Exam (elaborations) NR 601 Week 6 Quiz Review of Week 5 Diabetes (NR601)
NR 601: Week 6 Quiz Review
Week 5
Diabetes
· ADA screening recommendations:
... [Show More] when to screen to repeat screens based on findings
Recommendations
Screening for type 2 diabetes with an informal assessment of risk factors or validated tools should be
considered in asymptomatic adults. B
Testing for type 2 diabetes in asymptomatic people should be considered in adults of any age who are
over- weight or obese (BMI >25 kg/m2 or $23 kg/m2 in Asian Americans) and who have one or more
additional risk factors for diabetes. B
For all people, testing should be- gin at age 45 years. B
If tests are normal, repeat testing carried out at a minimum of 3-year intervals is reasonable. C
To test for type 2 diabetes, fasting plasma glucose, 2-h plasma glucose after 75-g oral glucose tolerance
test, and A1C are equally appropriate. B
In patients with diabetes, identify and treat other cardiovascular disease risk factors.
Updated recommendations emphasize that testing for prediabetes and type 2 diabetes should be
considered in children and adolescents younger than 18 years of age who are overweight or obese (BMI
>85th percentile for age and sex, weight for height >85th percentile, or weight >120% of ideal for height),
and have one or more additional risk factors for diabetes such as (1) maternal history of diabetes or
gestational diabetes during the child’s gestation; (2) family history of type 2 diabetes in first- or seconddegree
relative; (3) race/ethnicity (Native American, African American, Latino, Asian American, Pacific
Islander; and/or (4) signs of insulin resistance or conditions associated with insulin resistance (acanthosis
nigricans, hypertension, dyslipidemia, polycystic ovary syndrome, or small-
DIAGNOSTIC TESTS FOR DIABETES
Diabetes may be diagnosed based on plasma glucose criteria, either the fasting plasma glucose (FPG) or
the 2-h plasma glucose (2-h PG) value after a 75-g oral glucose tolerance test (OGTT) or A1C criteria
(1,6) (Table 2.2).
FPG, 2-h PG after 75-g OGTT, and A1C are equally appropriate for diagnostic testing. It should be noted
that the tests do not necessarily detect diabetes in the same individuals. The efficacy of
interventions for primary prevention of type 2 diabetes (7,8) has primarily been demonstrated among
individuals with impaired glucose tolerance (IGT), not for individuals with isolated impaired fasting glucose
(IFG) or for those with prediabetes defined by A1C criteria.
The same tests may be used to screen for and diagnose diabetes and to detect individuals with
prediabetes. Diabetes may be identified anywhere along the spectrum of clinical scenarios: in seemingly
low-risk individuals who happen to have glucose testing, in individuals tested based on diabetes risk
assessment, and in symptomatic patients.
Fasting and 2-Hour Plasma Glucose
The FPG and 2-h PG may be used to diagnose diabetes (Table 2.2). The concordance between the FPG
and 2-h PG tests is imperfect, as is the concordance be- tween A1C and either glucose-based test.
Numerous studies have confirmed that, compared with FPG and A1C cut points, the 2-h PG value
diagnoses more people with diabetes.
A1C
The A1C test should be performed using a method that is certified by the NGSP () and
standardized or traceable to the Diabetes Control and Complications Trial (DCCT) reference as- say.
NR 601 Week 6 Quiz Review of
Week 5 Diabetes
Although point-of-care A1C assays may be NGSP certified, proficiency testing is not mandated for
performing the test, so use of point-of-care assays for diagnostic purposes is not recommended but may
be considered in the future if proficiency testing is performed and documented.
The A1C has several advantages com- pared with the FPG and OGTT, including greater convenience
(fasting not required), greater preanalytical stability, and less day-to-day perturbations during stress and
illness. However, these
advantages may be offset by the lower sensitivity of A1C at the designated cut point, greater cost, limited
availability of A1C testing in certain regions of the developing world, and the imperfect correlation
between A1C and average glucose in certain individuals. National Health and Nutrition Examination
Survey (NHANES) data indicate that an A1C cut point of $6.5% (48 mmol/mol) identifies one-third fewer
cases of undiagnosed diabetes than a fasting glucose cut point of $126 mg/dL (7.0 mmol/L) (9).
