Thursday, July 30, 2009

Congenital heart diseases classsification

Definition:
Congenital heart defects are heart defects that are present at birth. There are many types of congenital heart defects. The American Heart Association states that there are at least thirty-five distinct forms of Congenital Heart Defects. The main types are categorized into either acyanotic or cyanotic categories. Within these two categories are separate types.

What are the different types of congenital heart defects:
Congenital heart defects can be classified into several categories according to the problems your child may experience. They include the following:
  • Problems that cause too much blood to pass through the lungs -- These defects allow oxygen-rich (red) blood that should be traveling to the body to re-circulate through the lungs, causing increased pressure and stress in the lungs. Examples include the following:
    • patent ductus arteriosus (PDA)
    • atrial septal defect (ASD)
    • ventricular septal defect (VSD)
    • atrioventricular canal (AV canal or AVC)
  • Problems that cause too little blood to pass through the lungs — These defects allow blood that has not been to the lungs to pick up oxygen (and, therefore, is oxygen-poor) to travel to the body. The body does not receive enough oxygen with these heart problems, and the baby will be cyanotic, or "blue." Examples include the following:
    • tricuspid atresia (TA)
    • pulmonary atresia (PA)
    • transposition of the great arteries (TGA)
    • tetralogy of fallots (TOF)
  • Problems that cause too little blood to travel to the body -- These defects are a result of underdeveloped chambers of the heart or blockages in blood vessels that prevent the proper amount of blood from traveling to the body to meet its needs. Examples include:
    • coarctation of the aorta
    • aortic stenosis
    • pulmonary stenosis
  • A combination of several heart defects -- These combinations create a more complex problem that can fall into several of these categories. Complex combination of heart defects include:
    • hypoplastic left heart syndrome (HLHS)
    • truncus arteriosis
    • total anomalous pulmonary venous return (TAPVR)
Causes of congenital heart disease:

Congenital cardiovascular defects are present in about 1 percent of live births. They're the most common congenital malformations in newborns. In most cases scientists don't know why they occur. Sometimes a viral infection causes serious problems. German measles (rubella) is an example. If a woman contracts German measles while pregnant, it can interfere with how her baby's heart develops or produce other malformations. Other viral diseases also may cause congenital defects.

Heredity sometimes plays a role in congenital cardiovascular defects. More than one child in a family may have a congenital cardiovascular defect, but this rarely occurs. Certain conditions affecting multiple organs, such as Down's syndrome, can involve the heart, too. Some prescription drugs and over-the-counter medicines, as well as alcohol and "street" drugs, may increase the risk of having a baby with a heart defect. Researchers are studying other factors.

Pericardial Effusion and It's sign and symtom

Definition:
Collection Of free fluid in pericardial sac.
Normal amount -150 ml
clinical and radiologically detect -250ml
Types of Pericardial Effusion:
a. Transudate
b.Exudates- 1. Serous
2.Purulent
3. Hemorrhagic

Causes :
a. Trasudate:
-CCF
-Myxoedema
-Nephritic syndrome
-Wet Beri Beri
b. Exudate:
-Serous:
-Tuberculosis
-Myocardial infarction
-Uremia
-Rheumatic effusion
-SLE
-Connective Tissue Disease
-Purulent:
-Pyogenic infection
-staphylococci
-sterptococci
-pneumococci
-Burst mediastinal abcess, lung abcess, liver abcess into pericardial
sac
-Hemorrhagic:
- Myocardial infarction
- Malignancy
- Tuberculosis
- Stab injury or gun shot injury
-Ruptured of dissecting aneurysm or syphilitic aneurysm
-Rheumatic origin
Causes of smalll and large pericardial effusion:
a. Small :
- Initial phase of large effusion
- Heart failure
- Nephrotic syndrome
b. Large:
-Tuberculosis
-Malignancy
-Carcinoma
-Myxoedema
Symtom and Sign:
Symtom-
- no specific symtom
- Pain of pericarditis may disappear when effusion develops
-In hemorrhagic pericardial effusion there may be pain due to irrition to pericardium
-In large effusion substernal discomfort and may feel faint on sitting upright or on exertion
-Shortness of breath, palpitation
Sign-
- Small effusion does not give any specific sign
-Large effusion
a. Pulse-Tachycardia
b. Apex beat-Nor visible neither palpable
c. Increase cardiac dullness
d. Roth's Sign positive
e. Ewart's sign positive
f. on auscultation-
Faint heart sound
Pericardial friction rub may still be audible despite effusion
Bronchial breath sound beneath left scapula
Rales over lung field due to compression of lung field

