TYPE 2 DIABETES MELLITUS

New treatments for an old disease Ahdy Wadie Helmy, MD, FACP Associate Professor of Medicine IU School of Medicine

Type 2 Diabetes Mellitus that is hitting back with

vengeance

Age-adjusted Prevalence of Obesity and Diagnosed Diabetes Among US Adults 2EHVLW\%0,•NJP2) 1994

USA .

2000

2014

A new Diabetic case Dx every 20 secs(1.7 million/yr ) No Data

<14.0%

14.0%±17.9%

18.0%±21.9%

Diabetes kills 1 A merican

Diabetes

every 3 minutes

1994

22.0%±25.9%

2000

> 26.0%

2014

180 diabetics loose a limb

every 24 hrs 55 Diabetics end on dialysis No Data

every hrs <4.5% 24 4.5%±5.9%

6.0%±7.4%

7.5%±8.9%

>9.0%

&'&¶V'LYLVLRQRI'LDEHWHV7UDQVODWLRQUnited States Surveillance System available at http://www.cdc.gov/diabetes/data

Globally, same mess, only Bigger! Estimated global prevalence of diabetes EU 17.8 25.1 41%  

NA 19.7 33.9 72%

China 20.8 42.3 204%  

MEC 20.1 52.8 263%

LAC 13.3 33.0 248%

151 million

2000

SSA 7.1 18.6 261%  

366 million

2011

India 31.7 79.4 251%

A+NZ 1.2 2.0 65%  

642 million

2040

International Diabetes Federation. IDF Diabetes Atlas. 7th ed.accessed April 2016.

'LDEHWHVGRHVQ¶WGHYHORSRYHUQLJKW it  takes  years  of  preparation  

Feeding More Insulin to suppress lipolysis

Liver Visceral Adiposity

Pancreas

Cardiac Muscle

ǃ-­Cell  mass  in  Type  2  diabetes   3.5

E -Cell volume (%)

3.0 -50%

2.5 2.0

-63%

1.5 1.0 0.5 0.0 ND

IFG

Obese

T2DM

ND

T2DM

Lean

ND=non-diabetic; IFG=impaired fasting glucose; T2DM=Type 2 diabetes mellitus Butler et al. Diabetes. 2003

Insulin  Secretion  /  Insulin  Resistance  (Disposition)   Index  During  OGTT   Getting Back up on WKH&XUYH¶

40 Lean

30

¨,¨* IR

20

10 Obese

TZDs,Metformin 0

IS

NGT

IGT

T2DM

2-Hour Plasma Glucose (mg/dL) G=glucose; I=insulin; IR=insulin resistance. Gastaldelli A, et al. Diabetologia. 2004;47:31-39.

IR

Pathogenesis  of  Type  2  Diabetes   Islet E-cell   Diabetes

Diabetes Normal glucose tolerance

Insulin Secretion

Normal glucose tolerance

Insulin Secretion

Impaired Insulin Secretion 1 0

5

1st Phase

0

5

i.v. Glucose

1 0

1 5

2nd Phase

2 0

2 5

3 0

3 5

4 4 5 5 0 5 0 5 Time (minutes)

6 0

6 5

7 0

7 5

8 0

8 5

9 0

9 5

1 0 0

1st Phase (AIR ) -10 -5 0 Increased HGP

5

2nd Phase

10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95 100

i.v. Glucose

Time (minutes)

Decreased Glucose Uptake

Adapted from glucose Weyer C,production. et al. J Clin Invest. 1999;104:784-789; Ward WK, et al. Diabetes Care. 1984;7:491-502. HGP=hepatic

Insulin  Secretion  and  Insulin  Resistance     in  Different  Ethnic  Populations  With  IGT   Decrease in AIR Necessary to Convert From NGT to IGT

ǻ AIR (%)

0 -10

Pima Indian

Latino/Hispanic

White

-8

-20

-18

-30 -32

-40

Insulin resistance

ĹĹĹ

ĹĹ

AIR=acute insulin response to glucose. Abdul-Ghani MA, et al. Diabetes Care. 2006;29:1130-1139.