When using A1C to diagnose diabetes, it is important to recognize that A1C is an indirect measure of
average blood glucose levels and to take other factors into consideration that may impact hemoglobin
glycation independently of glycemia including age, race/ethnicity, and anemia/ hemoglobinopathies.
Confirming the Diagnosis
Unless there is a clear clinical diagnosis (e.g., patient in a hyperglycemic crisis or with classic symptoms
of hyperglycemia and a random plasma glucose $200 mg/dL [11.1 mmol/L]), a second test is required for
confirmation. It is recommended that the same test be repeated without delay using a new blood sample
for confirmation because there will be a greater likelihood of concurrence. For ex- ample, if the A1C is
7.0% (53 mmol/mol) and a repeat result is 6.8% (51 mmol/mol), the diagnosis of diabetes is confirmed. If
two different tests (such as A1C and FPG) are both above the diagnostic threshold, this also confirms the
diagnosis. On the other hand, if a patient has discordant results from two different tests, then the test
result that is above the diagnostic cut point should be repeated. The diagnosis is made on the basis of the
confirmed test. For example, if a patient meets the diabetes criterion of the A1C (two results $6.5% [48
mmol/mol]) but not
FPG (,126 mg/dL [7.0 mmol/L]), that person should nevertheless be considered to have diabetes.
Since all the tests have preanalytic and analytic variability, it is possible that an abnormal result (i.e.,
above the diagnostic threshold), when repeated, will produce a value below the diagnostic cut point. This
scenario is likely for FPG and 2-h PG if the glucose samples remain at room temperature and are not
centrifuged promptly. Because of the potential for preanalytic variability, it is critical that samples for
plasma glucose be spun and separated immediately after they are drawn. If patients have test results
near the margins of the diagnostic threshold, the health care professional should follow the patient closely
and repeat the test in 3–6 months.
Description
In 1997 and 2003, the Expert Committee on the Diagnosis and Classification of Diabetes Mellitus (17,18)
recognized a group of individuals whose glucose levels did not meet the criteria for diabetes but were too
high to be considered nor- mal. “Prediabetes” is the term used for individuals with IFG and/or IGT and/or
A1C 5.7–6.4% (39–47 mmol/mol). Pre- diabetes should not be viewed as a clinical entity in its own right
but rather as an increased risk for diabetes (Table 2.3) and cardiovascular disease (CVD). Prediabetes is
associated with obesity (especially abdominal or visceral obesity), dyslipidemia with high triglycerides
and/or low HDL cholesterol, and hypertension.
Diagnosis
The Expert Committee on the Diagnosis and Classification of Diabetes Mellitus (17,18) defined IFG as
FPG levels be- tween 100 and 125 mg/dL (between 5.6 and 6.9 mmol/L) and IGT as 2-h PG after 75-g
OGTT levels between 140 and 199 mg/dL (between 7.8 and 11.0 mmol/L). It should be noted that the
World Health Organization (WHO) and numerous other diabetes organizations define the IFG cutoff at
110 mg/dL (6.1 mmol/L).
As with the glucose measures, several prospective studies that used A1C to predict the progression to
diabetes as defined by A1C criteria demonstrated a strong, continuous association between A1C and
subsequent diabetes. In a systematic review of 44,203 individuals from 16 cohort studies with a follow-up
interval averaging 5.6 years (range 2.8– 12 years), those with A1C between 5.5 and 6.0% (between 37
and 42 mmol/mol) had a substantially increased risk of diabetes (5-year incidence from 9 to 25%). An
A1C range of 6.0–6.5% (42–48 mmol/mol) had a 5-year risk of developing diabetes between 25 and 50%
and a relative risk 20 times higher compared with A1C of 5.0% (31 mmol/mol) (19). In a communitybased
study of African American and non-Hispanic white adults without diabetes, baseline A1C was a
stronger predictor of subsequent diabetes and cardiovascular events than fasting glucose (20). Other
analyses suggest that A1C of 5.7% (39 mmol/mol) or higher is associated with a diabetes risk similar to
that of the high-risk participants in the Diabetes Prevention Program (DPP) (21), and A1C at baseline was
a strong predictor of the development of glucose- defined diabetes during the DPP and its follow-up (22).