Monday, July 27, 2009

Pancytopenia and its management

Introduction:
Pancytopenia is an important clinicohaematological entity encountered in our dayto-day clinical practice.Cytopenia is a reduction in the number of each type of peripheral blood cell. A reduction
in all 3 types of cellular components in peripheral blood is termed pancytopenia and this involves anaemia, neutropenia, and thrombocytopenia.Mild impairment in marrow function is inapparent.
It is apparent only during times of stress or increaseddemand (e.g., bleeding or infection).
Severe pancytopenia is defined as follows :
i) Absolute neutrophil count < 500/mm3
ii) Platelet count < 20,000/mm3
iii) Corrected reticulocyte count < 1%

Aetiopathogenesis:
Aplastic anaemia is one of the most serious causes of pancytopenia.Marrow failure leading to pancytopenia may result from immune-mediated or non-immune mediated damage or suppression of either pluripotent stem cells or committed progenitor cells.Interestingly, most cytotoxic drugs used in the treatment of malignancies exert their major effects on committed progenitor cells. Ablation of these cells result in marrow hypoplasia but recovery is still possible by regeneration from the pluripotent stem-cell compartment. Pancytopenia from bone marrow failure is also an important feature of acute leukaemias, the later stages of chronic leukaemias, myeloproliferative disorders, and myelodysplasias.

The different causes of pancytopenia due to bone
marrow failure are enumerated in Table I.
Causes of pancytopenia:
Primary Secondary
Idiopathic Drugs
Congenital/Familial Viral infections
Mycobacterial infections
Autoimmune disorders
Chemicals (benzene, arsenic)
Cytotoxics
Malignant infiltration
Paroxysmal nocturnal haemoglobinuria
Drugs causing pancytopenia:
A. Cytotoxics (by bone marrow suppression)
B. Chloramphenicol (by dose related effects)
C. Idiosyncratic response (immune mediated)
a. NSAIDs
b. Colchicine
c. Chloramphenicol
d. Sulfonamides
e. Phenothiazines
f. Thiazides
g. Anti-thyroid drugs
h. Anti-epileptics
i. Anti-diabetics
Viral infections causing pancytopenia:
1. Hepatitis B and C viruses
2. Cytomegalovirus
3. Epstein – Barr Virus
4. HIV
5. Hepatitis A virus(rare)
Clinical features:
The cardinal signs of moderate to severe pancytopenia are anaemia, bleeding, and infection.
Red blood corpuscles survive much longer than platelets or neutrophils. Thus, anaemia develops slowly.and the typical symptoms of tiredness, fatigue, puffiness of face, oedema, lassitude, and effort intolerance may not be striking in the initial phase.

The platelet count is first to be affected. Mucocutaneous bleeding is typical of thrombocytopenia with petechial haemorrhages in skin and mucous membranes.The presence of spontaneous bleeding with platelet count <20 x 109/l indicates severe marrow failure.Retinal bleeding is common and may lead to blindness.

Next to be affected is the myeloid series.Infections usually occur with commensal organisms of the skin or gastrointestinal tract.Early manifestation of neutropenia is often a sore throat or chest or soft tissue infection which typically show incomplete response to antibiotics.Thecommonest offending organisms include coliforms, klebsiella spp, pseudomonas
species, and staplylococci.


