digestive phys and glucose metabolism

Question 1

Pathway of digestion

Answer 1

• ingestion
• mechanical digestion: chewing, churning of stomach and segmentation in stomach
• propulsion: swallowing, peristalsis (esophagus, stomach, small intestine, and large intestine)
• absorption in small intestine and large intestine (mostly water)
• defecation

Question 2

The pancreas (location, function, anatomy)

Answer 2

• gland with both exocrine and endocrine fxns
• 6-10 inches in length
• 60-100 g in weight
• location: retro-peritoneum, 2nd lumbar vertebral level
• extends in oblique, and transvere position
• parts of the pancreas: head, neck, body and tail

Question 3

Embryology of pancreas?

Answer 3

• endodermal origin
• develops from ventral and dorsal pancreatic buds (develop independently)
• ventral bud becomes the uncinate process and inferior head of pancreas
• dorsal bud becomes superior head, neck, body, and tail
• ventral bud duct fuses with dorsal bud duct to brecome main pancreatic duct (wirsung)
• pancreas divisum when fails to fuse

Question 4

What is the definition of exocrine?

Answer 4

• secreeting outwardly via a duct

Question 5

What is the definition of endocrine?

Answer 5

• secreting inwardly, applied to organs and structures whose functions is to secrete into the blood or lymph a hormone that has a specific effect on another organ or part

Question 6

Where is there a large capillary network in the pancreas?

Answer 6

• in the islet of langerhans (endocrine part of pancreas)

- islets of langerhan cells are not part of duct system

Question 7

What cells make up the exocrine part of pancreas?

Answer 7

• acinar cells: secrete pancreatic enzymes into pancreatic duct

Question 8

What is function of islet of langerhan cells?

Answer 8

• secrete endocrine hormones into blood vessels

Question 9

Anatomy of islet of langerhans?

Answer 9

• insulin producing B cells are in the center closest to the blood supply and are surrounded by glucagon producing alpha cells. On outside are the delta cells which make somatostatin (produces GH), and the PP cells (gamma cells) that make pancreatic polypeptide

Question 10

histology of endocrine part of pancreas?

Answer 10

• accounts for only 2% of pancreatic mass

- nest of cells: islet of langerhans

Question 11

Four major cell types of the endocrine pancreas?

Answer 11

• alpha cells: secrete glucagon
• beta cells: secrete insulin
• delta cells: secrete somatostatin
• F cells (gamma cells) secrete pancreatic polypeptide

Question 12

Organization of acinar cells and iselt of langerhans?

Answer 12

• islet of langerhans is surrounded by pancreatic acinar cells. The islet cells form cords separated by blood capillaries. The islet is surrounded by reticular fibers separating it from acinar cells

Question 13

What is function of alpha cells?

Answer 13

• release glucagon; main action is to produce an increase in blood glucose: they do this by -
  breakdown of glycogen, stimulates gluconeogenesis (inhibits glycogenesis), increases transport of AA into the liver and stimulates their conversion to glucose
• high levels activate adipose cell lipase making fatty acids available for use as energy

Question 14

What stimulates the release of glucagon?

Answer 14

• released into portal circulation in response to low glucose levels in blood, stimulated by high concentrations of AA and by strenuous exercise

Question 15

Metabolic effects of glucagon?

Answer 15

• increase glucose, increase ketoacids,

and decrease amino acids

Question 16

What factors stimulate glucagon secretion?

Answer 16

• hypoglycemia
• amino acids: aginine and alanine
• GI hormones: CCK, gastrin
• fasting
• exercise
• neural influences: vagal activity acetylcholine, sympathetic stim (NE, E)

Question 17

What factors inhibit glucagon secretion?