Hence, it is reasonable to consider an A1C range of 5.7–6.4% (39–47 mmol/mol) as identifying individuals
with prediabetes. Similar to those with IFG and/or IGT, individuals with A1C of 5.7–6.4% (39– 47
mmol/mol) should be informed of their increased risk for diabetes and CVD and counseled about effective
strategies to lower their risks (see Section 5 “Prevention or Delay of Type 2 Diabetes”). Similar to glucose
measurements, the continuum of risk is curvilinear, so as A1C rises, the diabetes risk rises
disproportionately (19). Aggressive interventions and vigilant follow-up should be pursued for those
considered at very high risk (e.g., those with A1C .6.0% [42 mmol/mol]).
· Guideline recommendations to start medications
recommendations
A complete medical evaluation should be performed at the initial visit to
- Confirm the diagnosis and classify diabetes.
- Detect diabetes complications and potential comorbid conditions.
- Review previous treatment and risk factor control in patients with established diabetes.
- Begin patient engagement in the formulation of a care management plan.
- Develop a plan for continuing care.
Recommendations
- Provide routine vaccinations for children and adults with diabetes according to age-related
recommendations. C
- Annual vaccination against influenza is recommended for all persons with diabetes $6 months of age.
- Vaccination against pneumonia is recommended for all people with diabetes 2 through 64 years of age
with pneumococcal polysaccharide vaccine (PPSV23). At age $65 years, administer the pneumococcal
conjugate vaccine (PCV13) at least 1 year after vaccination with PPSV23, followed by another dose of
vaccine PPSV23 at least 1 year after PCV13 and at least 5 years after the last dose of PPSV23.
- Administer 3-dose series of hepatitis B vaccine to unvaccinated adults with diabetes who are age 19–59
years.
- Consider administering 3-dose series of hepatitis B vaccine to un- vaccinated adults with diabetes who
are age $60 years.
First line medication options and medication side effects
Recommendations
- Metformin, if not contraindicated and if tolerated, is the preferred initial pharmacologic agent for the
treatment of type 2 diabetes.
- Long-term use of metformin may be associated with biochemical vitamin B12 deficiency, and periodic
measurement of vitamin B12 levels should be considered in metformin-treated patients, especially in
those with anemia or peripheral neuropathy. B
- Consider initiating insulin therapy (with or without additional agents) in patients with newly diagnosed
type 2 diabetes who are symptomatic and/or have A1C $10% (86 mmol/mol) and/or blood glucose levels
$300 mg/dL (16.7 mmol/L).
If noninsulin monotherapy at maximum tolerated dose does not achieve or maintain the A1C target after 3
months, add a second oral agent, a glucagon-like peptide 1 receptor agonist, or basal insulin.
- A patient-centered approach should be used to guide the choice of pharmacologic agents.
Considerations include efficacy, hypoglycemia risk, impact on weight, potential side ef- fects, cost, and
patient preferences.
- For patients with type 2 diabetes who are not achieving glycemic goals, insulin therapy should not be
delayed.
- In patients with long-standing suboptimally controlled type 2 diabetes and established atherosclerotic
cardiovascular disease, empagliflozin or liraglutide should be considered as they have been shown to
reduce cardiovascular and all-cause mortality when added to standard care. Ongoing studies are
investigating the cardio- vascular benefits of other agents in these drug classes.
Initial Therapy
Metformin monotherapy should be started at diagnosis of type 2 diabetes unless there are
contraindications. Metformin is effective and safe, is inexpensive, and may reduce risk of cardiovascular
events and death (22). Metformin may be safely used in patients with estimated glomerular filtration rate
(eGFR) as low as 30 mL/min/1.73 m2 (23), and the U.S. label for metformin was recently re- vised to
reflect its safety in patients with eGFR $30 mL/min/1.73 m2 (24). Patients should be advised to stop the
medication in cases of nausea, vomiting, or dehydration. Metformin is associated with vitamin B12
deficiency, with a recent report from the Diabetes Prevention Pro- gram Outcomes Study (DPPOS)
suggesting that periodic testing of vitamin B12 levels should be considered in metformin-treated patients,
especially in those with anemia or peripheral neuropathy (25).