Investigations:

A. Pancytopenia and morphological changes in peripheral blood.
i) RBC changes:
Reticulocytes are markedly reduced or absent.
Stress in erythropoiesis may result in an increase in Haemoglobin F Increase in iron overload from multiple Increase in serum folate and vitamin B12 levels excludes other causes of macrocytic
anaemia.
ii) WBC changes
Blast cells may be evident in bone marrow of patients in whom pancytopenia is due to
malignant infiltration.
Morphological changes in neutrophils(absent granulation, nuclear abnormalities)
suggest preleukemia/myelodysplastic states.

iii) Platelet changes :
Mean volume of platelets (MVP) is normal.
B. Bone marrow examination :
It is indicated in all cases of pancytopenia where the underlying cause is not quite obvious. This is particularly needed to exclude leukaemia or other malignant infiltration. Routine aspiration smears may have to be combined with trephine biopsies as quite often aspiration might yield dry or bloody tap. Bone marrow examination shows diminished cellularity with increased fat cells,
reticulin cells, plasma cells, mast cells, and relative increase in lymphocytes. Trephine
biopsy better demonstrates increased fat spaces, elements of dyserythropoiesis, megaloblastosis, and nuclear cytoplasmic asynchrony.

Management :
The basic management of patients with pancytopenia involves identification and reversal of the underlying cause and adequate supportive care until normal counts are restored. It must be emphasised that bleeding and infection due to cytopenias is a medical emergency.
A. Supportive care :
This is the most important aspect of management of pancytopenia. Anaemia is corrected by transfusion of packed red cells to maintain haemoglobin (Hb) level above 8-9 gm/dl. It has been observed that retinal haemorrhage is likely to occur below this level. Blood should be administered cautiously to avoid circulatory overload. The previous concept of maintaining Hb
below 7 gm/dl to facilitate bone marrow stimulation is no longer valid. Intramuscular injections and teeth brushing should be avoided in thrombocytopenic patients. Active bleeding should be
promptly managed with the help of infusion of platelet concentrates in the form of
platelet packs from random donors (5.5 x 1010 platelet/unit) or single donor (3 to 4 x
1011 platelet/unit). It has been observed that each random donor platelet unit increases the platelet count by 10,000/ mm3 at 1 hour after infusion6. Platelet concentrates prepared from single donors using leukocyte filter is the ideal treatment with the aim to maintain platelet count
around 20,000/mm3. Bleeding in thrombocytopenic patients may be decreased by oral administration of eaminocaproic acid 50 mg/kg every 6 hours. In patients receiving large volumes of blood/blood component transfusions, irradiation of blood or blood products is
ideal to prevent transfusion-induced graft versus host disease (GVHD). Moreover, for
multiple transfusions (>50 transfusions) or when there are indications of iron overload.
(serum ferritin >500 mg/dl), iron chelation is needed. The scope of granulocyte tranfusions for the management of neutropenia is very limited as well as controversial because of
inconsistent rise in leucocyte count, prohibitive cost, unreliability in the homing of infused granulocytes at the sites of infection, possibility of allosensitisation, and GVHD. Its role has been further undermined with the availability of very effective and potent antimicrobials and
growth factors. Granulocyte transfusions are now only confined to desperate situations in which proven infection does not respond to appropriate antibiotic therapy.

B. Prevention of infection :

Reverse barrier isolation is one of the most cost-effective measures in the management
of pancytopenia. Careful maintenance of skin hygiene, good dental care, and rectal
hygiene is absolutely essential. Severe neutropenia by itself is not an indication
for hospitalisation as with each admission in the hospital the patient is exposed to the
risk of becoming colonised with antibiotic resistant micro organisms. Strict isolation
in a sterile environment (equipped with laminar flows) together with measures for
skin and gastrointestinal tract decontamination and consumption of
sterile food have been shown to reduce the episodes of infection but generally have
little impact on the eventual outcome of the underlying disorder.
For the past few years some centres are routinely using prophylactic oral antibiotics, such as ciprofloxacin or norfloxacin to reduce the incidence of gram negative sepsis. Both these drugs are very effective but carry the risk of inducing antibiotic resistance. Scrupulous hand washing by medical and health care.

Other management:

The availability of recombinant growth factors like granulocyte colony stimulating factor (GCSF)
or granulocyte macrophage colony stimulating factor (GM-CSF), and recombinant
erythropoietin (rhu EPO) have enabled more specific management with improved outcome
of the pancytopenic patients7,8. The exact role of newer cytokines like recombinant human
interleukin – 3 (IL-3) and interleukin-6 will gradually become better established in near
future. Although at present they are very expensive, yet may ultimately prove to be cost
effective, by reducing the cost of antimicrobials as well as transfusion requirements, thus reducing the total cost of supportive care9. Immunosuppressive therapy with anti
lymphocyte globulin (ALG) and/or cyclosporin has proved to be effective in achieving
remission in aplastic anaemia10. Bone marrow transplantation (BMT) is a therapeutic option
for suitable subsets of younger patients who have HLA matched siblings donors.