Answer 17

• glucose
• somatostatin
• insulin (direct effect)
• GI hormones: secretin, GLP-1
• free fatty acids
• ketoacids
• neural influences: alpha-adrenergic stim

Question 18

Effect of DPP-4 inhibitors

Answer 18

• block DPP-4 and decrease glucose
• DPP-4 enzyme inactivates GLP-1, and incretin this stimulates insulin release (stim. beta cell production) and inhibits glucagon release which lowers the blood glucose
  (DPP-4 is essential in formation of glucose)
• impt impact in DM II, won’t work on DM I because there are no beta cells to stimulate

Question 19

Fuel metabolism during the anabolic state (building up)

Answer 19

• hormones: increased insulin and decreased glucagon
• fuel source is diet
• process: glycogen synthesis, triglyceride synthesis, and protein synthesis

Question 20

Fuel metabolism in catabolic state?

Answer 20

• catabolism: decreased insulin, increased glucagon

- fuel source: storage depots, process: glycogenolysis, lipolysis, proteolysis, ketogenesis (formation of ketones)

Question 21

Metabolic effects of Epi?

Answer 21

• increased glucose, free fatty acids from triglycerides, and increased ketoacids from free fatty acids

Question 22

What hormones promote glucose production (liver)?

Answer 22

• Glucocorticoids, GH, glucagon, Epi

- insulin will inhibit glucose production

Question 23

What hormone promotes glucose consumption in muscle and adipose tissue?

Answer 23

• insulin

- glucocorticoids, and GH have inhibitory effect on glucose consumption

Question 24

Function of Beta cells?

Answer 24

• produce insulin: lowers blood glucose by: promoting uptake of glucose by target cells, provides for glucose storage as glycogen, prevents fat and glycogen breakdown
• inhibits gluconeogenesis and increases protein synthesis
• promotes fat storage by increasing transport of glucose by increasing transport of glucose into fat cells
• increases triglycerides synthesis
• Beta cells produce pro-insulin formed by an A and B cahin separated by inactive C-peptide chain which is cleaved by enzymes in the beta cells and packaged in secretory granules, insulin enters protal circulation where 50% used or degraded, 1/2 life is 15 minutes

Question 25

Where do the main steps of insulin synthesis and secretion by a B cell take place?

Answer 25

• islets of Langerhands
• RER: synthesis of proinsulin
• small transfer vesicle - transport of proinsulin to Golgi
• golgi secretes secretory granules and conversion of proinsulin to insulin occurs

Question 26

Insulin and glucose relationship in circulation?

Answer 26

• insulin directly enters protal venous circulation before peripheral cirulation: 2/3 of glucose is stored as glycogen in the liver, and other glucose is released back into blood to keep blood glucose at steady state after intake

Question 27

What is a major regulator of insulin?

Answer 27

• glucose
• in pancreatic beta cell glucose transporters - allow influx of glucose: glucokinase
• results in closure of K+ channels and opening of Ca channels allowing secretion of insulin by exocytosis

Question 28

What factors stimulate insulin secretion?

Answer 28

• glucose: mannose and galactose
• amino acids
• free fatty acids, keto acids
• glucagon (direct and indirect effects)
• GI hormones: GLP-1 and GIP
• neural influences: vagal activity (acetylcholine), B-adrenergic stimulation
• sulfonylurea drugs

Question 29

What factors inhibit insulin secretion?

Answer 29

• somatostatin (inhibits both glucagon and insulin)
• fasting
• exercise
• neural influences: sympathetic activity: alpha-adrenergic stimulation (NE and E)
• Leptin: released from fat

Question 30

What is the effect of insulin on carbohydrates?

Answer 30

• carbs from a meal release glucose:
• stimulates secretion of insulin
• causes uptake and storage of glucose in all tissues
• in muscle if not used glycogen is stored
• in liver stored as glycogen, once liver has stored all the glycogen it can, insulin promotes conversion of glucose to fatty acids

Question 31

Metabolic effects of insulin

Answer 31

• decrease glucose, free fatty acids, ketoacids (fatty acids aren’t being broken down), and amino acids (proteins being stored in muscles)

Question 32

Insulin effect on muscle?

Answer 32

• increase GLUT4 transporters
• increase glycogen
• increase glycolysis (glucose to pyruvate)
• increased protein synthesis, decreased protein degradation
• increas in triglycerides (FAs from circulation)

Question 33

Effect of insulin on liver?