In patients with metformin contraindications or intolerance, consider an initial drug from another class
depicted in Fig. 8.1 under “Dual Therapy” and proceed accordingly. When A1C is $9% (75 mmol/mol),
consider initiating dual combination therapy (Fig. 8.1) to more expeditiously achieve the target A1C level.
Insulin has the advantage of being
effective where other agents may not be and should be considered as part of any combination regimen
when hyperglycemia is severe, especially if symptoms are pre- sent or any catabolic features (weight
loss, ketosis) are present. Consider initiating combination insulin injectable therapy (Fig. 8.2) when blood
glucose is $300 mg/dL (16.7 mmol/L) or A1C is $10% (86 mmol/mol) or if the patient has symptoms of
hyperglycemia (i.e., polyuria or polydipsia). As the patient’s glucose toxicity resolves, the regimen may,
potentially, be simplified.
Combination Therapy
Although there are numerous trials com- paring dual therapy with metformin alone, ew directly compare
drugs as add-on therapy. A comparative effectiveness meta- analysis (23) suggests that each new class
of noninsulin agents added to initial therapy generally lowers A1C approximately 0.9–1.1%.
If the A1C target is not achieved after approximately 3 months, consider a combination of metformin and
one of
the six available treatment options: sulfonylurea, thiazolidinedione, DPP-4 inhibitor, SGLT2 inhibitor, GLP-
1 receptor agonist, or basal insulin (Fig. 8.1). If A1C target is still not achieved after ;3 months of dual
therapy, proceed to three-drug combination (Fig. 8.1). Again, if A1C target is not achieved after 3 months
of triple therapy, proceed to combination injectable therapy (Fig. 8.2).
Drug choice is based on patient preferences (26), as well as various patient, disease, and drug
characteristics, with the goal of reducing blood glucose levels while minimizing side effects, especially
hypoglycemia. Table 8.1 lists drugs commonly used in the U.S. Cost-effectiveness models have
suggested that some of the newer agents may be of relatively lower clinical utility based on high cost and
moderate glycemic effect (27). Table 8.2 provides cost information for currently approved noninsulin
therapies. Of note, prices listed are average wholesale prices (AWP) and do not account for discounts,
rebates, or other price adjustments often involved in prescription sales that affect the actual cost incurred
by the patient. While there are alternative means to estimate medication prices, AWP was utilized to
provide a comparison of list prices with the primary goal of highlighting the importance of cost
considerations when pre- scribing antihyperglycemic treatments. The ongoing Glycemia Reduction
Approaches in Diabetes: A Comparative Effectiveness Study (GRADE) will compare four drug classes
(sulfonylurea, DPP-4 inhibitor, GLP-1 receptor agonist, and basal insulin) when added to metformin
therapy over 4 years on glycemic control and other medical, psychosocial, and health economic
outcomes (28).
Rapid-acting secretagogues (meglitinides) may be used instead of sulfonylureas in patients with sulfa
allergies, irregular meal schedules, or those who develop late postprandial hypoglycemia when taking a
sulfonylurea. Other drugs not shown in Fig. 8.1 (e.g., inhaled insulin, a-glucosidase inhibitors,
colesevelam, bromocriptine, and pramlintide) may be tried in specific situations but are not often used due
to modest efficacy in type 2 diabetes, the frequency of administration, the potential for drug interactions,
and/or side effects.
· 2017 HTN guidelines recommended BP ranges for diabetic patients
Diabetes mellitus (DM) and hypertension: Antihypertensive drug treatment should be
initiated at a BP ≥130/80 mm Hg with a treatment goal of <130/80 mm Hg. In adults with
DM and hypertension, all first-line classes of antihypertensive agents (i.e., diuretics, ACE
inhibitors, ARBs, and CCBs) are useful and effective. ACE inhibitors or ARBs may be
considered in the presence of albuminuria.