Ĺ

Hormones  in  Sequence   insulin secretion 2nd wave

insulin secretion Meal AIR

80

Beta Cells

15

Amylin

10

Insulin (mU/L)

20

40

20

5

0 -30

60

0

30

60

GLP-1: Secreted upon the ingestion of food Without diabetes; n = 27 Late-stage type 2; n = 12 Type 10 1; n = 190 Data from Kruger D, et al. Diabetes Educ 1999; 25:389-398

90

120

Meal (min)

150

180

* * * * * * *

0 0 30 60 90 120 150180

 The  Incretins    ³Gut-­derived  factors  that  increase     glucose-­VWLPXODWHGLQVXOLQVHFUHWLRQ´   (  Intestine        Secretion    of      Insulin  )    

GLP-1: Secreted upon the ingestion of food

 

Promotes satiety and reduces appetite

Alpha cells:

p Postprandial glucagon secretion

Liver: Beta cells: Enhances glucose-dependent insulin secretion

p Glucagon reduces hepatic glucose output

Stomach: Helps regulate gastric emptying

Data from Flint A, et al. J Clin Invest. 1998;101:515-520; Data from Larsson H, et al. Acta Physiol Scand. 1997;160:413-422 Data from Nauck MA, et al. Diabetologia. 1996;39:1546-1553; Data from Drucker DJ. Diabetes. 1998;47:159-169

The  Incretin  Effect  is  Reduced  in  Subjects   with  Type  2  Diabetes   The Incretin Effect accounts for ~ 60% of total Insulin release following a meal Subjects with type 2 diabetes

80

80

60

60

Insulin (mU/L)

Insulin (mU/L)

Control subjects

40 * * * * * * *

20

30

60

90 120 150 180

Time (min)

Oral Glucose Nauck MA, et al. Diabetologia 1986;29:46±52. *P ”FRPSDUHGZLWKUHVSHFWLYHYDOXHDIWHURUDOORDG

* * *

20

0 0

40

0 0

30

60 90 120 150 180 Time (min)

Intravenous Glucose

GLP-­1  Is  Cleaved  and  Inactivated  by  DPP-­4  

T1/2= 1 to 2 min

Development  of  more  incretin  mimetics    50%  overlap  with  human  GLP-­11   ± Binds  GLP-­1  receptors  on  ȕ-­cells  (in  vitro)2   ± Resistant  to  DPP-­IV  inactivation3  

liraglutide  OD     T½  13  h  

Liraglutide GLP-1 Human

Q A AAKE H AE G T F T S D V S SSYL Y L E GGQ K E F I AA

A Site of DPP-IV Inactivation

exenatide  

2.4  h  

T½   Ŷ Following injection, exenathours4

1Eng

2,3

has

97 % AA sequence identity with human GLP-1

J, et al. J Biol Chem 1992;267:7402±7405; Adapted from 2Nielsen LL, et al. Regul Pept 2004;117:77±88; DJ. Diabetes Care 2003;26:2929±2940; 4Calara F, et al. Clin Ther 2005;27:210±215.

3Drucker

Chemical  Structures  of  GLP-­1  RAs   BYETTA Drug   (Exenatide)

53% Homology Gila monster Exenatide  IR   saliva ®

(Byetta )  

Exenatide  ER   (Bydureon®)   VICTOZA Liraglutide   (Liraglutide) (Victoza®)   97% Homology C-­16 Fatty Acid Chain Albiglutide  

(Tanzeum®)  

Dulaglutide   (Trulicity®)  

Initial  

Titrate  

5  mcg  BID  within   60  mins  of  a  meal     Ĺ  to  10  mcg   (>  6H  between   after  1  month   doses)  

2  mg  once   weekly  

Weekly N/A   TANZEUM (Albiglutide) 0.6  mg  once   1.2  mg  once   97% daily   daily  per  week   Homology   Dimer fused Ĺ  to  50  mg   to Albumin 30  mg  once   weekly  

0.75  mg  once   weekly  

once  weekly  if   inadequate   response  

Ĺ  to  1.5  mg   once  weekly  if   inadequate   response  

Max  

Dose  Adjustments  

Weekly BYDUREON

10  mcg   Renal  impairment:  CrCl  30-­50  mL/min:  use   (Exenatide ER) caution;;  CrCl  <  30  mL/min  not   53% recommended   Homology Hepatic  impairment:  not  studied   Microsphere technology 2  mg  once   weekly  

1.8  mg  once   daily  

50  mg  once   daily  

1.5  mg  once   weekly  

Renal  &  hepatic  impairment:  use  caution   ±  limited  experience   Renal  impairment:  use  caution  when   Weekly initiating  or  escalating  doses   TRULICITY Hepatic  impairment:  not  studied,  unlikely   (Dulaglutide) 90% Homology required   Linked to modified IgG Renal  impairment:  use  caution  when   initiating  or  escalating  doses   Hepatic  impairment:  use  with  caution  