Answer 33

• GLUT2 transporter: increase glucokinase
• increase glycogen
• decrease glucose release: decrease G6Pase
• increase glycolysis: increases acetyl CoA, increases FA synthesis
• increases TG storage and export (VLDLs)
• increase protein synthesis, and decreases protein degradation

Question 34

Insulin on fat metabolism?

Answer 34

first insulin increased the utilization of glucose (uptake) by most of the body’s tissues, which decreases utilization of fat

• once liver glycogen is maxed all add. glucose forms fatty acids
• fatty acids in the liver form TGs which are released into blood stream and are transported to adipose tissue
• once there insulin activates LPL which splits TGs into fatty acids again for them to be absorbed into adipose cells

Question 35

What promotes break down of TGs to fatty acids?

Answer 35

• Epi, T3, Cortisol, GH

Question 36

What promotes TG production from fatty acids?

Answer 36

• insulin

Question 37

Insulin impact on adipocytes?

Answer 37

• increase GLUT4 transporters
• increase glycolysis: increase alpha-glycerol phosphate, increase acetyl CoA, and increase FA synthesis
• increase TGs: decrease hormone sensitive lipase and increase LPL

Question 38

Insulin effects on AAs?

Answer 38

• stimulates transport of many AA into the cells
• inhibits the catabolism of proteins especially in muscles cells
• in the liver depresses rate of gluconeogenesis

Question 39

• What will respond to low plasma glucose

- what will respond to high plasma glucose?

Answer 39

• low glucose: glucagon response

- high glucose: insulin response

Question 40

Hormonal responses to specific glucose concentrations?

Answer 40

• 80-85 mg/dl: decreased insulin

- 65-70: increased glucagon, increased Epi, and increased cortisol and GH

Question 41

CNS responses to specific glucose concentrations?

Answer 41

65-70: decreasd glucose uptake
50-55 (60): sympotoms 
50: decreased cognition
40: coma
30: convulsion
20: permanent brain damage

Question 42

Function of delta cells?

Answer 42

• secrete prosomatostatin that is processed soatostatin-14 and somatostatin-28
• actions: inhibits secretion of growth hormone and thyro-tropin from pituitary
• inhibits insulin and glucagon in the endocrine pancreas
• inhibits gastrin release and gastric secretion from parietal cells
• inhibits exocrine secretion of pancreas
• circulating half life: 3 min

Question 43

Pancreatic exocrine functonal unit?

Answer 43

• acinus and its draining ductule with cetroacinar cell b/t acinar cell and ductal epithelium

Question 44

What is the acinar cell of the pancreas?

Answer 44

• basolateral membrane receptors for hormones and neurotransmitters
• basal part: nucles and RER for protein synthesis (active part of the cell)
• apical-zymogen granules to store digestive enzymes
• apical surface: microvilli for exocytosis

Question 45

WHat is the ductal epithelium of the pancreas?

Answer 45

• abundant mitochondria for energy transport

- carbonic anhydrase important to secrete bicarb

Question 46

Histology of exocrine pancreas, what are the 2 major components?

Answer 46

• acinar cells and ducts
• constitute 80-90% of pancreatic mass
• acniar cells secrete the digestive enzymes
• 20-40 acinar cells coalesce into a unit calle the acinus
• centroacinar cell (2nd cell type in the acinus) is responsible for fluid and electrolyte secretion by the pancreas

Question 47

Ductular system in exocrine pancreas?

Answer 47

• ductular system: network of conduits that carry the exocrine secretions into the duodenum
• acinus - to the small intercalated ducts - to the interlobular duct - to the pancreatic duct of wirsung
• interlobular ducts contribute to fluid and electrolyte secretion along with the centroacinar cells

Question 48

Pancreatic secretion of Digestive enzymes? activation?

Answer 48

• digestive enzymes secreted from pancreatic acini:
  in the pancreas the enzymes are in inactive form such as trypsinogen and procarboxypolypeptidase A and B
  in the intestinal lumen glycoprotein peptidase activates trypsinogen then trypsin activits the other inactive proenzymes (if active in pancreas - would destroy it)

Question 49

Enzyme actions of exocrine pancreas?