Subjective signs of hypoglycemia and hyperglycemia
● An irregular heart rhythm
● Fatigue
● Pale skin
● Shakiness
● Anxiety
● Sweating
● Hunger
● Irritability
● Tingling sensation around the mouth
● Crying out during sleep
● Confusion, abnormal behavior or both, such as the inability to complete routine tasks
● Visual disturbances, such as blurred vision
● Seizures
● Loss of consciousness
Physical signs of elevated glucose you might see on exam
● Increased thirst and/or hunger
● Frequent urination
● Sugar in your urine
● Headache
● Blurred vision
● Fatigue
● High level of ketones in the urine
● Shortness of breath
● Fruit-smelling breath
● Dry mouth
Week 6
GU
· Incontinence in men and women- common causes and types of incontinence
Causes
Urinary incontinence (UI), the involuntary loss of urine, has a prevalence of approximately
25% in young women (aged 14 to 21 years) (1), 44% to 57% in middle-aged and
postmenopausal women (aged 40 to 60 years) (2), and 75% in elderly women (aged ≥75
years) (3). However, these statistics may be underestimated because one study showed that
at least half of incontinent women do not report the issue to their physicians (4). Risk factors
for UI include pregnancy, pelvic floor trauma after vaginal delivery, menopause,
hysterectomy, obesity, urinary tract infection, functional and/or cognitive impairment,
chronic cough, and constipation (5). The effects of UI range from slightly bothersome to
debilitating. Urinary incontinence also contributes to high medical spending—approximately
$19.5 billion was spent in the United States in 2004—and it accounts for 6% of nursing home
admissions for elderly women, costing approximately $3 billion (6).
Types – From Harvard Health & Guideline
The 2 types of UI are based on the dysfunctional mechanism: stress and urgency. However, the
distinction is not always clear, particularly for older women. Stress UI is related to urethral sphincter failure
associated with intra-abdominal pressure and results in the inability to retain urine when laughing,
coughing, or sneezing (7). Urgency UI is the involuntary loss of urine associated with a sudden and
compelling urge to void (7).
Mixed UI is a combination of stress and urgency UI. Overactive bladder is a constellation of symptoms
that includes urinary urgency (with or without UI), usually accompanied by frequency, and nocturia (5).
Stress incontinence
If urine leaks out when you jump, cough, or laugh, you may have stress incontinence. Any physical
exertion that increases abdominal pressure also puts pressure on the bladder. The word "stress" actually
refers to the physical strain associated with leakage. Although it can be emotionally distressing, the
condition has nothing to do with emotion. Often only a small amount of urine leaks out. In more severe
cases, the pressure of a full bladder overcomes the body's ability to hold in urine. The leakage occurs
even though the bladder muscles are not contracting and you don't feel the urge to urinate.
Stress incontinence occurs when the urethral sphincter, the pelvic floor muscles, or both these structures
have been weakened or damaged and cannot dependably hold in urine. Stress incontinence is divided
into two subtypes. In urethral hypermobility, the bladder and urethra shift downward when abdominal
pressure rises, and there is no hammock-like support for the urethra to be compressed against to keep it
closed. In intrinsic sphincter deficiency, problems in the urinary sphincter interfere with full closure or allow
the sphincter to pop open under pressure. Many experts believe that women who have delivered vaginally
are most likely to develop stress incontinence because giving birth has stretched and possibly damaged
the pelvic floor muscles and nerves. Generally, the larger the baby, the longer the labor, the older the
mother, and the greater the number of births, the more likely that incontinence will result.
Age is likewise a factor in stress incontinence. As a woman gets older, the muscles in her pelvic floor and
urethra weaken, and it takes less pressure for the urethra to open and allow leakage. Estrogen can also
play some role, although it is not clear how much. Many women do not experience symptoms until after
menopause.
Overactive bladder (urge incontinence)
If you feel a strong urge to urinate even when your bladder isn't full, your incontinence might be related to
overactive bladder, sometimes called urge incontinence. This condition occurs in both men and women
and involves an overwhelming urge to urinate immediately, frequently followed by loss of urine before you
can reach a bathroom.
Even if you never have an accident, urgency and urinary frequency can interfere with work and a social
life because of the need to keep running to the bathroom.
Urgency is caused when the bladder muscle, the detrusor, begins to contract and signals a need to
urinate, even when the bladder is not full. Another name for this phenomenon is detrusor overactivity.
Overactive bladder can result from physical problems that keep your body from halting involuntary
bladder muscle contractions. Such problems include damage to the brain, the spine, or the nerves
extending from the spine to the bladder — for example, from an accident, diabetes, or neurological
disease. Irritating substances within the bladder, such as those produced during an infection, might also
cause the bladder muscle to contract.
