In vivo dosimetry using a single diode for megavoltage photon beam radiotherapy: implementation and response characterization.

The AAPM Task Group 40 reported that in vivo dosimetry can be used to identify major deviations in treatment delivery in radiation therapy. In this paper, we investigate the feasibility of using one single diode to perform in vivo dosimetry in the entire radiotherapeutic energy range regardless of its intrinsic buildup material. The only requirement on diode selection would be to choose a diode with the adequate build up to measure the highest beam energy. We have tested the new diodes from Sun Nuclear Corporation (called QED and ISORAD-p--both p-type) for low-, intermediate-, and high-energy range. We have clinically used both diode types to monitor entrance doses. In general, we found that the dose readings from the ISORAD (p-type) are closer of the dose expected than QED diodes in the clinical setting. In this paper we report on the response of these newly available ISORAD (p-type) diode detectors with respect to certain radiation field parameters such as source-to-surface distance, field size, wedge beam modifiers, as well as other parameters that affect detector characteristics (temperature and detector-beam orientation). We have characterized the response of the high-energy ISORAD (p-type) diode in the low- (1-4 MV), intermediate- (6-12 MV), and high-energy (15-25 MV) range. Our results showed that the total variation of the response of high-energy ISORAD (p-type) diodes to all the above parameters are within +/-5% in most encountered clinical patient treatment setups in the megavoltage photon beam radiotherapy. The usage of the high-energy buildup diode has the additional benefit of amplifying the response of the diode reading in case the wrong energy is used for patient treatment. In the light of these findings, we have since then switched to using only one single diode type, namely the "red" diode; manufacturer designation of the ISORAD (p-type) high-energy (15-25 MV) range diode, for all energies in our institution and satellites.

Photodynamic therapy in oncology.

Photodynamic therapy (PDT) is a cancer treatment modality that is based on the administration of a photosensitiser, which is retained in tumour tissues more than in normal tissues, followed by illumination of the tumour with visible light in a wavelength range matching the absorption spectrum of the photosensitiser. The photosensitiser absorbs light energy and induces the production of reactive oxygen species in the tumour environment, generating a cascade of events that kills the tumour cells. The first generation photosensitiser, Photofrin (porfirmer sodium), has been approved for oesophageal and lung cancer in the US and has been under investigation for other malignant and non-malignant diseases. Sub-optimal light penetration at the treatment absorption peak of Photofrin and prolonged skin photosensitivity in patients are limiting factors for this preparation. Several new photosensitisers have improved properties, especially absorption of longer wavelength light which penetrates deeper into tissue and faster clearance from normal tissue. This paper reviews the current use of first- and second-generation photosensitisers in oncology. The use of PDT in oncology has been restricted to certain cancer indications and has not yet become an integral part of cancer treatment in general. The main advantage of PDT is that the treatment can be repeated multiple times safely, without producing immunosuppressive and myelosuppressive effects and can be administered even after surgery, chemotherapy or radiotherapy. The current work on new photosensitisers and light delivery equipment will address some of the present shortcomings of PDT. Much has been learned in recent years about the mechanisms of cellular and tissue responses to PDT and protocols designed to capitalise on this knowledge showed lead to additional improvements.

Photodynamic therapy: a new concept in medical treatment.

A new concept in the therapy of both neoplastic and non-neoplastic diseases is discussed in this article. Photodynamic therapy (PDT) involves light activation, in the presence of molecular oxygen, of certain dyes that are taken up by the target tissue. These dyes are termed photosensitizers. The mechanism of interaction of the photosensitizers and light is discussed, along with the effects produced in the target tissue. The present status of clinical PDT is discussed along with the newer photosensitizers being used and their clinical roles. Despite the promising results from earlier clinical trials of PDT, considerable additional work is needed to bring this new modality of treatment into modern clinical practice. Improvements in the area of light source delivery, light dosimetry and the computation of models of treatment are necessary to standardize treatments and ensure proper treatment delivery. Finally, quality assurance issues in the treatment process should be introduced.

Phthalocyanine 4 (Pc 4) photodynamic therapy of human OVCAR-3 tumor xenografts.