Sunday, July 26, 2009

Hematoma management

A sprain can vary from light, moderate, to severe.A sprain will always be accompanied by inflammation.The injured area will be hot and tender to the touch.There will also be damage to the surrounding tissues—vessels, nerves, and muscles.Thereby produce hematoma, which is nothing else collection of blood. But it is pailnful.
So, rapid relieve of pain is the main goal of treatment.How we can relieve pain , these are decribed below:
1. First you have to take a analgesic drug.
2.Use elastic stocking if possible , will reduce the hematoma size and thereby reduce the pain.
3. Give cold compression 3-4 times daily for 2 days.
4. From 3rd day give hot compression for 20 minutes at a time,followed by cold compression. hot compression can be given by hot water bag or bottle, towel. It has two role , first it reduces the pain, second it reduces the hematoma.Cold compression will reduce swelling caused by hot compression.
4.
Elevate the injured limb so that blood will not collect in the injured area.
5.
Massage the area gently to decrease the swelling.
6.
To regain strength, a well-balanced diet with extra protein should be observed. When things are getting back to normal, it is a good practice to build up strength and warm up before any exercise.

Friday, February 13, 2009

New Genomic Markers Identified for MI, CAD, Some of Which Are a Surprise

Lisa Nainggolan


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February 9, 2009 (New York, New York) - Several research groups have identified new genomic markers in various cohorts that have an association--albeit small--with MI or coronary artery disease (CAD). The work appears as five papers online February 8, 2009 in Nature Genetics, and some of the discoveries are somewhat surprising, say experts.
Dr Nilesh Samani (University of Leicester, UK), who was involved in three of the papers, told heartwire: "The bottom line is that if we take this new research [on top of existing work], we now have at least 10 loci that clearly affect the risk of heart attacks and CAD. This is from a position where, two years ago, we didn't really have any loci we were completely comfortable with. And most of these are [associated with genes] we wouldn't hitherto have suspected of being involved, so this provides new evidence, new pathology, that may be involved in causing heart disease."
Dr Eric Topol (Scripps Translational Research Institute, La Jolla, CA), who was not involved in any of this new research, told heartwire: "Using various cohorts, several new genomic markers have been found without any particular theme on type of gene; the only common thread is that the effect is small: 1.1 to 1.2 odds ratio."
Haplotype Association Study Among Papers Identifying New Loci for MI/CAD
Samani was involved in the work by Dr David-Alexandre Tregouet (University Pierre and Marie Curie, Paris, France) and his team, who have discovered a new gene cluster--SLC22A3-LPAL2-LPA--as a strong susceptibility locus for CAD [1]. The novelty of this paper, says Samani, is that they used "a slightly different technique to look at the data that come out of genomewide association studies [GWAS]." Rather than looking at individual differences in DNA sequence--single nucleotide polymorphisms (SNPs)--the researchers looked at groups of SNPs that are inherited together, known as haplotypes.
"Tregouet has slowly walked across the chromosomes identifying these haplotypes to see whether the signal was better when looking at the haplotype rather than individual SNPs . . . and one region showed very strong evidence, which was apparent in the individual SNP analysis but wasn't strong enough to be definite. By analyzing it in this way [by haplotype], we found evidence that this locus is strongly associated with CAD. So the findings are twofold: first, we identified a new locus; and second, it shows we can extract more information out of GWAS by doing a slightly more sophisticated analysis," Samani asserts.
We can extract more information out of GWAS by doing a slightly more sophisticated analysis.
The second paper that Samani is involved in is by Dr Jeanette Erdmann (University of Lubeck, Germany) and colleagues, who identify a new susceptibility locus for CAD on chromosome 3q22.3 following a three-stage analysis of genomewide data in 1222 German individuals with MI and 1298 controls [2].
Samani explains: "When we did the original genomewide scans, we really looked at the low-hanging fruit--the signals that were very strong--but we knew that, because of the nature of these studies, there was a strong possibility that among the signals that were of moderate significance, there must be some that were definitely genuine. In this new Erdmann paper, we saw some signals that appeared to be stronger when we combined everything together and then took it through to replication in these populations, and we confirmed that this locus was true."