Answer 49

• trypsin and chymotrypsin split proteins into peptides
• carboxypolypeptidase splits peptides into some amino acids
• pancreatic amylase hydrolyzes glycogen and carbohydrates into disacharides and trisaccharides
• Lipase hydrolyzes fat into FAs and monglycerides
• cholesterol esterase hydrolyzes cholesterol esters
• phospholipase splits fatty acids from phospholipids
• Pancreatic amylase and lipase increase in blood when problem with pancreas

Question 50

What is secreted in large volumes by small ductules of the exocrine pancreas?
purpose of this?

Answer 50

• sodium bicarbonate is secreted in large volumes by small ductules leading from acini
• the ductule cells are stimulated by secretin released when acidic chyme enters the small intestine, they then release large volumes of water and bicarb which makes the contents of the small intestine more alkaline so the pancreatic enzymes work better and more pancreatic enzymes flow out with water and bicarb
• combined enzymes and bicarb flow through pancreatic duct joins hepatic duct and empties into duodenum through papilla of Vater, surrounded by sphincter of Oddi
• also alkaline so you don’t get ulcers from hydrochloric acid

Question 51

Regulation of pancreatic secretion main players?

Answer 51

• acetylcholine: from vagal nerve - moderate amounts of enzymes secreted in acini (20%) - during gastric and cephalic phase
• secretin: from upper intestinal mucosa - stimulates release of water and bicarb from ductules so gets enzymes out of acini - during intestinal phase (alkaline pH)
• cholecystokinin: from duodenal and upper jejunal mucosa: secreted when food enters - causes greater release of enzymes (80%)
• Trypsin inhibitor: in acini prevents activation of trypsinogen and since trypsin activates other enzymes this prevents enzymes from being activated and digesting pancreas

Question 52

Process of activation of pancreatic juice?

Answer 52

• vagal stimulation releases enzymes into acini
• secretin causes copious secretion of pancreatic fluid and bicarb; cholecystokinin causes secretion of enzymes
• acid from stomach releases secretin from wall of duodenum; fats and amino acids cause release of cholecystokinin
• secretin and cholecystokinin is absorbed into the blood stream

Question 53

What is pancreatitis?

Answer 53

• if pancreas becomes damaged or duct blocked then secretions back up and overwhelm trypson inhibitor and pancreatic secretions become activated and digest pancreas causing acute pancreatitis - very serious condition

Question 54

Reaction to low blood glucose on muscle, pancreas and glycogen and adipose cells

Answer 54

pancreas decreases insulin secretion which helps to also trigger muscle and glycogen

• muscle: proteins broken down
• adipose cells: glycerol and fatty acids released
• glycogen: glucose is released
• • in a fasted state: substrates for glucose synthesis (gluconeogenesis) are released from storage

Question 55

What are signs and symptoms of hypoglycemia?

Answer 55

• SNS stimulation:
  sweating, palpitations, tremor, nervousness, irritability, paresthesias, hunger, N/V
• other sxs:
  HA, tired and drowsy, dizzy and fainting, blurred vision, confusion, abnormal behavior, seizures, coma

Question 56

Sympathoadrenal sxs of hypoglycemia?

Answer 56

• sweating, nausea, hunger
• warmth, hunger
• tremor, palpitations, tachycardia (first sxs presented)

Question 57

Neuroglycopenic sxs of hypoglycemia?

Answer 57

• fatigue, HA, drowsiness, dizziness, visual disturbances, difficulty speaking, inability to concentrate, abnormal behavior, loss of memory, confusion, loss of consciousness, seizures

Question 58

What is Whipple’s triad?

Answer 58

• grouping of sxs consisten with hypoglycemia

- low plasma glucose (

Question 59

How common is hypoglycemia, how fast does it occur?

Answer 59

• rapid
• emergency (most common endo emergency)
• 10-30% of type 1 diabetics/ year
• classification: reactive/ functional

Question 60

Causes of reactive hypoglycemia?

Answer 60

• external influences:
  severe exercise
  med use: insulin (timing and dose), B-blockers (will hide SNS effects), bacterium, haloperidol, MAO inhibitors, sulfonylureas

Question 61

Causes of functional hypoglycemia?