Deciding  about  First  Injectable  Drug  for   Patients  Not  Controlled  by  Oral  Agents  

‡ DURATION-­3  trial  of  once-­weekly  exenatide  vs  insulin   glargine  as  first  injectable  therapy     Exenatide   QW     (n=233)  

Insulin   glargine   (n=223)  

P  Value  

Change  in  A1C  

-­1.01%  

-­0.81%  

0.03  

Change  in  body   weight  

-­5.5  lbs  

+4.4  lbs  

<0.001  

0.9  events   per  patient-­ year  

NR  

3-­year  endpoint  

Hypoglycemia   0.3  events   (exposure-­adjusted   per  patient-­ events)   year   NR = not reported.

Diamant M et al. Lancet. 2014:2:464-­473.

ITKA  650  osmotic  pump  for  continuous   Exenetide  infusion  implanted  yearly        

60  Mcg  daily  was  found  to  be  the  most  tolerable  dose  .  Diab  Care.  Vol   36  :  2013,  lancet  04/2016  

Exenetide  QMS  once-­monthly  suspension  dosing  (  Phase   II  study  data  )  

‡ Microsphere  technology  provides  a  continuous  level  of  exenatide1   Microspheres  consist  of  a  biodegradable  polymer  that  dissipates  into  CO2  and  water1   Using  a  non-­aqueous  suspending  medium  of  Medium  Chain  Trigs  Miglyol  812  that   keeps  the  microspheres  suspended  &  preserved  eliminating  the  need  for   reconstitution  immediately  before  injection.    (  5,  8,  11  MG  dosing  )  with  efficacy  &   tolerability  c/w  Exenetide  QW  

 

Subcutaneous  injection   of  microsphere   suspension  of   exenatide1  

Individual   microspheres   aggregate  and  initial   release  of  exenatide1  

Microsphere   degradation  and   continued  release  of   exenatide1  

Further  degradation   and  metabolism  of   microsphere  polymer   provide  sustained  level   of  exenatide1  

Wysham et al.Efficacy & Safety of multiple doses of exenetide once-monthly suspension in patients with Type 2 DM: a phase II RCT. Diabetes Care 2016;39:1768-1776.

DPP-­4  Inhibitors  Prevent  the   Inactivation  of  GLP-­1    

GLP-­1  Modulates  Numerous  Functions  in  Humans   GLP-1 Receptor Agonism

DPP-4 Inhibition

Decreases food intake

Slows gastric Emptying

Improves firstphase insulin response

Suppresses glucagon secretion, decreasing glucose output Stimulates glucosedependent insulin secretion

1. Stonehouse A, et al. Curr Diabetes Rev 2008;4:101-109; 2. Nielsen LL, et al. Regul Pept 2004;117:77-88 3. Kolterman OG, et al. J Clin Endocrinol Metab 2003;88:3082-3089; 4. Fehse F, et al. J Clin Endocrinol Metab 2005;90:5991-5997

Sitagliptin  

Linagliptin  

Saxagliptin  

Alogliptin  

Comparison  of  Dipeptidyl  Peptidase±4  (DPP-­4)   (Nesina  )   (  januvia)   (  Tradjenta)   (onglyza  )   Inhibitors   Dose  frequency   100  mg  QD   5  mg  QD     5  mg  QD  

6.25mg,  12.5,25  

         QD     Half-­life  (t1/2),  h   DPP-­4  inhibition  at   24  h   Elimination  

Renal  dose   adjustments   required  

12.4  

12.5±21.1    

2.2±3.8  

~80%  

 ~80%  (25  mg)  

~55%  (5  mg)      

Kidney   (mostly  unchanged)  

Bile  but  not  kidney   (mostly  unchanged)  

Liver  and  kidney   Active  metabolite  

Yes  

No   Bile

Yes  

         21  hrs  

 Yes  

Selectivity  for  DPP-­  >2600-­fold  vs  DPP-­8  >10,000-­fold  vs  DPP-­8/9  >400-­fold  vs  DPP-­8   4   >10,000-­fold  vs  DPP-­ >100-­fold  vs  DPP-­9     9   Potential  for  drug± drug  interaction   Food  effect  

Low  

Low  

Strong  CYP3A4/5   inhibitors  

No  

No  

No  

The  Kidneys  Play  an  Important  Role  in  the   Handling  of  Glucose   ‡ Total  glucose  stored  in  body                                                   ~450  g   ‡ Glucose  utilization                                                                                    ~250  g/day   ‡ ‡ ‡

‡ Brain        ~125  g/day   ‡ Rest  of  body        ~125  g/day   Glucose  in  Western  diet                                                              ~180  g/day   Renal  glucose  production  (gluconeogenesis  +                      ~70  g/day   glycogenolysis)   Renal  glucose  filtration  &  reabsorption          ~180  g/day   SGLT2 receptors   ‡ Urinary  glucose       High Capcity/Low      0  g  

affinity @ Prox Renal Tubules Wright  EM,  et  al.  J  Intern  Med.  2007.  