Largest GWAS for MI to Date; No Association of MI With CNVs
Samani is also involved in the international Myocardial Infarction Genetics Consortium research, a GWAS testing SNPs and copy number variants (CNVs) for association with early-onset MI in 2967 cases and 3075 controls and replicated in an independent sample of 19 492 [3].
Our study is the largest GWAS for MI conducted to date [and] the first to comprehensively test whether CNVs are associated with MI.
Corresponding author on the paper, Dr Sekar Kathiresan (Massachusetts General Hospital, Boston, MA), told heartwire: "Our study is the largest GWAS for MI conducted to date [and] the first to comprehensively test whether CNVs are associated with MI."
Kathiresan explained that CNVs are large chunks of DNA that are either deleted or duplicated, and it has been hypothesized that they might be responsible for some of the inherited component of common diseases. They found no evidence in this new study, however, that any CNVs were associated with MI.
They did find that SNPs at nine loci reached significance, three of which were new: 21q22, 6p24, and 2q33. The remaining six had previously been observed, including one at 9p21, which is recognized to be the strongest genetic predictor of early MI discovered to date.
"These nine variants in aggregate identify 20% of the population at 2.25-fold increased risk for MI," says Kathiresan.
Surprising Link Between Eosinophil Count and MI; New Data in Asian Subjects
Probably the most surprising of the new reports is from Dr David F Gudbjartsson (deCODE Genetics, Reykjavik, Iceland) and colleagues, who find a link between a high-eosinophil-count gene and MI [4]. They looked for sequence variants affecting eosinophil counts in the blood of 9392 Icelanders and, using the most significant SNPs identified, they studied them further in 12 118 Europeans and 5212 East Asians.
A variety of the SNPs were associated with asthma and one--a nonsynonymous SNP at 12q24--was significantly associated with MI in six different populations (6650 cases and 40 621 controls).
Topol says the Icelandic paper is "curious," with "the surprise link of a high-eosinophil-count gene and MI. This wasn't at all surprising for atopic asthma, but we would not have expected it to be the case for MI."
This wasn't at all surprising for atopic asthma, but we would not have expected it to be the case for MI.
Finally, Japanese researchers extend on prior work they have conducted. Dr Kouichi Ozaki (Center for Genomic Medicine, RIKEN, Yokohama, Japan) and colleagues have previously reported an association of variants in LGALS2, encoding galectin-2, with MI susceptibility in a case-control association in a Japanese population.
Now, they identify BRCA-1 associated protein (BRAP) as a galectin-2 binding protein and report an association of SNPs in BRAP with MI risk in a large Japanese cohort (OR 1.48, 2475 cases and 2778 controls), with replication in additional Japanese and Taiwanese cohorts [5].
Topol says, "This has been a very interesting series of findings from the group of Ozaki and [Dr Toshihiro] Tanaka over several years."
In conclusion, Topol says that he now believes "there are several pathways that set up a genomic susceptibility to MI. Some are ancestry-specific (such as galectin2-BRAP) and some are unanticipated (eg, eosinophilia). While we see the common phenotype of MI, [it appears] there are many ways to get there at the molecular level."
Tregouet D-A, Konig IR, Erdmann J, et al. Genome-wide haplotype association study identifies the SLC22A3-LPAL2-LPA gene cluster as a risk locus for coronary artery disease. Nat Genet 2009; DOI: 10.1038/ng.314. Available at: http://www.nature.com/ng.
Erdmann J, Grosshennig A, Braund PS, et al. New susceptibility locus for coronary artery disease on chromosome 3q22.3. Nat Genet 2009; DOI: 10.1038/ng.307. Available at: http://www.nature.com/ng.
Myocardial Infarction Genetics Consortium. Genome-wide association of early-onset myocardial infarction with single nucleotide polymorphisms and copy number variants. Nat Genet 2009; DOI: 10.1038/ng.327. Available at: http://www.nature.com/ng.
Gudbjartsson DF, Bjornsdittir US, Halapi E, et al. Sequence variants affecting eosinophil numbers associate with asthma and myocardial infarction. Nat Genet 2009; DOI: 10.1038/ng.323. Available at: http://www.nature.com/ng.
Ozaki K, Sato H, Inoue K, et al. SNPs in BRAP associated with risk of myocardial infarction in Asian populations. Nat Genet 2009; DOI: 10.1038/ng.326. Available at: http://www.nature.com/ng.