Answer 61

• hepatic and renal dysfunction
• malnutrition
• endocrinopathies: adrenal (glucocorticoid) insufficiency, GH deficiency, glucagon deficiency, pituitary disease ( decreased corticotropin/GH)
• pancreatic tumors: insulonoma
• alcohol consumption (inhibits gluconeogenesis)

Question 62

Clinical presentation of hypoglycemia?

Answer 62

• fasting hypoglycemia is assoc’ with sxs of neuroglycopenia, whereas postprandial hypoglycemia is more likely to produce adrenergic responses
• neuroglycopenic manifestations are result of decreased glucose supply to CNS and PNS, including HAs, confusion, slurred speech, neuromuscular sxs, seizures coma
• adrenergic response: caused by an abrupt decrease in glucose level and counter-regulatory release of epi, resulting in sudden onset of hunger, diaphoresis, weakness and palpitation

Question 63

hypoglycemic coma?

Answer 63

• recovery from hypoglycemia may be delayed because of cerebral edema. Unconsciousness lasting more than 30 minutes after plasma glucose is corrected is called posthypoglycemic coma, IV mannitol ( will draw out edema from brain) , or glucocorticoids, or both can be used along with maintenance of normal plasma glucose levels

Question 64

What is hypoglycemic unawareness?

Answer 64

• 50% of type 1 pts undergo diminution in their epi response to hypoglycemia
• further pts lose the autonomic warning sxs of hypoglycemia and may recognize (or even fail to recognize) the condition only when somatic neuro function becomes impaired (neuroglycopenia)
• usually associated with duration of diabetes and autonomic neuropathy
• may also occur when pts are switched to intensive insulin regimens
• the introduction of intensified diabetes tx regimens can lower the glucose levels that triggers epi release and adrenergic sxs
• b blockers blunt cardiac response to hypoglycemia

Question 65

How are hypoglycemic disorders managed?

Answer 65

• in these situations: if pts can ingest food, the hypoglycemia generally responds well to oral glucose (orange juice) or carb-containing products
• if the pt isn’t able or unwilling to ingest food because of mental changes, glucagon is given SC or IM may be give outside of hospital setting
• in the hospital setting: the std tx in these situations is IV glucose admin, which is followed by subsequent glucose infusion, feeding or both
• 1 amp of D 50

Question 66

What is the usual cause of hypoglycemia?

Answer 66

– hypoglycemia in insulin-treated diabetic patients is usually due to omission of a meal while insulin was given, an error in medication or unproductive absorption of food in a pt (gastroparesis)

Question 67

What is important education to give to your patient about diabetes?

Answer 67

• etiologies of hypoglycemia
• preventive measures
• appropriate adjustments to meds
• diet and exercise regimen

Question 68

Body’s reaction to high blood glucose? (right after eating a meal)

Answer 68

• pancreas: increases secretion of insulin which in turn also helps stimulate glycogen formation and glucose absorption into the muscle
• muscle: glucose will be absorbed
• glucose to glycogen
• insulin also stimulates glucose to be absorbed in the adipose cells

Question 69

1st, 2nd, and 3rd priorities of absorbed glucose?

Answer 69

• 1st: glycogen storage: glycogen storage - stored in muscle and liver
• 2nd: provide energy, oxidized to ATP
• 3rd: stored as fat: only ecess glucose, stored as triglycerides in adipose

Question 70

Glucose utilzation?

Answer 70

• adipose tissue and turned into glycogen for energy stores
• turned into ribose-5-phosphate for pentose phosphate pathway
• turned into pyruvate for glycolysis

Question 71

Metabolic consequences of insulin deficiency - DM

Answer 71

• increased blood glucose concentration
• increased blood FFA and ketoacid concentration - fat depletion
• increased blood amino acid concentration - protein depletion

Question 72

Fluid and electrolyte consequences of DM?

Answer 72

• metabolic acidosis - DKA
• glycosuria and osmotic diuresis
• increased osmolarity
• hyperphagia
• polydypsia
• hypovolemic and hypotension
• coma and death if not tx

Question 73

Pathophys of Type 1 DM?