Renal  glucose  re-­absorption  in  healthy   individuals  

Filtered glucose load 180 g/day

SGLT2

~ 90%

SGLT1

~ 10%

Gerich  JE.  Diabet  Med.  2010;;27:136±142.  

23

Renal  glucose  re-­absorption  in  patients   with  hyperglycaemia   Filtered glucose load > 180 g/day

SGLT2

~ 90%

SGLT1

~ 10%

Gerich  JE.  Diabet  Med.  2010;;27:136±142.  

When blood glucose increases above the renal threshold (~ 10 mmol/l or 180 mg/dL), the capacity of the transporters is exceeded, resulting in urinary glucose excretion

Urinary  glucose  excretion  via  SGLT2   inhibition   Filtered glucose load > 180 g/day

SGLT2 SGLT2 inhibitor

SGLT1

*Loss  of  ~  80  g  of  glucose/day  (~  240  cal/day).   Gerich  JE.  Diabet  Med.  2010;;27:136±142.    

SGLT2 inhibitors reduce glucose re-absorption in the proximal tubule, leading to urinary glucose excretion* and osmotic diuresis

Renal(CANAGLIFLOZIN) Glucose Handling After (DAPAGLIFLOZIN) (EMPAGLIFLOZIN) SGLT-2 Inhibition Urinary Glucose Excretion (g/day)

150

Dosing Frequency

Dosage

Diabetes Threshold SGLT-2 Inhibition 100 & 300 mg

100

5 & 10 mg

10.6 ± 13.1 Normal Threshold

Half-life (hours) 50

Metabolism

Elimination 0 0

~ 12.9 UGT1A9

Fecal / Renal

Renal / Fecal 200

Luseogliflozin 10 & 25 mg

Tofogliflozin

~ 12.4 upSGLT2 receptors Ertugliflozin regulated in diabetes, increasing glucose UGT2B7, UGT1A3 reabsorption UGT1A8, UGT1A9

UGT1A9, UGT2BA

100

Ipragliflozin

300

Renal / Fecal 400

Renal Dosing < 45 mL/min < 60(mg/dL) mL/min < 45 mL/min Plasma Glucose (eGFR): Farber et al. J Clin Invest. 1951;30: 125-129. Mogensen CE. Scand J Clin Lab Invest. 1971;28:101-109. NotSJ, Recommended Silverman M, Turner RJ. Handbook of Physiology. In: Windhager EE, ed. Oxford University Press. 1992: 2017-2038. Cersosimo E, et al. Diabetes. 2000;49:1186-1193. DeFronzo RA, et al. Endocr Pract. 2008;14: 782-790.

Large  CV  Outcomes  Trials  in  Diabetes   Study  

SAVOR  

EXAMINE  

DPP4-­i  

saxagliptin  

alogliptin  

Comparator  

placebo  

n  

TECOS  

CAROLINA  

CARMELINA  

sitagliptin  

linagliptin  

linagliptin  

placebo  

placebo  

sulfonylurea  

placebo  

16,500  

5,400  

14,000  

6,000  

8,300  

Results  

2013  

2013  

2015  

2017  

2017  

Study  

LEADER  

ELIXA  

SUSTAIN  6  

EXSCEL  

REWIND  

GLP1-­RA  

liraglutide  

lixisenatide  

semaglutide  

exenatide  LR  

dulaglutide  

Comparator  

placebo  

placebo  

placebo  

placebo  

placebo  

n  

16,500  

14,000  

6,000  

5,400  

8,300  

Results  

6/2016  

2015  

10/2016  

2018  

2019  

✓ ✓

NCT01986881

Study  

EMPA-­REG  

CANVAS  

DECLARE  

SGLT-­2-­i  

empagliflozin  

canagliflozin  

dapagliflozin  

ertugliflozin  

Comparator  

placebo    Reported     7300   EASD  2015     2015  

placebo  

placebo  

placebo  

4300  

22,200  

3900  

2017  

2019  

2020  

n   Results  

Number needed to treat (NNT) to prevent one death across landmark trials in patients with high CV risk

