Following conditions are included in the ACC/AHA/HRS guidelines for the pacemaker insertion
In
recent cardiovascular outcome trials, SGLT2 inhibitors are associated with
30%–35% lower risk of hospitalization for heart failure. Other glucose-lowering
agents appear to be more potent than SGLT2 inhibitors, but fail to reduce
cardiovascular risk, particularly with regard to heart failure outcomes.
Moreover, although the glucose-lowering efficacy of SGLT2-inhibitor therapy
declines at lower estimated glomerular filtration rates, its cardiovascular
benefits are remarkably preserved, even in patients with renal impairment. This
implies differing mechanisms of action in glycemic control and cardiovascular
risk reduction.
Hyperparathyroidism and alterations in calcium metabolism involving hypercalcemia and/or hypo-calciuria can lead to hypermagnesemia through an increased calcium-induced magnesium absorption in the tubule. Patients with familial hypocalciuric hypercalcemia (FHH), a rare autosomal dominant condition, can manifest hypermagnesemia.
Lithium-based psychotropic drugs can also lead to hypermagnesemia by reducing excretion. Patients with milk-alkali syndrome due to the ingestion of large amounts of calcium and absorbable alkali are more susceptible to develop hypermagnesemia. Magnesium levels can increase in hemolysis patients. Red blood cells contain three times as much magnesium as compared to plasma. The rupture of these cells pours magnesium into the plasma. However, symptomatic hypermagnesemia occurs only in the case of aggressive hemolysis. Tumor lysis syndrome, rhabdomyolysis, and acidosis (e.g., decompensated diabetes with ketoacidosis) can also induce hypermagnesemia through extracellular shifts.
Summary:
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Despite its important intracellular roles, about 99% of body calcium is in bone, mainly as hydroxyapatite crystals. About 1% of bone calcium is freely exchangeable with the extracellular fluid and, therefore, is available for buffering changes in calcium balance.
Normal total serum calcium concentration ranges from 8.8 to 10.4 mg/dL. About 40% of the total blood calcium is bound to plasma proteins, primarily albumin. The remaining 60% includes ionized calcium plus calcium complexed with phosphate and citrate. Total calcium (ie, protein-bound, complexed, and ionized calcium) is usually what is determined by clinical laboratory measurement.
However, ideally, ionized (or free) calcium should be estimated or measured because it is the physiologically active form of calcium in plasma and because its blood level does not always correlate with total serum calcium.
Ionized
calcium is generally assumed to be about 50% of the total serum calcium.
Ionized calcium can be estimated, based on total serum calcium and serum albumin levels. Direct determination of ionized calcium, because of its technical difficulty, is usually restricted to patients in whom significant alteration of protein binding of serum calcium is suspected.
Normal ionized serum calcium concentration range varies somewhat between laboratories, but is typically 4.7 to 5.2 mg/dL.
Thoracic Aortic Aneurysms
PULMONARY NODULE
Evaluation is guided by nodule size & assessment
of probability of malignancy. In addition is based on the yield of available
diagnostic testing, patient comorbidities, & patient preferences. Focal
pulmonary lesions that are > 3 cm in diameter are called lung masses &
should be considered malignant until proven otherwise.
Pulmonary nodules are categorized as small solid
(<8 mm), larger solid (≥8 mm), and subsolid.
Subsolid nodules are divided into ground-glass nodules
(no solid component) and part-solid (both ground-glass and solid components).
The probability of malignancy is less than 1% for all
nodules smaller than 6 mm and 1% to 2% for nodules 6 mm to 8 mm.
Nodules that are 6 mm to 8 mm can be followed with a
repeat chest CT in 6 to 12 months, depending on the presence of patient risk
factors and imaging characteristics associated with lung malignancy, clinical
judgment about the probability of malignancy, and patient preferences.
The treatment of an individual with a solid pulmonary
nodule 8 mm or larger is based on the estimated probability of malignancy; the
presence of patient comorbidities, such as chronic obstructive pulmonary
disease and coronary artery disease; and patient preferences. Management
options include surveillance imaging, defined as monitoring for nodule growth
with chest CT imaging, positron emission tomography-CT imaging, nonsurgical
biopsy with bronchoscopy or transthoracic needle biopsy, and surgical
resection.
Part-solid pulmonary nodules are managed according to
the size of the solid component.
Larger solid components are associated with a higher risk
of malignancy.
Ground-glass pulmonary nodules have a probability of
malignancy of 10% to 50% when they persist beyond 3 months and are larger than
10 mm in diameter.
A malignant nodule that is entirely ground glass in
appearance is typically slow growing.
Current bronchoscopy and transthoracic needle biopsy
methods yield a sensitivity of 70% to 90% for a diagnosis of lung cancer.
The most common cause of hyperparathyroidism is Parathyroid adenoma. Another cause is hyperplasia of the parathyroid glands.
Parathyroid
hormone (PTH) increases serum calcium by
·
Enhancing
distal tubular calcium reabsorption
·
Rapidly
mobilizing calcium and phosphate from bone (bone resorption)
·
Increasing
intestinal absorption of calcium by stimulating conversion of vitamin D to its
most active form, calcitriol
Hyperparathyroidism
is characterized as:
·
Primary:
Excessive secretion of PTH due to a disorder of the parathyroid glands
·
Secondary:
Hypocalcemia due to non-parathyroid disorders leads to chronic PTH
hypersecretion
· Tertiary: Autonomous secretion of PTH unrelated to serum calcium concentration in patients with long-standing secondary hyperparathyroidism
Primary hyperparathyroidism: excessive secretion of PTH by one or more parathyroid glands. Incidence increases with age and is higher in postmenopausal women. Primary hyperparathyroidism causes hypercalcemia, hypophosphatemia, and excessive bone resorption (leading to osteoporosis).