Answer 73

• autoimmune destruction of B-cells
• insulinopenia
• ketonemia (ketone overload)
• dependent on insulin to sustain life and prevent ketoacidosis

Question 74

Pathophys of Type II DM (NIDDM)

Answer 74

• insulin resistance
• normal or elevated insulin initially and then relative insulin deficiency
• increased hepatic glucose production
• not as prone to ketoacidosis as type 1
• most pts are obese
• may require insulin to control hyperglycemia

Question 75

Progression of type 1 diabetes?

Answer 75

• more acute presentation
• usually genetic predisposition then there is an immunologic trigger and decrease of B cell mass - get to such a small number of working beta cells that diabetes presents (acutely, age range is usually 15-20)

Question 76

What happens in the progression of type II diabetes?

Answer 76

• insulin is capable of uptake of glucose but then gets to point where insulin loses effect no matter the concentration – body becomes resistant to insulin and then insulin secreting beta cells eventually get burnt out. (see first: glucose intolerance, and obese changes to overt diabetes + increased insulin to diabetes + decreased insulin)

Question 77

IDDM facts: % of total diabetics, age at onset, body build, severity, insulin dependency, oral hypoglycemic effect?

Answer 77

• %: 5-10 of total diabetics
• 15 yo age at onset
• body build: normal to thin
• severity: severe
• insulin dependency: almost all
• oral hypoglycemics: few respond

Question 78

NIDDM facts: % of total diabetics, age at onset, body build, severity, insulin dependency, oral hypoglycemic effect?

Answer 78

• %: 85-90% of total diabetics
• 40+ age at onset
• obese body build
• severity: mild
• insulin dependency: 25-30%
• oral hypoglycemics: 50% respond

Question 79

Ketoacidosis in IDDM and NIDDM?

Answer 79

• common in IDDM

- uncommon in NIDDM

Question 80

Onset of disease of IDDM and NIDDM?

Answer 80

• rapid in IDDM

- slow in NIDDM

Question 81

Complication and stability in IDDM and NIDDM?

Answer 81

• IDDM: 90% in 20 years, unstable

- NIDDM: less common, stable

Question 82

Family history factor in IDDM and NIDDM?

Answer 82

• IDDM: common

NIDDM: more common

Question 83

Insulin receptor defects in IDDM and NIDDM?

Answer 83

• IDDM: uncommon

- NIDDM: common (resistance)

Question 84

What is diabetic ketoacidosis and who is it most commonly seen in?

Answer 84

• most commonly seen in type 1
• can happen with type 2 though
• onset: hours to days
• defined as being present with absolute or relative insulin deficiency when the following criteria are met:
• blood glucose levels> 250
• ketosis: ketones in urine and blood
• Acidosis: pH

Question 85

Associated metabolic and plasma abnormalities in DKA?

Answer 85

• dehydration
• increased osmolality (15): metabolic acidosis
• increased serum amylase
• elevated white count (if infection is the culprit)
• hyperTGemia

Question 86

Pathophysiology of DKA?

Answer 86

• stress on the body this results in increase of catecholamines and increase GH - this leads to increase glucagon and decreased insulin which then causes hyperglycemia + ketosis - leads to osmotic diuresis, dehydration and metabolic acidosis

Question 87

Precipitating factors in DKA?

Answer 87

• infection, new onset diabetes, insulin admin, stress

- (first onset of type 1 could be ketoacidosis)

Question 88

Sxs of DKA?

Answer 88

• N/V
• thirst, polydypsia
• polyuria
• abdominal pain
• weakness
• fatigue
• anorexia

Question 89

Signs of DKA?

Answer 89

• tachycardia
• orthostatic hypotension
• poor skin turgo
• dry skin and mucous membranes
• kussmaul’s respirations
• hypothermia
• fruity breath (ketones)
• altered mental status or coma

Question 90

At what plasma osomolarity do you go from alert to obtunded, stuperous, comatose?