Simvastatin for 5.4 years

Pre-statin era 1994

Ramipril for 5 years

Empagliflozin for 3 years

Pre-ACEi/ARB era

>80% ACEi/ARB

<29% statin

>75% statin

2000

1. 4S investigator. Lancet 1994; 344: 1383-89, http://www.trialresultscenter.org/study2590-4S.htm; 2. HOPE investigator N Engl J Med 2000;342:145-53, http://www.trialresultscenter.org/study2606-HOPE.htm

2015 28

Insulin  degludec  from  solution  to   subcutaneous  depot    

(Multi-­hexamer  formation  key  to  protraction  mechanism..Tresiba  ®)  

 

Phenol              Zn2+   Insulin  degludec     injected   As  phenol  from  the  vehicle  diffuses  degludec   hexamers  link  up  via  single  side-­chain  contacts  

Long  multi-­hexamers   assemble  

Insulin  degludec:  slow  release  following  injection  

Subcutaneous  depot  

Zn2+    

Insulin  degludec     multi-­hexamers  

Zinc  diffuses  slowly  causing  individual  hexamers  to   disassemble,  releasing    monomers    

Monomers  are  absorbed  from  the   depot  into  the  circulation  

Insulin  degludec:     Mechanism  of  protraction  

Multi-­hexamers  

Subcutaneous  tissue    

Half-life is ~24 hours, duration Monomers   >42 hours, VWHDG\VWDWHídays Comes in 2 different degrees of green pens (Forest G/Garden G) U200& U100 Capillary  membrane  

Capillary  blood  

Cell  Membrane  

Insulin  degludec  in  blood  

Albumin  binding    

Insulin  Receptors  

Timing  of  flexible  insulin  degludec   administration   Mon  

Tue  

Wed  

Thu  

8h  

morning  

Fri  

Sat  

Sun  

8h  

morning    

morning    

8-­12  AND  36-­40  hours  between  insulin  administration   40h  

40h  

evening  

40h  

evening  

24h  

evening  

evening  

‡ Insulin detemir (Levemir®) ‡ Insulin glargine (Lantus®) ‡ Insulin glargine U300 (Toujeo®) ‡ Insulin glargine (BasaglarTM)

ONSET 90 min 90 min Up to 6 h 90 min

Similar reduction in A1c compared to U-100 glargine

Up to 24 h (detemir 16-24 h) Up to 24 h (glargine 24 h) Up to 30 h Up to 24 h (glargine 24 h)

For patients maintained on insulin Less glargine (U-100), expect a higher daily nocturnal dose requirement of (U-300) to maintain the same hypoglycemia level of glycemic control with U-300 glargine

Combination  of  Basal  Insulin  with  a  GLP-­1  Agonist     has  a  Scientific  Logic  

Complementary   actions  

Insulin Degludec/Liraglutide ( Xultophy ) P Basal  insulin  analogs  

GLP-­1  agonists  

‡ ‡ ‡ ‡

‡ ‡ ‡ ‡

Simple  to  initiate   Control  nocturnal  and  FPG   Lower  hypoglycaemia  risk  vs  NPH   Modest  weight  increase  (1±3  kg)     ‡ Achieve  A1C  targets  in  ~50±60%  

Simple  to  initiate   Pronounced  PPG  control   No  increase  in  hypoglycaemia   Weight  lowering/neutral  effects     ‡ Achieve  A1C  targets  in  ~40±60%  

Insulin Lantus/Lixisenitide ( iGlarlixi ) OK Additive     effects  

Once-daily prandial lixisenatide versus once-daily rapidacting insulin in patients with type 2 diabetes mellitus insufficiently controlled with basal insulin: analysis of data from five randomized, controlled trials.. GETGOAL DUO -2

Triple Composite Outcome

Journal of Diabetes and Its Complications 2014 28, 40-44DOI: (10.1016/j.jdiacomp.2013.10.003) Copyright © 2014 Terms and Conditions

Ultra  rapid  Acting  Inhaled  Insulin   ‡ Pulling  Zinc  ions  out  will  destabilize  the  hexamer  structure  allowing  for  quicker   ‡

absorption.     Max  Blood  concentrations  within  15  mins,  rapid  hypoglycemic  effect  with  2-­3  hrs   total  duration  of  action.  

 

Technosphere®  ,QVXOLQ$)5(==$Œ   Technosphere insulin particles made up of diketopiperazine derivatives and insulin, which self-organize into a lattice array, and form particles of 2±4 µm diameter.

