Dear Editor

We read with interest the report on postulated atorvastatin induced lactic acidosis [1]. In our view, the arguments outlined by its authors do not support this hypothesis at all, for the reasons outlined below:

a) The patient clearly had a mixed acid-base disturbance (combined respiratory alkalosis and metabolic acidosis, as evidenced by the normal pH of 7.39 coupled with severe hypocapnia).

b) Both the delta anion gap (24.2 –16= 8 mEq/L) and the decrease in standard base excess (which we use in preference to whole blood base excess and calculate to be -17.9 mEq/L) are much larger than the delta lactate, which is only approximately 1.5 mmol/L. This clearly indicates that the metabolic acidosis is multifactorial, and that another pathological process rather than hyperlactaemia is the major contributor to the raised anion gap. This should lead to a search for other causes of a raised anion gap. For example, one would need to measure serum salicylates, the osmolar gap and plasma beta-hydroxybutyrate. With concerns of statin myopathy, a serum CK would be useful. With a history of paracetamol ingestion, pyroglutamic acidosis is a likely possibility and could be diagnosed using a urinary organic acid screen [2].

c) The authors’ discussion of potential causes of an elevated plasma lactate concentration is incomplete. For example, they have failed to discuss the possible contribution of salbutamol to the hyperlactaemia. Furthermore, covert tissue hypoxia is a possibility despite normal arterial oxygenation, which can lead to hyperlactaemia.

d) If it were to be a mitochondrial paralysis from statin therapy, it is hard to imagine an immediate clinical improvement upon cessation of the medication.

Other significant and fundamental errors in the report detract from its validity. They include the following:

a) The [HCO3-] is said to be 13.8 mmol/L, whereas at the quoted pH (7.39) and PCO2 (1.2 kPa) it would be much lower at 5.3 mmol/L.

b) The quoted PO2 of 19.3 kPa on room air implies a negative A-a gradient of nearly 1 kPa. This is clearly impossible in any patient, let alone an 82 year old woman. Presumably supplemental oxygen was being administered.

c) The mention of unmeasured cations instead of anions in the abstract when discussing a raised anion gap is a cause for confusion.

We recognise that simvastatin has been reported to induce lactic acidosis through mitochondrial failure [3]. However, this report describes a mixed acid-base disorder not primarily due to lactate. Hence, the authors cannot claim that it adds to the body of evidence supporting the link between statin therapy and lactic acidosis.

References

(1) Neale R, Reynolds TM, Saweirs W. Statin precipitated lactic acidosis? J Clin Pathol 2004;57(9):989-90.

(2) Dempsey GA, Lyall HJ, Corke CF, Scheinkestel CD. Pyroglutamic acidemia: a cause of high anion gap metabolic acidosis. Crit Care Med 2000;28(6):1803-7.

(3) Goli AK, Goli SA, Byrd RP, Jr., Roy TM. Simvastatin-induced lactic acidosis: a rare adverse reaction? Clin Pharmacol Ther 2002;72(4):461-4.

Dear Editor

When a patient has an infection, doctors often send a sample of infected blood or tissue to a lab where they can grow the bacteria and see which antibiotics are most effective (called Bacterial Culture and Sensitivity Testing). Chemosensitivity testing is an attempt to do something similar for cancer; fresh samples of the patient's tumor from surgery or a biopsy are grown in test tubes and tested with various drugs. Drugs that are most effective in killing the cultured cells are recommended for treatment. It is highly desirable to know what drugs are effective against your particular cancer cells before highly-toxic agents are systemically administered to your body.

One approach to individualizing patient therapy is chemosensitivity testing. Chemosensitivity assay is a laboratory test that determines how effective specific chemotherapy agents are against an individual patient's cancer cells. Often, results are obtained before the patient begins treatment. This kind of testing can assist in individualizing cancer therapy by providing information about the likely response of an individual patient's tumor to proposed therapy. Chemosensitivity testing may have utility at the time of initial therapy, and in instances of severe drug hypersensitivity, failed therapy, recurrent disease, and metastatic disease, by providing assistance in selecting optimal chemotherapy regimens.

All available chemosensitivity assays are able to report drug "resistance" information. Resistance implies that when a patient's cancer cells are exposed to a particular chemotherapy agent in the laboratory, the cancer cells will continue to live and grow. Some chemosensitivity assays also are able to report drug "sensitivity" information. Sensitivity implies that when a patient's cancer cells are treated with a particular chemotherapy agent in the laboratory, that agent will kill the cancer cells or inhibit their proliferation.

The goal of all chemosensitivity tests is to determine the response of a patient's cancer cells to proposed chemotherapy agents. Knowing which chemotherapy agents the patient's cancer cells are resistant to is important. Then, these options can be eliminated, thereby avoiding the toxicity of ineffective agents. In addition, some chemosensitivity assays predict tumor cell sensitivity, or which agent would be most effective. Choosing the most effective agent can help patients to avoid the physical, emotional, and financial costs of failed therapy and experience an increased quality of life.

Fresh samples of the patient's tumor from surgery or a biopsy are grown in test tubes and tested with various drugs. Drugs that are most effective in killing the cultured cells are recommended for treatment. Chemosensitivity testing does have predictive value, especially in predicting what "won't" work. Patients who have been through several chemotherapy regimens and are running out of options might want to consider chemosensitivity testing. It might help you find the best option or save you from fruitless additional treatment. Today, chemosensitivity testing has progressed to the point where it is 85% - 90% effective.