Answer 90

• alert: 315
• obtunded: 321
• stuperous: 343
• comatose: 369

Question 91

What counter regulatory hormones can cause hyperglycemia (DKA) in increased amounts?
What else occurs in DKA?

Answer 91

• cortisol
• GH
• glucagon
• Epi
• increased insulin deficiency
• decreased peripheral glucose utilization

Question 92

electrolyte osmolarity shifts in DKA?

Answer 92

• hyperosmolarity due to increased blood glucose levels
• osmotic diuresis leads to dehydration
• hyperosmolar state leads to water shift and K+ from intracellular to extracellular
• serum Na+ is low to normal despite diuresis
• serum K+ is normal or elevated (d/t intracellular fluid shift)
• metabolic acidosis from ketone production leads to marked decrease in serum bicarb

Question 93

Production of ketones in DKA?

Answer 93

• body breaks down free FAs to try to utilize as energy, leading to produciton of ketones
• increased breakdown of fatty acids also leads to hypertriglyceridemia
• anion gap: be on CMP

Question 94

What should you order if you suspect DKA?

Answer 94

• CMP
• serum osmolarity
• lipid profile
• amylase/lipase
• CBC with diff
• serum acetone
• urine glucose/ketones
• EKG, CXR
• ABGs

Question 95

What are the goals of therapy in DKA? restoring circulatory volume -

Answer 95

• restore cirulatory volume:
  NS or 1/2 NS: depending on NA+ level
• 1 L/hr x 2 hours
• 250-500 ml/hr for 2-4 hours
• watch serum Na+ may need to switch IV to 1/2 NS
• fluid replacement will lower blood glucose levels thru dilution, lower osmolarity and ketones and improve peripheral utilization of ketones and glucose
• switch to 5% dextrose solution when glucose is

Question 96

Goals of therapy - insulin therapy?

Answer 96

• insulin therapy: 10 U IV bolus of regular insulin
• cont. insulin drip at 6 U/hr or 0.1U/kg/hr
• dont decrease serum glucose too fast
• check blood sugars hourly
• insulin facilitates peripheral uptake of ketones and glucose and inhibits hepatic glucose production

Question 97

Goals of therapy for DKA: K+ replacement?

Answer 97

• K+ level will be normal or high at first
• dilution of plasma with fluid admin will lower K+
• K+ will follow insulin and glucose into cell
• K+ replacement based on q 2 hr serum measurements
• initially replace with K+ boluses
• eventually can add K+ to IV solution

Question 98

Bicarb replacement? When should it happen?

Answer 98

• use with extreme caution and only consider if pH

Question 99

DKA pt: When should insulin be changes to SQ?

Answer 99

• when the pt can eat and drink

Question 100

What is hyperglycemic hyperosmolar nonketotic syndrome?

Answer 100

• occurs almost exclusively in type 2
• elderly and physically impaired
• limited access to free water
• dist. from DKA by:
  high hyperglycemia more than 600
  relative absence of acidosis and ketones
  greater degree of dehydration

Question 101

Signs and symptoms of hyperglycemic hyperosmolar nonketotic syndrome?

Answer 101

• severe dehydration:
  dry skin and mucous membranes, extreme thirst
• Neuro signs:
  lethargy to coma
  sensory impairment
  seizures
  hyperthermia (could be mistaken for a stroke)

Question 102

Lab findings in Hyperglycemic hyperosmorlar nonketotic syndrome?

Answer 102

• blood glucose of more than 600
• serum osmolarity greater than 320
• serum Na+ normal to high (135-145)
• serum K+ normal 94-5)
• serum bicarb ( greater than 15)
• pH greater than 7.3
• ketones: negative
• can be complicated by thromboembolic events arising because of high serum osmolarity
• prognosis less favorable than DKA

Question 103

Tx of hyperglycemic hyperosmolar nonketotic syndrome?

Answer 103

• tx:
  IV fluid replacement - slower rate than DKA, greater volume needed, rehydrate over 36-72 hours, pts usually older and have co-morbidities
• insulin replacement starts after rehydration is in progress: more sensitve to insulin so may need to lower doses
• heparin: prophylaxis d/t predisposition to vascular thrombosis from hyperosmol state