Peak  Effect:     pH < 6 ‡ SQ(  RAA):  ~1  hrs  

as

‡ Inhaled:  53  min  

‡$)5(==$Œ Cough ~30% Duration:     Inhaled:  160-­180  min   10 U SCchanges Ins ‡ No‡ clinically meaningful in ‡ SQ(RAA):  2-­4  hrs   3)7¶VVKRUW-term) pH > 6 in the lungs

More  Changes  to  Insulin  Formulations  

‡ BioD-­090(VIAject)  recombinant  insulin  +  (EDTA);;   loosely  packed  insulin  multimers  with  rapid  dissociation  into   monomers  &  dimers.  

‡ Ultra-­fast-­acting  insulin  aspart(FIAsp)  

recombinant  insulin  +  nicotinamide  &  arginine  causing  increased   local  blood  flow  &  so  accelerated  pharmacokinetics.  

‡ Hyaluronidase  +  analogue  insulin  (  uPH20/Hylenex)   accelerated  insulin  action,  time  to  peak,  PP  glycemic  excursions   reduced  by  82  %,  and  statistically  significant  reduction  in   hypoglycemic  events.   ‡ Injectable  nano-­network  (  smart  insulin  );;  where  Dextran   nanoparticles  loaded  with  insulin  &  glucose-­specific   enzymes,  causing  glucose-­dependent  insulin  release    

Hyaluronidase Mechanism of Action

Hyaluronidases  increase  the     dispersion  of    SC  Insulin    

Produces  earlier  and  greater    peak  insulin  concentrations,     leading  to  improved     postprandial  glycemic  control  

39

Using  Nanotechnology;;     Oral  Insulin  Delivery  by  PH  Sensitive  Microspheres   Gel/Microsphere system with polymethacrylic acid + PEG In stomach (pH 2) pores in the polymer shrink & block protein release In neutral pH ( small intestine) the pores swell & release protein

PH 2

PH 7

Buccal Insulin Delivery using RapidMist Technology

G2 The insulin canister hold 400 units and delivers 10 units per puff in a precisely metered dose. The formulated insulin is called Oral-lynŒLQLWLDOO\,had a 10% absorption. University of Toronto Researchers enhanced the Oral-lynŒ formulation, a 9-fold increase in serum insulin at 15 minutes and nearly 500 percent higher absorption of insulin over the 2-hour test period was verified in comparison to dogs that received the original formulation; a 33 percent decrease in serum glucose around minute 30 for the enhanced Generex Oral-lynŒIRUPXODWLRQZDV noted in comparison to a 12 percent increase in serum glucose in those that received the original formulation. It may be taken just before the first bite and just after the last. This flexibility offers both Type 1 and Type 2 patients a unique opportunity to aggressively treat diabetes with a minimal risk of hypoglycemia. The formulated insulin is stable at room temperature (North America) for 6 months or more. The micelles that are formed, containing the insulin, are > 7 microns and cannot enter the deep lungs regardless of effort. It is important to remember that only 20 ± 40% of subcutaneous injection is absorbed. As will be mentioned below, insulin appears in the blood within 5 min, peaks at 30 min and is back to baseline at 2 hr«7KLVnarrow window is unique to buccal insulin. It is possible because of the rich vascularity below the buccal epithelium. As with nitroglycerin, the insulin PK-PD is very fast, thus affording flexibility. The ODFNRIDµWDLO¶RILQVXOLQDFWLYLW\ZRXOGIDYRUOHVVK\SRJO\FHPLD

Older Therapies revisited ( teaching old dogs new tricks)

IR XR

DR

Published in: André J. Scheen; Expert Opinion on Pharmacotherapy 2016, 17, 627-630. DOI: 10.1517/14656566.2016.1149166 Copyright © 2016 Informa UK Limited, trading as Taylor & Francis Group

Effect of TZD ( Pioglitazone ) & on Fat Topography

Recent Data from IRIS trial

( Insulin Resistance Intervention after Stroke ) (Pio reduced DM risk by 52 % in Stroke Pts, Reduced MACE by 24 % over 5 yrs) Hi TG Hi FFA

Intramuscular Fat

TZD Subcutaneous Fat

Intrahepatic Fat Intraabdominal Fat

TG FFA

4% more

20 % less

DeFronzo RA, JCEM 89:463-478, 2004 Inzucchi et al. Pioglitazone prevents Diabetes in patients with IR & CVA. Diabetes Care 2016;39:1684-1692.

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