Chondroitin May Act as Disease Modifier in Knee Osteoarthritis

NEW YORK (Reuters Health) Feb 09 - Long-term use of prescription-grade chondroitins 4 and 6 sulfate (CS) for treatment of knee osteoarthritis reduces pain and slows joint narrowing, investigators report in the February issue of Arthritis and Rheumatism.
The Study on Osteoarthritis Progression Prevention (STOPP) involved 622 patients in Europe and the US, ages 45-80 years, with primary knee osteoarthritis of the medial tibiofemoral compartment. Mean baseline pain scores were 57 mm on a 100-mm visual analog scale.
Patients were randomly assigned to 2 years of daily treatment with an 800-mg sachet of highly purified CS of bovine origin (n = 309) or identical placebo (n = 313). The per-protocol analysis included 206 and 217 patients, respectively. Radiographs of the target knee were obtained using the Lyon Schuss view and assessed by digital image analysis.
Structural effects and pain relief increased with time in the CS group, lead author Dr. Andre Kahan, at Cochin Hospital in Paris, and colleagues report.
The intent-to-treat analysis at 24 months showed a significantly smaller minimum joint space width loss in the CS group (-0.07 mm vs -0.31 mm; median difference 0.14 mm, p < 0.0001). The authors observed a 33% relative risk reduction for joint narrowing.
In addition, the percentage of patients with radiographic progression of less than 0.25 mm was lower in the CS group (28% vs 41% in the control group, p <0.0005).
The decrease in pain scores also favored CS, with significant differences from placebo between months 1 and 9.
The per-protocol analysis showed a median 0.20 mm difference over 24 months in minimum joint space width loss (p < 0.0001), and better global efficacy scores at 6 months (median 50 vs 35, p = 0.03) associated with CS use.
In the per protocol radiographic analysis, the number of patients needed to treat was 5. In the intent-to-treat analysis, the number needed to treat was 8.
Tolerability was deemed good or very good by more than 90% of subjects, with no significant difference between groups in the frequency of adverse events.
The authors note that because the CS used in the STOPP trial is a prescription drug, the results cannot be generalized to chondroitin products sold as dietary supplements.
"The long-term combined structure-modifying and symptom-modifying effects of CS suggest that it could be a disease-modifying agent in patients with knee osteoarthritis," Dr. Kahan and associates conclude.

Infliximab May Prevent Crohn's Disease Recurrence After Surgery

NEW YORK (Reuters Health) Feb 09 - Treatment with infliximab may help prevent endoscopic and histologic recurrence of Crohn's disease following ileal resection, according to a report in the February issue of Gastroenterology.
The results provide "a rationale for aggressive postoperative chemoprevention with biologic therapy," lead author Dr. Miguel Regueiro, from the University of Pittsburgh Medical Center, said in a statement. "We are encouraged by our findings," he added, "which warrant future study of the duration of post-operative infliximab maintenance and appropriate endoscopic follow-up."
The study featured 24 patients who were randomized to receive infliximab (5 mg/kg IV) or placebo after ileal resection, starting within 4 weeks of surgery and continued for 1 year. The main endpoint was the proportion of patients with endoscopic recurrence at 1 year.
Just 1 of 11 patients (9.1%) in the infliximab group had endoscopic recurrence, compared with 11 of 13 patients (84.6%) in the control group, the authors found (p = 0.0006).
The histologic recurrence rate at 1 year was also lower in the infliximab group: 27.3% vs. 84.6% (p = 0.01). The clinical remission rate was non-significantly higher in the infliximab group: 80.0% vs. 53.8%.
Rates of adverse events did not differ between the study groups, the authors note.
"In our practice, we now consider patients with a high risk for postoperative recurrence of Crohn's disease, such as ileal penetrating disease and recurrent resective surgery, for postoperative infliximab prophylaxis," the investigators conclude.