Photodynamic therapy (PDT) is a cancer treatment modality utilizing a photosensitizer, light and oxygen. Photodynamic therapy with Photofrin has been approved by the U.S. Food and Drug Administration for treatment of advanced esophageal and early lung cancer. Because of certain drawbacks associated with the use of Photofrin, there is a need to identify new photosensitizers for human use. The photosensitizer Pc 4 (HOSiPc-OSi[CH3]2[CH2]3N[CH3]2) has yielded promising PDT effects in many in vitro and in vivo systems. The aim of this study was to assess the usefulness of Pc 4 as a PDT photosensitizer for a human tumor grown as a xenograft in athymic nude mice. The ovarian epithelial carcinoma (OVCAR-3) was heterotransplanted subcutaneously in athymic nude mice. Sixty mice bearing OVCAR-3 tumors (approximately 80-130 mm3) were divided into six groups of 10 animals each, three for controls and three for treatment. The Pc 4 was given by tail vein injection, and 48 h later a 1 cm area encompassing the tumor was irradiated with light from a diode laser coupled to a fiberoptic terminating in a microlens (lambda = 672 nm, 150 J/cm2, 150 mW/cm2). Tumors of control animals receiving no treatment, light alone or Pc 4 alone continued to grow. Of animals receiving 0.4 mg/kg Pc 4 and light, one (10%) had a complete response and was cured (no regrowth up to 90 days post-PDT), while all others (90%) had a partial response and were delayed in regrowth. Of animals receiving 0.6 mg/kg Pc 4 and light, eight (80%) had a complete response, and two of these were cured. Of animals receiving 1.0 mg/kg Pc 4 and light, six (60%) had a complete response, and two of these were cured. In additional experiments, tumors from animals treated with Pc 4 (1 mg/kg) and light were removed 15, 30, 60 and 180 min post-PDT, and from these tumors DNA and protein were extracted. Agarose gel electrophoresis revealed the presence of apoptotic DNA fragmentation as early as 15 min post-PDT. Western blotting showed the cleavage of the 116 kDa native poly(ADP-ribose) polymerase (PARP) into fragments of approximately 90 kDa, another indication of apoptosis, and the presence of p21/WAF1/CIP1 (p21) in all PDT-treated tumors. These changes did not occur in control tumors. Pc 4 appears to be an effective photosensitizer for PDT of human tumors grown as xenografts in nude mice. Early apoptosis, as revealed by PARP cleavage, DNA fragmentation and p21 overexpression, may be responsible for the excellent Pc 4-PDT response. Clinical trials of Pc 4-PDT are warranted.

Perspectives of photodynamic therapy for skin diseases.

Photodynamic therapy (PDT) is largely an experimental modality for the treatment of neoplastic and selected nonneoplastic diseases. This therapeutic procedure, through a cascade of events, leads to cell killing. In the past few years, dermatology has taken advantage of PDT for the treatment of skin cancer and other skin diseases. The skin has considerable attributes over many other organs for the application of PDT. These include the accessibility to all three PDT essential requirements; the drug (photosensitizing agent), visible light and oxygen. The major benefit of experimental PDT in dermatology is the ability to assess the clinical response visually and the relative ease in obtaining biopsies for precise biochemical and histological analysis. Currently, PDT has received approval worldwide for the ablation of various tumor types. In the United States, the Food and Drug Administration has approved PDT for the treatment of advanced esophageal cancer and selected patients with lung cancer. Clinical trials, employing several types of photosensitizers for PDT, are ongoing for a variety of dermatological lesions. This review summarizes current knowledge of PDT in dermatology and highlights future perspectives of this modality for effective management of skin diseases.

Terapia fotodinâmica em hiperoxigenaçäo hiperbárica / Photodynamic therapy in hyperbaric hyperoxia

A Terapia Fotodinâmica (PDT) tem-se mostrado uma técnica seletiva promissora no tratamento do câncer. Após injeção intravenosa de um sensibilizador, que é retido por várias horas em células neoplásias, o tecido é irradiado por um laser, e devido a um mecanismo de transferência de energia não radiativa, agentes citotóxicos são produzidos, induzindo as células tumorais à morte. A técnica de hiperoxigenação hiperbárica (HBO) permite elevar o suprimento de oxigênio molecular, nos tecidos tumorais permitindo potencializar a PDT. Para avaliar o efeito combinado (PDT+HBO), desenvolvemos um modelo experimental que consiste na irradiação de tumores sólidos subcutâneos em dorso de ratos.

Photodynamic Therapy (PDT) have been demonstrated a very promising selectivity potential in cancer treatment. After an intravenous infusion of sensitizes, which is retained for severa! hours inside the neoplasic cells, the tissue is irradiated with a laser beam, and due a non-radiactive transfer mechanism, cytotoxic agents are produced, inducing death of the tumor cells. Hyperbaric hyperoxia (HBO) allows the tissues to achieve high supply of molecular oxygen. ln order to evaluate this combined effect of both therapies an experimental model was developed, creating a tumor mass in the dorsal subcutaneous tissue of rats.