Often there is no identifiable cause for overactive bladder, but people are more likely to develop the
problem as they age. Postmenopausal women, in particular, tend to develop this condition, perhaps
because of age-related changes in the bladder lining and muscle. African American women with
incontinence are more likely to report symptoms of overactive bladder than stress incontinence, while the
reverse is true in white women.
A condition called myofascial pelvic pain syndrome has been identified with symptoms that include
overactive bladder accompanied by pain in the pelvic area or a sense of aching, heaviness, or burning.
In addition, infections of the urinary tract, bladder, or prostate can cause temporary urgency. Partial
blockage of the urinary tract by a bladder stone, a tumor (rarely), or, in men, an enlarged prostate (a
condition known as benign prostatic hyperplasia, or BPH) can cause urgency, frequency, and sometimes
urge incontinence. Surgery for prostate cancer or BPH can trigger symptoms of overactive bladder, as
can freezing (cryotherapy) and radiation seed treatment (brachytherapy) for prostate cancer.
Neurological diseases (such as Parkinson's disease and multiple sclerosis) can also result in urge
incontinence, as can a stroke. When hospitalized following a stroke, 40% to 60% of patients have
incontinence; by the time they are discharged, 25% still have it, and one year later, 15% do.
Overflow incontinence
If your bladder never completely empties, you might experience urine leakage, with or without feeling a
need to go. Overflow incontinence occurs when something blocks urine from flowing normally out of the
bladder, as in the case of prostate enlargement that partially closes off the urethra. It can also occur in
both men and women if the bladder muscle becomes underactive (the opposite of an overactive bladder)
so you don't feel an urge to urinate. Eventually the bladder becomes overfilled, or distended, pulling the
urethra open and allowing urine to leak out. The bladder might also spasm at random times, causing
leakage. This condition is sometimes related to diabetes or cardiovascular disease.
Men are much more frequently diagnosed with overflow incontinence than women because it is often
caused by prostate-related conditions. In addition to enlarged prostate, other possible causes of urine
blockage include tumors, bladder stones, or scar tissue. If a woman has severe prolapse of her uterus or
bladder (meaning that the organ has dropped out of its proper position), her urethra can become kinked
like a bent garden hose, interfering with the flow of urine.
Nerve damage (from injuries, childbirth, past surgeries, or diseases such as diabetes, multiple sclerosis,
or shingles) and aging often prevent the bladder muscle from contracting normally. Medications that
prevent bladder muscle contraction or that make you unaware of the urge to urinate can also result in
overflow incontinence.
Functional incontinence
If your urinary tract is functioning properly but other illnesses or disabilities are preventing you from
staying dry, you might have what is known as functional incontinence.
For example, if an illness rendered you unaware or unconcerned about the need to find a toilet, you would
become incontinent. Medications, dementia, or mental illness can decrease awareness of the need to find
a toilet.
Even if your urinary system is fine, it can be extremely difficult for you to avoid accidents if you have
trouble getting to a toilet. This problem can affect anyone with a condition that makes it excessively
difficult to move to the bathroom and undress in time. This includes problems as diverse as having
arthritis, being hospitalized or restrained, or having a toilet located too far away.
If a medication (such as a diuretic used to treat high blood pressure or heart failure) causes you to
produce abnormally large amounts of urine, you could develop incontinence that requires a change in
treatment. If you make most of your urine at night, the result might be nocturnal incontinence, or
bedwetting.