Chemosensitivity testing might help you find the best option, or save you from fruitless additional treatment. Another situation where chemosensitivity testing might make particularly good sense is in rare cancers where there may not be enough experience or previous ideas of which drugs might be most effective.

Finally, there has been a veritable deluge of new approvals of cytotoxic drugs in recent years as the tortuous FDA process has been speeded and liberalized. In many cases a new drug has been approved on the basis of a single very very narrow indication. But these drugs may have many useful applications - and it's going to take years to find out. Chemosensitivity testing offers a way of seeing if any of these new drugs might apply to your specific cancer.

Dear Editor

We read with interest the recent article by Alikhan et al , in which they reviewed necropsy reports to find out the number of deaths due to fatal pulmonary embolism in hospitalised patients.[1] There seem to be a number of confusions in this paper.

1. Acute infection was the most common medical illness found in patients who had died from pulmonary embolism, in particular respiratory infections. The authors state that the pathophysiology of venous thromboembolism in the presence of acute infection remains to be fully defined and then quote recent evidence that respiratory viruses are capable of infecting endothelial cells and causing a shift from anti- coagulant to pro-coagulant activity.[2] Such a proposed mechanism would presumably increase the likelihood of pulmonary thrombosis, not thromboembolism from deep venous thromboses.

2. The authors recognise that without denominator numbers for the surgical and medical patient groups, no interpretation is possible regarding the actual incidence of fatal pulmonary embolism. However, they themselves then go on to make a number of comparisons between surgical and “non-surgical” groups.

3. Pulmonary emboli were recorded as the cause of death when the necropsy report stated that embolism was the main or contributing cause of death. Many things get written down as contributing towards death, as any pathologist knows. The authors also state that it is difficult to distinguish between fatal, contributory, and incidental emboli when the definitions and interpretations are based on pathologists’ opinions over a long time period. One obvious way to address this difficulty would be for the authors to ask a pathologist to help them interpret the necropsy reports.

References

1. Alikhan R, Peters F, Wilmott R, et al. Fatal pulmonary emboli in hospitalised patients: a necropsy review. J Clin Pathol 2004;57:1254-7.

2. Visseren FL, Bouwman JJ, Bouter KP, et al. Procoagulant activity of endothelial cells after infection with respiratory viruses. Thromb Haemost 2000;84:319-24.

The paper by Turnbull and colleagues (1) on the decline of the adult hospital autopsy rate in UK prompted me to review and extend the Norwich data that they kindly quoted (2). I calculated the adult hospital autopsy rate since our publication (including that relating to the first five months of this year) using the method that we both employed. The modest improvement that we reported in the adult hospital autopsy rate in Norwich between 2003 and 2005 was not subsequently sustained and the overall trend continued downward. During the period since 1 January 2006, the mean adult hospital autopsy rate in Norwich was 1.1% (range 0.1%-1.7%). The rate in 2013 was 0.6%, in line with the data presented by Turnbull et al. (1).

During 2006-2014, there has been a rising trend here in the annual number of autopsies undertaken for HM Coroner (mean 1191; range 1037- 1355). Most such cases represented deaths in the community or in the A&E Department, but some were patients who died in the wards after admission. In such cases the attending clinicians were unable to complete a certificate of the cause of death. While some such cases followed trauma or other unnatural events, many were natural deaths in which the clinical course was difficult to understand, sometimes despite detailed examination and testing; no confident diagnostic label was attached before death. Such Coroner's cases arising from within the hospital patient population represent medicolegal quasi-hospital autopsies and provide a partial means of alleviating the decline in consented adult hospital autopsies. It is my experience that many such cases provide valuable opportunities to study disease and the efficacy of diagnosis and treatment in the hospital setting.

The continuing decline of the adult hospital autopsy is of great concern. It is likely to multifactorial and to be influenced by the attitudes of clinicians, pathologists and bereaved families (3,4). It does have important implications for clinical audit, diagnostics and medical education (3). While such matters can, at least in part, be addressed by the coronial autopsies that are undertaken on certain hospital deaths, such cases are relatively few and do not necessarily reflect the normal population of patients who die in hospital; they are likely to provide a skewed experience. We know little about the numbers of such cases or what stimulates a clinician to discuss a seemingly natural death with the Coroner, rather than to use clinical judgement and suggest the most likely cause of death and complete a death certificate. It may be that clinicians wish to have a greater degree of certainty than such an approach allows.

While medicolegal quasi-hospital autopsies are an imperfect substitute for properly conducted hospital autopsies, they are better than nothing and should, perhaps, be considered when assessing adult hospital autopsy rates. The whole matter clearly requires further research. Autopsy practice in general is threatened by the decline in the numbers of histopathologists who are prepared to undertake any such examinations. That itself is a matter of concern and requires deeper understanding and rectification. It chimes with Byard's view that the decline in the autopsy is, at least in part, the responsibility of histopathologists (4).

References

1. Turnbull A, Osborn M, Nicholas N. Hospital autopsy: Endangered or extinct? J Clin Pathol Published Online First: [15 06 2015] doi:10.1136/jclinpath-2014-202700

2. Limacher E, Carr U, Bowker L, et al. Reversing the slow death of the clinical necropsy: developing the post of the Pathology Liaison Nurse. J Clin Pathol 2007; 60:1129-34.

3. Carr U, Bowker L, Ball RY. The slow death of the clinical post- mortem examination: implications for clinical audit, diagnostics and medical education. Clin Med 2004; 4:417-23.

4. Byard RW. Who's killing the autopsy? A new tool for assessing the causes of falling autopsy rates. Med J Aust 2005; 183:654-5.

Conflict of Interest:

None declared