Secondary
hyperparathyroidism occurs most commonly in advanced chronic kidney disease
when decreased formation of active vitamin D in the kidneys and other factors
lead to hypocalcemia and chronic stimulation of PTH secretion.
Hyperphosphatemia that develops in response to chronic kidney disease also contributes.
Other less common causes of secondary hyperparathyroidism include
·
Decreased
calcium intake
·
Poor
calcium absorption in the intestine due to vitamin D deficiency
·
Excessive
renal calcium loss due to loop diuretic use
· Inhibition of bone resorption due to bisphosphonate use
Tertiary hyperparathyroidism results when PTH secretion becomes autonomous of serum calcium concentration and generally occurs in patients with long-standing secondary hyperparathyroidism, as in patients with ESRD of several years’ duration.
Indications
of surgery:
·
Serum
calcium 1 mg/dL greater than the upper limits of normal
·
Calciuria
> 400 mg/day
·
Creatinine
clearance < 60 mL/minute
·
Peak
bone density at the hip, lumbar spine, or radius 2.5 SD below controls (T score
= −2.5)
·
Age
< 50 years
· The possibility of poor adherence with follow-up
Secondary
hyperparathyroidism in patients with renal failure can result in a number of
symptoms, including
·
Osteitis
fibrosa cystica with arthritis, bone pain, and pathologic fractures
·
Spontaneous
tendon rupture
·
Proximal
muscle weakness
·
Extra-skeletal
calcifications, including soft tissue and vascular calcification
·
Pruritis
O2
content (CaO2) = (Hgb x 1.34 x SaO2) + (0.0031 x PaO2)
where Hgb is hemoglobin concentration and SaO2 is hemoglobin saturation at the given PO2.
The principal form of oxygen transport in blood is as hemoglobin-bound.
Each
gram of hemoglobin can maximally bind 1.34 mL of oxygen.
The
oxygen-carrying capacity of the blood is calculated as = [Hb] x 1.34.
In
a healthy person, with a hemoglobin concentration of 15 g / dL blood, the
oxygen carrying capacity is 20.1 mL O2 / dL blood.
Oxygen
transport is dependent on both respiratory and circulatory function.
Total
O2 delivery (DO2) to tissues is the product of arterial O2 content and cardiac
output (CO).
DO2
= CaO2 x CO
Note
that arterial O2 content is dependent on PaO2 as well as hemoglobin
concentration. As a result, deficiencies in O2 delivery may be due to a low
PaO2, a low hemoglobin concentration, or an inadequate cardiac output.
The
Fick equation of O2 consumption
VO2 = CO x (CaO2 – CvO2)
Oxy-hemoglobin
Dissociation Curve
With a normal O2 consumption of approximately 250 ml/min and cardiac output of 5000 ml/min the normal arteriovenous difference is calculated to be about 5 ml O2/dl blood. The normal extraction ratio is approximately 25%, thus the body normally consumes only ~25% of the O2 carried on hemoglobin. When O2 demand exceeds supply, the extraction fraction exceeds 25%, and conversely, if O2 supply exceeds demand, the extraction fraction falls below 25%.
When
DO2 (oxygen delivery) is moderately reduced, VO2 usually remains normal because
of increased O2 extraction (meaning mixed venous O2 saturation decreases). With
further reductions in the DO2, a critical point is reached beyond which VO2
becomes directly proportional to DO2. This state of supply-dependent O2 is
typically associated with progressive lactic acidosis caused by cellular
hypoxia.
·
Type
1 MI is due to acute coronary atherothrombotic myocardial injury with plaque
rupture. Most patients with STEMI and many with NSTEMI comprise this category.
·
Type
2 MI is the most common type of MI encountered in clinical settings in which is
there is demand-supply mismatch resulting in myocardial ischemia. This demand
supply mismatch can be due to multiple reasons including but not limited to presence
of a fixed stable coronary obstruction, tachycardia, hypoxia or stress. Other
potential etiologies include coronary vasospasm, coronary embolus, and
spontaneous coronary artery dissection (SCAD).
·
Type
3 MI include patient with Sudden cardiac death who succumb before any troponin
elevation comprise.
·
Types
4 and 5 MIs are related to coronary revascularization procedures like PCI or CABG.
The
American College of Cardiology, American Heart Association, European Society of
Cardiology, and the World Heart Federation committee established the following
ECG criteria for ST-elevation myocardial infarction STEMI:
·
New
ST-segment elevation at the J point in 2 contiguous leads with the cutoff point
as greater than 0.1 mV in all leads other than V2 or V3
·
In
leads V2-V3 the cutoff point is greater than 0.2 mV in men older than 40 years
old and greater than 0.25 in men younger than 40 years old, or greater than
0.15 mV in women
Patients
with a pre-existing left bundle branch block can be further evaluated using
Sgarbossa's criteria:
·
ST-segment
elevation of 1 mm or more that is concordant with (in the same direction as)
the QRS complex
·
ST-segment
depression of 1 mm or more in lead V1, V2, or V3
·
ST-segment
elevation of 5 mm or more that is discordant with (in the opposite direction)
the QRS complex
John
F. Goodwin developed a classification based on structural and functional
changes.
·
Congestive
cardiomyopathy, now referred to as dilated cardiomyopathy (DCM),
·
Hypertrophic
cardiomyopathy (HCM), and
·
Constrictive
(now referred to as restrictive) cardio myopathy (RCM).
·
Arrhythmogenic
right ventricular cardiomyopathy (arrhythmogenic cardiomyopathy),
Each
of these categories was further subdivided by pathogenesis, such as secondary
to a systemic disorder, an infection, inflammation, an inherited disorder, or
idiopathic cardiomyopathies.