Reflex incontinence
Reflex incontinence occurs when the bladder muscle contracts and urine leaks (often in large amounts)
without any warning or urge. This can happen as a result of damage to the nerves that normally warn the
brain that the bladder is filling. Reflex incontinence usually appears in people with serious neurological
impairment from multiple sclerosis, spinal cord injury, other injuries, or damage from surgery or radiation
treatment
· Diagnoses which present as urinary difficulty in men
Type of Problem Etiology Treatment
Pyelonephritis Coliform
organisms
Quinolones; aminoglycosides plus ampicillin (Principen);
third-generation cephalosporins; piperacillin (Pipracil)
Cystitis Coliform
organisms
Trimethoprim-sulfamethoxazole (Bactrim), quinolones,
cephalosporins, nitrofurantoin (Furadantin), amoxicillin
(Amoxil)
Urethritis Neisseria
gonorrhoeae,
Chlamydia
trachomatis
Ceftriaxone (Rocephin) plus doxycycline (Vibramycin);
macrolides; quinolones
Prostatitis Coliform
organisms
Quinolones, doxycycline, trimethoprim-sulfamethoxazole
Epididymoorchit
is
Coliform
organisms,
viruses (e.g.,
mumps virus)
Quinolones, doxycycline, trimethoprim-sulfamethoxazole
Meatitis and
urethritis
Herpes simplex
virus II
Acyclovir (Zovirax), famciclovir (Famvir), valacyclovir
(Valtrex)
Obstruction
Benign
prostatic
hyperplasia
Age and
androgens
Alpha blockers, finasteride (Proscar), hyperthermia
therapy, surgery
Urethral
stricture
Previous surgery Dilation, surgery
Malignancy
Renal cell
tumor
Unknown Surgery, chemotherapy
Bladder cancer Smoking, aniline
dye exposure
Surgery, radiation therapy, chemotherapy
Stone disease Metabolic
disorders,
infection
Hydration, pain management, antibiotics (if infection is
present), correction of metabolic defects (e.g., allopurinol
[Zyloprim] for hyperuricemia)
Spondyloarthropathy
Behçet's
syndrome
Unknown Anti-inflammatory drugs, immunosuppressants
Reiter's
syndrome
Unknown Anti-inflammatory drugs, immunosuppressants
Toxicity or drug
side effects
Dopamine,
cantharidin and
others
Avoidance
*—Exact treatment varies, depending on patient and antibiotic sensitivities.
· BPH: diagnosis testing, common medications (including most common side effects) and
recommended follow up
Diagnosis
Diagnosis of BPH often rules out other clinical manifestations that may present with similar symptoms.
Examples include prostate cancer, prostatitis, bladder cancer, bladder stones, overactive bladder (OAB),
interstitial cystitis, and urinary tract infections; all of which may also cause LUTS.3 Although symptoms
related to BPH are often not life-threatening, they can be debilitating and affect quality of life (QOL)
significantly. Thus, it is important to identify and correctly diagnose BPH in order to pursue an effective
treatment strategy.
The American Urological Association (AUA) guideline panel made several recommendations for the
diagnosis of BPH that were consistent with an article published by Abrams et al in 2009.2,4 The
recommendations state that a basic evaluation should be performed on patients who are experiencing
negative changes in their QOL due to LUTS. This evaluation may include several components, which are
summarized in FIGURE 1. If the initial evaluation shows the presence of LUTS associated with one or
more of the digital rectal examination (DRE) findings suspicious of prostate cancer, hematuria, abnormal
prostate-specific antigen (PSA), pain, recurrent infection (infection should be assessed before referral),
palpable bladder, or neurologic disease, the patient should be referred to a urologist for additional
evaluation before pursuing treatment.
Medications
If lifestyle modifications are insufficient in improving QOL, then pharmacotherapy may be indicated in
patients who do not have absolute indications warranting surgery.5 Current oral pharmacotherapy options
for managing BPH include: alpha-adrenergic antagonists (alpha-blockers:
- Alfuzosin (Uroxatral), Doxazosin (Cardura), Tamsulosin (Flomax, Terazosin (Hytrin), Silodosin (Rapaflo),
- 5-alpha-reductase inhibitors (5ARIs): Dutasteride (Avodart), Finasteride (Proscar)
- muscarinic receptor antagonists (MRAs): Tolterodine (Detrol), Tolerodine (Detrol LA), Festerodine
(Toviaz)
- phosphodiesterase 5 (PDE5) inhibitors: Tadalafil (Cialis)
- Anticholinergics
- Combination therapy
Follow up
Watchful waiting is appropriate in patients who do not need surgery.
