step 3

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
The “second” cycle – the
pancreas
The changes to the pancreas in T2DM have been the
most poorly characterized… until recently
▪ Pancreas is very “deep” in the body, hard to assess,
hard to biopsy, and there has always been a
conceptual “block” 🡪
The acinar cells and > 95% of pancreatic tissue Bad
don’t matter in T2DM… it’s all about the islets? assum
▪ Studies that examine the degree of adiposity and p-tion?
fibrosis in the islets AND the surrounding acinar
cells suggest that the pancreas is an important
player – “the second cycle”
Intrapancreatic fat accumulation is common in those
with T2DM, and reversal of T2DM is associated with
large decreases in pancreatic fat

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
The “second” cycle – the
pancreas
The liver delivers excess TGs (via VLDL) to the pancreas
▪ Linked to fibrosis and fatty accumulation in the pancreas in general (around acinar cells)
▪ Linked to accumulation of palmitic acid (FFA) in islet cells, specifically pancreatic beta-
cells

What are the consequences of “fatty pancreas”?
▪ Initially hypothesized to be apoptosis of beta-cells over time
Increased ER stress, ROS production, apoptosis
of beta cells
“beta cell burnout” due to continuous insulin
production
This may be true
Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
The “second” cycle – the
pancreas
What are the consequences of “fatty pancreas”?
▪ There are other possibilities beyond apoptosis – beta cell de-differentiation
▪ In animal and in vitro studies, excess fat and highly excessive glucose lead to beta cells
that act more like alpha cells
What does an alpha cell secrete?
▪ This is being intensely studied right now in humans

Whatever the cause of beta cell dysfunction, resolution
of fat deposition and fibrosis in the pancreas (as
assessed by MRI) seems to be improved with dietary
restriction and the resolution of T2DM, and is linked
with resolution of hepatic steatosis
Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
The twin cycle hypothesis and
T2DM
Step 2
Start
here!

Step 3

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
10.1097/XCE.0000000000000201
Note the positive feedback
loop
Insulin resistance 🡪 increased hepatic steatosis and VLDL output 🡪 TG and
FFA accumulation in the pancreas 🡪 compromised insulin secretion
(impaired ability to secrete large, immediate “pulses of insulin) 🡪
hyperglycemia 🡪 conversion to fat, increased circulating FFAs…

Elevations in VLDL and the
general inflammation
associated with T2DM…
▪ Describe the likely
impact on
atherosclerosis
 Endogenous pathway (review slide)
Initial
lipoprotein:
VLDL is synthesized by the liver – contains mostly TGs but also
contains phospholipids, cholesteryl esters, vitamin E
Contain ApoC-II and ApoA-V – these are important for the activity of
LPL in peripheral tissues 🡪 as LPL “drains” triglycerides from VLDL, it
becomes IDL and then LDL
Intermediate
As
Also
forms: TGscontains ApoB-100
are removed from – major
VLDL itstructural
becomesprotein and IDL
IDL – most allows later by
is cleared
clearance
the liver via byApoE
the liver
binding to the LDL receptor (ApoE was transferred
via HDL particles)
IDL that loses TGs and becomes more and more cholesterol-rich
becomes
Cleared by: LDL
Liver
LDL clears IDL and
is cleared byLDL
thevia
LDLthe LDL receptor
receptor, on hepatocytes
and seems to have no useful
physiologic
LDL receptor can bind to either ApoE or ApoB-100
role
If LDL
LDL is receptor
not cleared,
can itbind
cantobecome oxidized
both ApoE and becomes a major risk
and ApoB-100
factor for the development of atherosclerosis
 Subcutaneous fat
“saturation”
Adipose tissue cannot take all the fat (VLDL) out of circulation –
everyone has a limit
▪ Determined by genetics, sex, age

In the setting of insulin resistance, the adipocytes are less able
to build triglycerides, and instead release FFAs
Our subcutaneous fat mass seems to be “good at” secreting
adiponectin
▪ For reasons that are not clear, the subcutaneous fat store secretion of adiponectin cannot “keep up” with
the secretion of leptin (from visceral and subcutaneous fat)
▪ In insulin resistance/T2DM, the ratio of leptin:adiponectin is increased… but many are resistant to leptin,
so food intake becomes more poorly regulated
The twin cycle hypothesis and
T2DM
That is a very detailed… and therefore hard-to-prove…
hypothesis
▪ What is the evidence?
▪ How would we test it?

With successful T2DM treatment do we observe:
▪ Improvement in fatty liver?
▪ Improvement in fatty pancreas?
▪ Weight loss?
▪ A drop in serum triglycerides?

You would think that in long-term T2DM – when the
vast majority of the pancreatic beta cell mass has been
exhausted – the “twin cycles” would be difficult to stop
Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
DiRECT trial in the UK
306 T2DM patients subjected to intense weight-loss program, supervised
by dieticians and nurses
▪ All antihypertensive and antidiabetic meds stopped on first day of the trial, plus:
825 – 853 kcal/day for 3 months
Structured food “reintroduction” to a more
sustainable caloric content over the next 1 – 2
months
▪ Had to have been diagnosed with T2DM within the last 5 years (no long-term T2DM)
▪ Open-label study… but it got published in the Lancet (high-impact journal) because of
the impressive results

Al-Mrabeh, Card. Endo. Metab 2020, 9:132-142; doi:
https://doi.org/10.1016/S0140-
10.1097/XCE.0000000000000201
 DiRECT trial in the UK
Results:
149 with dietary intervention, 149 control
At 12 months, weight loss of 15 kg or more in 36 (24%) participants in
the intervention group and no participants in the control group
(p