Side Effects
Alpha blockers – ED, abnormal ejaculation, dizziness, HA, orthostatic hypotension, fatigue, infection, QT
interval prolongation, polydipsia, IFIS
55AR’s – Libido impairment, abnormal ejaculation, erectile dysfunction, mastalgia, gynecomastia
MRA’s – Xerostomia (dry mouth)
PDE5 inhibitors – Back pain, dyspepsia, flushing, myalgia, nausea, pharyngitis, nausea, pharyngitis
· Prostatitis signs & symptoms, assessment and treatment
Signs & Symptoms
Prostatitis signs and symptoms depend on the cause. They can include:
● Pain or burning sensation when urinating (dysuria)
● Difficulty urinating, such as dribbling or hesitant urination
● Frequent urination, particularly at night (nocturia)
● Urgent need to urinate
● Cloudy urine
● Blood in the urine
● Pain in the abdomen, groin or lower back
● Pain in the area between the scrotum and rectum (perineum)
● Pain or discomfort of the penis or testicles
● Painful ejaculation
● Flu-like signs and symptoms (with bacterial prostatitis)
CLINICAL PRESENTATION
The diagnosis of acute bacterial prostatitis is often based on symptoms alone. Urinary symptoms may be
irritative (e.g., urinary frequency, urgency, dysuria) or obstructive (e.g., hesitancy, poor or interrupted
stream, straining to void, incomplete emptying). Pain may be present in the suprapubic or perineal region,
or in the external genitalia. Systemic symptoms of fever, chills, malaise, nausea, emesis, and signs of
sepsis (tachycardia and hypotension) may be present as well. On physical examination, the prostate
should be gently palpated. Prostatic massage should not be performed and may be harmful
14
; the
prostate is tender, enlarged, and boggy. On abdominal examination, a palpable, distended bladder
indicates urinary retention.
DIAGNOSIS
Midstream urine culture should be obtained. The presence of more than 10 white blood cells per highpower
field suggests a positive diagnosis. Other laboratory testing (e.g., CBC, electrolyte levels, blood
culture) is determined by the severity of the presentation. Residual urine should be documented if a
patient has a palpable bladder or symptoms consistent with incomplete emptying.
TREATMENT
Empiric therapy should be started at the time of evaluation (Figure 2); coverage can be tailored to the
isolated organisms once urine culture results are available. Mildly to moderately ill patients may be
treated in the outpatient setting (with TMP/SMZ 160/800 mg PO bid x 6 weeks or Cipro 500 mg PO bid x
6 weeks); severely ill patients or those with possible urosepsis require hospitalization and parenteral
antibiotics. Once patients have become afebrile, they may be transitioned to oral antibiotics based on the
culture results. Minimal duration of treatment is four weeks
15
; however, the optimal period has been
shown to be six weeks, because of the possible persistence of bacteria, with repeat evaluation
recommended at that time.
16,17
Common causes of ED
Erectile function is the result of a complex interplay between vascular, neurologic, hormonal, and
psychologic factors. The attainment and maintenance of a firm erection requires good arterial inflow of
blood as well as efficient reduction of venous outflow. Risk factors and disease processes that affect the
function of the arterial or venous systems would therefore be expected to have a negative impact on
erectile function. Since the risk of developing ED is increased in the presence of diabetes, heart disease,
and hypertension, it is logical to conclude that optimal management of these diseases may prevent the
development of ED.7,8,9 It is also logical to assume that lifestyle modifications to improve vascular function
such as avoiding smoking, maintaining ideal body weight and engaging in regular exercise might either
prevent or reverse ED, however, only minimal data exists today to support this supposition.10,11
· Physical changes related to female urinary complaints and diagnoses
Complicated versus Uncomplicated UTI
The adjectives “uncomplicated” and “complicated” are sometimes used to guide selection and duration of
antibiotic therapy (see later discussion). “Uncomplicated” UTI refers to cystitis or pyelonephritis occurring
in an otherwise healthy, nonpregnant, premenopausal women with a normal urinary tract, but some
persons with so-called complicated disease may respond to the same treatments as those designated
“uncomplicated” (see later discussion)
Acute Urethral Syndrome (Symptomatic Abacteriuria/Early Infection and Chronic Interstitial
Cystitis/Bladder Pain Syndrome)
This syndrome occurs in about 10% to 15% of women who present with symptoms suggestive of UTI but
fewer than 105 organisms per milliliter on urine culture and on urinalysis, few white blood cells (WBCs)
and no bacteria. These patients can be subdivided into two groups: those with infection and those
without.
Early Infection.
Approximately 70% have some degree of pyuria (more than two to five WBCs per high-power field) and
true infection, either with bacterial counts of fewer than 105 organisms [Show Less]